VA Lessons From Partnering in COVID-19 Clinical Trials

Article Type
Changed
Tue, 10/31/2023 - 15:59

The US Department of Veterans Affairs (VA), through its Office of Research and Development (ORD), supports an extensive and experienced clinical research enterprise, including the first multisite trials in the US.1 These resources contribute to the ORD support for the largest US integrated health care system, with a primary focus on the care and well-being of veterans. While the history of VA research has facilitated the creation of an experienced and organized research enterprise, the COVID-19 pandemic challenged VA to contribute even more significantly. These challenges became pronounced given the urgency associated with standing up VA sites for both therapeutic and vaccine trials.

VA Clinical Research Enterprise

The VA recognized an early need for an organized research response not only to address operational challenges resulting from COVID-19 but also ensure that the agency would be ready to support new scientific efforts focused specifically on the virus and related outcomes.2 As a result, the ORD took decisive action first by establishing itself as a central headquarters for VA COVID-19 research activities, and second, by leveraging existing resources, initiatives, and infrastructure to develop new mechanisms that would ensure that the VA was well positioned to develop or participate in research endeavors being driven by the VA as well federal, industry, and non-VA partners.

Prior to the pandemic, the ORD, through its Cooperative Studies Program (CSP), had strategies to address challenges associated with clinical trial startup and improved efficient conduct.3 For example, the VA Network of Dedicated Enrollment Sites (NODES) is a consortium of 23 VA medical centers (VAMCs) dedicated to rapid startup and recruitment into VA-sponsored clinical trials. NODES provides site-level expertise on clinical trial management, including troubleshooting challenges that may occur during clinical research execution.4 Another initiative, Access to Clinical Trials (ACT) for Veterans, engaged industry, academic, patient advocacy, and other partners to identify potential regulatory and operational hurdles to efficient startup activities specific to externally sponsored multisite clinical trials. Under ACT for Veterans, stakeholders emphasized the importance of developing a single VA point of contact for external partners to work with to more efficiently understand and navigate the VA system. In turn, such a resource could be designed to facilitate substantive research and long-term relationships with compatible external partners. Targeted to launch in April 2020, the Partnered Research Program (PRP) was expedited to respond to the pandemic.

During the pandemic, new VA efforts included the creation of the VA CoronavirUs Research and Efficacy Studies (VA CURES) network, initially established as a clinical trial master protocol framework to support and maximize VA-funded COVID-19 trial efficiency.5 VA CURES joined the consortium of trials networks funded by the National Heart, Lung, and Blood Institute. It began treatment trials under Accelerating COVID-19 Therapeutic Interventions and Vaccination (ACTIV), specifically ACTIV-4. The VA also partnered with the National Institutes of Allergy and Infectious Diseases (NIAID) by organizing the VA International Coordinating Center (VA ICC) for other ACTIV trials (ACTIV-2 and -3). When approached to startup studies that included veterans and the VA health care system, these capabilities comprised the VA research response.

A Need for a New Approach

As the impact of the pandemic expanded and the need for effective treatments and vaccines grew, national calls were made to assess the capabilities and readiness of available clinical trials networks. Additionally, the US Department of Health and Human Services Biomedical Advanced Research and Development Authority, ACTIV, NIAID Division of Clinical Research and Division of AIDS, and many pharmaceutical companies were starting to roll out trials of new therapeutics and vaccines. These groups approached the VA to help evaluate the safety and efficacy of several therapeutics and vaccines because they recognized several advantages of the VA enterprise, including its position as the nation’s largest integrated health care system, its diverse patient population, and its expertise in conducting clinical trials.

Although the VA was well positioned as an important player in a collaborative investigational approach to COVID-19 research, these trials required startup approaches that were significantly different from those it had employed in traditional, prepandemic, clinical research. Despite the VA being a single federal agency, each VAMC conducting research establishes its own practices to address both operational and regulatory requirements. This structure results in individual units that operate under different standard operating procedures. Efforts must be taken centrally to organize them into a singular network for the entire health care system. During a national crisis, when there was a need for rapid trial startup to answer safety and efficacy questions and participate under a common approach to protocol execution, this variability was neither manageable nor acceptable. Additionally, the intense resource demands associated with such research, coupled with frequent reporting requirements by VA leaders, Congress, and the White House, required that VAMCs function more like a single unit. Therefore, the ORD needed to develop VAMCs’ abilities to work collectively toward a common goal, share knowledge and experience, and capitalize on potential efficiencies concerning legal, regulatory, and operational processes.

table

Beginning August 2020, 39 VAMCs joined 7 large-scale collaborative COVID-19 therapeutic and vaccine trials. Through its COVID-19 Research Response Team, the ORD identified, engaged, and directed appropriate resources to support the VAMC under a centralized framework for study management (Table). Centralized management not only afforded VAMCs the opportunity to work more collectively and efficiently but also provided an important advantage by enabling the VA to collect and organize its experiences (and on occasion data) to provide a base for continual learning and improvement efforts. While others have described efforts undertaken across networks to advance learning health systems, the VA’s national scope and integration of research and clinical care allow greater opportunities to learn in a practical setting.6

 

 

Challenges and Best Practices

Using surveys, webinars, interviews, and observation from site and VA Central Office personnel, the ORD identified specific variables that prevented the VAMCs from quickly starting up as a clinical trial site. We also documented strategies, solutions, and recommendations for improving startup time lines. These were organized into 8 categories: (1) site infrastructure needs and capabilities; (2) study management roles and responsibilities; (3) educational resources and training; (4) local review requirements and procedures; (5) study design demands; (6) contracting and budgeting; (7) central-level systems and processes; and (8) communication between external partners and within the VA.

Site Infrastructure Needs and Capabilities

A primary impediment to rapid study startup was a lack of basic infrastructure, including staff, space, and the agility necessary for the changing demands of high-priority, high-enrolling trials. This observation is not unique to the VA.7 Initially, certain facilities located in hot spots where COVID-19 was more prevalent became high-interest targets for study placement, despite varying degrees of available research infrastructure. Furthermore, pandemic shutdowns and quarantines permitted fewer employees onsite. This resulted in inadequate staffing in personnel needed to support required startup activities and those needed to handle the high volume of study participants who were being recruited, screened, enrolled, and followed. Additionally, as clinical care needs and infection control practices were prioritized, clinical research space was often appropriated for these needs, making it difficult to find the space to conduct trials. Lastly, supply chain issues also posed unique challenges, sometimes making it difficult for participating VAMCs to obtain needed materials, such as IV solution bags of specific sizes and contents, safety injection needles, and IV line filters.

The VA was able to use central purchasing/contracting at coordinating centers or the VA Central Office to support investigators and assist with finding supplies and clinical research space. VAMCs with research operating budgets to cover startup costs were better positioned to handle funding delays. During the pandemic, the ORD further contracted to supply administrative support to research offices to address regulatory and other requirements needed for startup activities. The ability to expand such central contracts to procure clinical research staff and outpatient clinical research space may also prove useful in meeting key needs at a site.

Management Roles and Responsibilities

Ambiguous and variable roles and responsibilities among the various partners and stakeholders represented a challenge given the large-scale, national, or international operations involved in the trials. VA attempts to operate uniformly were further limited given that each sponsor or group had preferred methods for operating and/or organizing work under urgent time lines. For example, one trial involved a coordinating center, a contract research organization, and federal partners that each worked with individual sites. Consequently, VA study teams would receive messages that were conflicting or unclear.

The VA learned that studies need a single “source of truth” and/or central command structure in times of urgency. To mitigate conflicting messages, vaccine trials relied on a clearinghouse through the PRP to interpret requirements or work on behalf of all sites before key actions were taken. For studies with the NIAID, the VA relied on experienced staff at the CSP coordinating center at the Perry Point, Maryland, VAMC before beginning. This approach especially helped with the challenges of understaffing and sites’ lack of familiarity with complex platform trial designs and already-established network practices within the ACTIV-2 and ACTIV-3 studies.

Educational Resources and Training

Since VA participation in externally sponsored, multisite clinical trials traditionally relies on an individual VAMC study team and its local resources, transitioning to centralized approaches for COVID-19 multisite studies created barriers. Many VAMCs were unfamiliar with newer capabilities for more rapid regulatory reviews and approvals involving commercial institutional review boards (IRBs) and central VA information security and privacy reviews. While tools and resources were available to facilitate these processes, real-time use had not been fully tested. As a result, everyone had to learn as they went along.

The simultaneous establishment of workflows required the ORD to centralize operations and provide training and guidance to field personnel. Although many principal investigators and clinical research coordinators had trial experience, training required unlearning previous understandings of requirements to meet urgent time lines. ORD enterprise road maps, central tools, and training materials also were made available on a study-by-study basis. Open communication was vital to train on central study materials while opportunities to discuss, question, and share experiences and ideas were promoted. The ORD also sent regular emails to prepare for upcoming work and/or raise awareness of identified challenges.

 

 

Local Review Requirements/Procedures

The clinical trials were impacted by varying VAMC review requirements and approval processes. Although VA policy defines standard requirements, the timing and procedures are left to the individual facility to determine any local factors to accommodate and/or resource availability. While such an approach is well understood within the VA, external sponsors were not as familiar and assumed a more uniform approach across all sites. In response, some VAMCs established ad hoc research and development committee review procedures, allowing study teams to obtain the necessary reviews in a timely fashion. However, not all VAMCs had the infrastructure (especially when clinical personnel had been redeployed to other priorities) to respond with such agility. One critical role of the VA Central Office coordinating entities was to communicate and manage external sponsor and group expectations surrounding individual site review time lines. However, establishing policies and procedures that focus on streamlining local review processes helped to broadly mitigate the COVID-19 trial challenges.

Study Design Demands

The design of COVID-19 studies combined with the uncertainty of the pandemic required rapid protocol changes and adaptations that were often difficult to deliver. The multinetwork trials that the VA collaborated on were platform or master protocol designs. These designs emphasized overall goals (eg, treating patients requiring intensive care unit care). However, because this trial strategy also introduces complexities that may impact review and execution among those unfamiliar with it, there is a need for increased discussion and understanding of this methodology.8 For example, there can be shared control groups, reliance on specific criteria for halting because of safety or futility concerns, or continuation and expansion applied through an external review board. Delays may arise when changes to study protocols occur rapidly or frequently and necessitate new regulatory reviews, negotiation of new agreements, modifications to contracts, changes to entry criteria, etc.

While the VA has adopted a quality by design framework, VA investigators noted many missed opportunities related to looking at outcomes with new diagnostics, studies of serology, outcomes related to vaccinations, and understanding the natural history of disease in these trials.9 The limited opportunities for investigator input suggested that the advantages offered by platform designs were not maximized during pandemic-focused urgencies. It was unclear whether this barrier was created by a general lack of awareness by sponsors or a lack of opportunities. At the very least, quality by design approaches may help avoid redundancies in documentation or study processes at the central and site levels.

Contracting and Budgeting

Given external sponsorship of COVID-19 trials, efficient contracting and budgeting were critical for a rapid start up. The variability of processes associated with these trials created several challenges that were compounded by issues, such as site sub-agreements and budget documents that did not always go to the correct groups and individuals. Furthermore, the VA’s ability to use contracted resources (eg, tents, trailers, personnel) that external sponsors had built into their contracts was more difficult for VA as a federal agency governed by other statues and policies. This also put VAMCs at a disadvantage from a timing perspective, as the VA often required additional time to find equivalent solutions that met federal regulations.

Although the VA was able to establish contract solutions to some issues, time was still lost while working to secure initial funding. Additionally, for needs such as home phlebotomy—commended for convenience to veterans and research staff—and engaging a specialized research team in the Office of General Counsel, early awareness of protocol needs and sponsor solutions could allow VA to pursue alternatives sooner.

Central-Level Systems and Processes

Not all challenges were at the VAMC level. As the ORD explored solutions, it learned that various tools and study platforms were available but not considered. Applications, such as eConsent, and file-sharing platforms that met existing information security and privacy requirements were needed but had to comply with the Privacy Act of 1974, Federal Information Security Modernization Act, and other requirements. Using sponsor-provided devices, such as drug temperature monitoring equipment, required additional review to ensure that they met system requirements for a national health care system. In addition, the VA uses a clinical trials management review system; however, its implementation was new at the time these trials began. Furthermore, the system engaged with some commercial IRBs but not all. This resulted in additional delays as VAMCs and central resources worked to familiarize themselves with the system and procedures.

The ability to work collaboratively across the VA includes having a framework in which key startup processes are standardized. This allows for efficiency and minimizes variability. Also, all stakeholders should understand the importance of holding discussions to identify appropriate solutions, guidance, and instruction. Finally, the VA must strive to be more nimble when adapting technological, regulatory, and financial processes.

 

 

Internal and External Communication

The value of communication—both internal and external—cannot be understated. Minimizing confusion, managing expectations, and ensuring consistent messaging were essential for rapid trial execution. Despite being the second largest federal agency, the VA did not have a seat at the study leadership table for several protocols. When it joined later, several study aspects were set and/or difficult to revise. Challenges affecting time and securing resources have been noted. The ability to plan and then share expectations and responsibilities across and within the respective participating organizations early in the process was perhaps the single factor that was most addressable. The VA enterprise organization and integration with other units could accentuate key communications that would be essential in time-sensitive activities.

VA as a Partner for Future Research

Before the pandemic, the VA had already undertaken a path to enhance its ability to partner as part of the national biomedical research enterprise. The need for COVID-19 therapeutic and vaccine trials accelerated opportunities to plan and develop processes and capabilities to advance this path. As a key strength for VA scientific activities, clinical trials represent a primary medium by which to develop its partnerships. Learning and development have become part of a culture that expedites opportunities for veterans who actively seek ways to contribute to medical knowledge and treatments for their peers and the nation.

CONCLUSIONS

Challenges associated with rapid startup and completion of clinical trials have been discussed for some time. During the pandemic, needs and barriers were magnified because of the heightened urgency for evidence-based therapeutics and vaccines. While the VA faced similar problems as well as those specific to it as a health care system, it had the opportunity to learn and more systematically implement solutions to help in its partnered efforts.10 As an enterprise, the VA hopes to apply lessons learned, strategies, and best practices to further its goals to enhance veteran access to clinical trials and respond to any future need to quickly establish evidence bases in pandemics and other health emergencies that warrant the rapid implementation of research.

Acknowledgments

The activities reported here were supported by the US Department of Veterans Affairs, Office of Research and Development.

References

1. Hays MT; US Department of Veterans Affairs, Veterans Health Administration, Office of Research and Development. A historical look at the establishment of the Department of Veterans Affairs Research & Development Program. Accessed August 28, 2023. https://www.research.va.gov/pubs/docs/ORD-85yrHistory.pdf

2. Garcia AP, Huang GD, Arnheim L, Ramoni R, Clancy C. The VA research enterprise: a platform for national partnerships toward evidence building and scientific innovation. Fed Pract. 2023;40(suppl 5):S12-S17. doi:10.12788/fp.0425

3. Johnston SC, Lewis-Hall F, Bajpai A, et al. It’s time to harmonize clinical trial site standards. NAM Perspectives. October 9, 2017. Accessed August 28, 2023. https://nam.edu/wp-content/uploads/2017/10/Its-Time-to-Harmonize-Clinical-Trial-Site-1.pdf

4. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: the Department of Veterans Affairs’ Network of Dedicated Enrollment Sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

5. US Food and Drug Administration. Master protocols: efficient clinical trial design strategies to expedite development of oncology drugs and biologics guidance for industry. March 2022. Accessed August 23, 2023. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/master-protocols-efficient-clinical-trial-design-strategies-expedite-development-oncology-drugs-and

6. IOM Roundtable on Value & Science-Driven Care; Institute of Medicine. Continuous learning and improvement in health care. In: Integrating Research and Practice: Health System Leaders Working Toward High-Value Care: Workshop Summary. National Academies Press (US); 2015:chap 2. Accessed August 28, 2023. https://www.ncbi.nlm.nih.gov/books/NBK284654 7. Institute of Medicine (US). Building an infrastructure to support clinical trials. In: Envisioning a Transformed Clinical Trials Enterprise in the United States. National Academies Press (US); 2012:chap 5. Accessed August 28, 2023. https://www.ncbi.nlm.nih.gov/books/NBK114656

8. Park JJH, Harari O, Dron L, Lester RT, Thorlund K, Mills EJ. An overview of platform trials with a checklist for clinical readers. J Clin Epidemiol. 2020;125:1-8. doi:10.1016/j.jclinepi.2020.04.025

9. Meeker-O’Connell A, Glessner C, Behm M, et al. Enhancing clinical evidence by proactively building quality into clinical trials. Clin Trials. 2016;13(4):439-444. doi:10.1177/1740774516643491

10. McClure J, Asghar A, Krajec A, et al. Clinical trial facilitators: a novel approach to support the execution of clinical research at the study site level. Contemp Clin Trials Commun. 2023;33:101106. doi:10.1016/j.conctc.2023.101106

Article PDF
Author and Disclosure Information

Krissa Caroff, MSa; Victoria J. Davey, PhD, MPHa; Miriam Smyth, PhDa; Grant D. Huang, MPH, PhDa

Correspondence:  Krissa Caroff  (krissa.caroff@va.gov)

Author affiliations

aOffice of Research and Development, Department of Veterans Affairs, Washington, DC

Author disclosures

The authors report no actual or potential conflicts of interest or outside sources of funding with regard to this article.

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the U.S. Government, or any of its agencies.

Ethics and consent

Not applicable

Issue
Federal Practitioner - 40(5)s
Publications
Topics
Page Number
S18
Sections
Author and Disclosure Information

Krissa Caroff, MSa; Victoria J. Davey, PhD, MPHa; Miriam Smyth, PhDa; Grant D. Huang, MPH, PhDa

Correspondence:  Krissa Caroff  (krissa.caroff@va.gov)

Author affiliations

aOffice of Research and Development, Department of Veterans Affairs, Washington, DC

Author disclosures

The authors report no actual or potential conflicts of interest or outside sources of funding with regard to this article.

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the U.S. Government, or any of its agencies.

Ethics and consent

Not applicable

Author and Disclosure Information

Krissa Caroff, MSa; Victoria J. Davey, PhD, MPHa; Miriam Smyth, PhDa; Grant D. Huang, MPH, PhDa

Correspondence:  Krissa Caroff  (krissa.caroff@va.gov)

Author affiliations

aOffice of Research and Development, Department of Veterans Affairs, Washington, DC

Author disclosures

The authors report no actual or potential conflicts of interest or outside sources of funding with regard to this article.

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the U.S. Government, or any of its agencies.

Ethics and consent

Not applicable

Article PDF
Article PDF

The US Department of Veterans Affairs (VA), through its Office of Research and Development (ORD), supports an extensive and experienced clinical research enterprise, including the first multisite trials in the US.1 These resources contribute to the ORD support for the largest US integrated health care system, with a primary focus on the care and well-being of veterans. While the history of VA research has facilitated the creation of an experienced and organized research enterprise, the COVID-19 pandemic challenged VA to contribute even more significantly. These challenges became pronounced given the urgency associated with standing up VA sites for both therapeutic and vaccine trials.

VA Clinical Research Enterprise

The VA recognized an early need for an organized research response not only to address operational challenges resulting from COVID-19 but also ensure that the agency would be ready to support new scientific efforts focused specifically on the virus and related outcomes.2 As a result, the ORD took decisive action first by establishing itself as a central headquarters for VA COVID-19 research activities, and second, by leveraging existing resources, initiatives, and infrastructure to develop new mechanisms that would ensure that the VA was well positioned to develop or participate in research endeavors being driven by the VA as well federal, industry, and non-VA partners.

Prior to the pandemic, the ORD, through its Cooperative Studies Program (CSP), had strategies to address challenges associated with clinical trial startup and improved efficient conduct.3 For example, the VA Network of Dedicated Enrollment Sites (NODES) is a consortium of 23 VA medical centers (VAMCs) dedicated to rapid startup and recruitment into VA-sponsored clinical trials. NODES provides site-level expertise on clinical trial management, including troubleshooting challenges that may occur during clinical research execution.4 Another initiative, Access to Clinical Trials (ACT) for Veterans, engaged industry, academic, patient advocacy, and other partners to identify potential regulatory and operational hurdles to efficient startup activities specific to externally sponsored multisite clinical trials. Under ACT for Veterans, stakeholders emphasized the importance of developing a single VA point of contact for external partners to work with to more efficiently understand and navigate the VA system. In turn, such a resource could be designed to facilitate substantive research and long-term relationships with compatible external partners. Targeted to launch in April 2020, the Partnered Research Program (PRP) was expedited to respond to the pandemic.

During the pandemic, new VA efforts included the creation of the VA CoronavirUs Research and Efficacy Studies (VA CURES) network, initially established as a clinical trial master protocol framework to support and maximize VA-funded COVID-19 trial efficiency.5 VA CURES joined the consortium of trials networks funded by the National Heart, Lung, and Blood Institute. It began treatment trials under Accelerating COVID-19 Therapeutic Interventions and Vaccination (ACTIV), specifically ACTIV-4. The VA also partnered with the National Institutes of Allergy and Infectious Diseases (NIAID) by organizing the VA International Coordinating Center (VA ICC) for other ACTIV trials (ACTIV-2 and -3). When approached to startup studies that included veterans and the VA health care system, these capabilities comprised the VA research response.

A Need for a New Approach

As the impact of the pandemic expanded and the need for effective treatments and vaccines grew, national calls were made to assess the capabilities and readiness of available clinical trials networks. Additionally, the US Department of Health and Human Services Biomedical Advanced Research and Development Authority, ACTIV, NIAID Division of Clinical Research and Division of AIDS, and many pharmaceutical companies were starting to roll out trials of new therapeutics and vaccines. These groups approached the VA to help evaluate the safety and efficacy of several therapeutics and vaccines because they recognized several advantages of the VA enterprise, including its position as the nation’s largest integrated health care system, its diverse patient population, and its expertise in conducting clinical trials.

Although the VA was well positioned as an important player in a collaborative investigational approach to COVID-19 research, these trials required startup approaches that were significantly different from those it had employed in traditional, prepandemic, clinical research. Despite the VA being a single federal agency, each VAMC conducting research establishes its own practices to address both operational and regulatory requirements. This structure results in individual units that operate under different standard operating procedures. Efforts must be taken centrally to organize them into a singular network for the entire health care system. During a national crisis, when there was a need for rapid trial startup to answer safety and efficacy questions and participate under a common approach to protocol execution, this variability was neither manageable nor acceptable. Additionally, the intense resource demands associated with such research, coupled with frequent reporting requirements by VA leaders, Congress, and the White House, required that VAMCs function more like a single unit. Therefore, the ORD needed to develop VAMCs’ abilities to work collectively toward a common goal, share knowledge and experience, and capitalize on potential efficiencies concerning legal, regulatory, and operational processes.

table

Beginning August 2020, 39 VAMCs joined 7 large-scale collaborative COVID-19 therapeutic and vaccine trials. Through its COVID-19 Research Response Team, the ORD identified, engaged, and directed appropriate resources to support the VAMC under a centralized framework for study management (Table). Centralized management not only afforded VAMCs the opportunity to work more collectively and efficiently but also provided an important advantage by enabling the VA to collect and organize its experiences (and on occasion data) to provide a base for continual learning and improvement efforts. While others have described efforts undertaken across networks to advance learning health systems, the VA’s national scope and integration of research and clinical care allow greater opportunities to learn in a practical setting.6

 

 

Challenges and Best Practices

Using surveys, webinars, interviews, and observation from site and VA Central Office personnel, the ORD identified specific variables that prevented the VAMCs from quickly starting up as a clinical trial site. We also documented strategies, solutions, and recommendations for improving startup time lines. These were organized into 8 categories: (1) site infrastructure needs and capabilities; (2) study management roles and responsibilities; (3) educational resources and training; (4) local review requirements and procedures; (5) study design demands; (6) contracting and budgeting; (7) central-level systems and processes; and (8) communication between external partners and within the VA.

Site Infrastructure Needs and Capabilities

A primary impediment to rapid study startup was a lack of basic infrastructure, including staff, space, and the agility necessary for the changing demands of high-priority, high-enrolling trials. This observation is not unique to the VA.7 Initially, certain facilities located in hot spots where COVID-19 was more prevalent became high-interest targets for study placement, despite varying degrees of available research infrastructure. Furthermore, pandemic shutdowns and quarantines permitted fewer employees onsite. This resulted in inadequate staffing in personnel needed to support required startup activities and those needed to handle the high volume of study participants who were being recruited, screened, enrolled, and followed. Additionally, as clinical care needs and infection control practices were prioritized, clinical research space was often appropriated for these needs, making it difficult to find the space to conduct trials. Lastly, supply chain issues also posed unique challenges, sometimes making it difficult for participating VAMCs to obtain needed materials, such as IV solution bags of specific sizes and contents, safety injection needles, and IV line filters.

The VA was able to use central purchasing/contracting at coordinating centers or the VA Central Office to support investigators and assist with finding supplies and clinical research space. VAMCs with research operating budgets to cover startup costs were better positioned to handle funding delays. During the pandemic, the ORD further contracted to supply administrative support to research offices to address regulatory and other requirements needed for startup activities. The ability to expand such central contracts to procure clinical research staff and outpatient clinical research space may also prove useful in meeting key needs at a site.

Management Roles and Responsibilities

Ambiguous and variable roles and responsibilities among the various partners and stakeholders represented a challenge given the large-scale, national, or international operations involved in the trials. VA attempts to operate uniformly were further limited given that each sponsor or group had preferred methods for operating and/or organizing work under urgent time lines. For example, one trial involved a coordinating center, a contract research organization, and federal partners that each worked with individual sites. Consequently, VA study teams would receive messages that were conflicting or unclear.

The VA learned that studies need a single “source of truth” and/or central command structure in times of urgency. To mitigate conflicting messages, vaccine trials relied on a clearinghouse through the PRP to interpret requirements or work on behalf of all sites before key actions were taken. For studies with the NIAID, the VA relied on experienced staff at the CSP coordinating center at the Perry Point, Maryland, VAMC before beginning. This approach especially helped with the challenges of understaffing and sites’ lack of familiarity with complex platform trial designs and already-established network practices within the ACTIV-2 and ACTIV-3 studies.

Educational Resources and Training

Since VA participation in externally sponsored, multisite clinical trials traditionally relies on an individual VAMC study team and its local resources, transitioning to centralized approaches for COVID-19 multisite studies created barriers. Many VAMCs were unfamiliar with newer capabilities for more rapid regulatory reviews and approvals involving commercial institutional review boards (IRBs) and central VA information security and privacy reviews. While tools and resources were available to facilitate these processes, real-time use had not been fully tested. As a result, everyone had to learn as they went along.

The simultaneous establishment of workflows required the ORD to centralize operations and provide training and guidance to field personnel. Although many principal investigators and clinical research coordinators had trial experience, training required unlearning previous understandings of requirements to meet urgent time lines. ORD enterprise road maps, central tools, and training materials also were made available on a study-by-study basis. Open communication was vital to train on central study materials while opportunities to discuss, question, and share experiences and ideas were promoted. The ORD also sent regular emails to prepare for upcoming work and/or raise awareness of identified challenges.

 

 

Local Review Requirements/Procedures

The clinical trials were impacted by varying VAMC review requirements and approval processes. Although VA policy defines standard requirements, the timing and procedures are left to the individual facility to determine any local factors to accommodate and/or resource availability. While such an approach is well understood within the VA, external sponsors were not as familiar and assumed a more uniform approach across all sites. In response, some VAMCs established ad hoc research and development committee review procedures, allowing study teams to obtain the necessary reviews in a timely fashion. However, not all VAMCs had the infrastructure (especially when clinical personnel had been redeployed to other priorities) to respond with such agility. One critical role of the VA Central Office coordinating entities was to communicate and manage external sponsor and group expectations surrounding individual site review time lines. However, establishing policies and procedures that focus on streamlining local review processes helped to broadly mitigate the COVID-19 trial challenges.

Study Design Demands

The design of COVID-19 studies combined with the uncertainty of the pandemic required rapid protocol changes and adaptations that were often difficult to deliver. The multinetwork trials that the VA collaborated on were platform or master protocol designs. These designs emphasized overall goals (eg, treating patients requiring intensive care unit care). However, because this trial strategy also introduces complexities that may impact review and execution among those unfamiliar with it, there is a need for increased discussion and understanding of this methodology.8 For example, there can be shared control groups, reliance on specific criteria for halting because of safety or futility concerns, or continuation and expansion applied through an external review board. Delays may arise when changes to study protocols occur rapidly or frequently and necessitate new regulatory reviews, negotiation of new agreements, modifications to contracts, changes to entry criteria, etc.

While the VA has adopted a quality by design framework, VA investigators noted many missed opportunities related to looking at outcomes with new diagnostics, studies of serology, outcomes related to vaccinations, and understanding the natural history of disease in these trials.9 The limited opportunities for investigator input suggested that the advantages offered by platform designs were not maximized during pandemic-focused urgencies. It was unclear whether this barrier was created by a general lack of awareness by sponsors or a lack of opportunities. At the very least, quality by design approaches may help avoid redundancies in documentation or study processes at the central and site levels.

Contracting and Budgeting

Given external sponsorship of COVID-19 trials, efficient contracting and budgeting were critical for a rapid start up. The variability of processes associated with these trials created several challenges that were compounded by issues, such as site sub-agreements and budget documents that did not always go to the correct groups and individuals. Furthermore, the VA’s ability to use contracted resources (eg, tents, trailers, personnel) that external sponsors had built into their contracts was more difficult for VA as a federal agency governed by other statues and policies. This also put VAMCs at a disadvantage from a timing perspective, as the VA often required additional time to find equivalent solutions that met federal regulations.

Although the VA was able to establish contract solutions to some issues, time was still lost while working to secure initial funding. Additionally, for needs such as home phlebotomy—commended for convenience to veterans and research staff—and engaging a specialized research team in the Office of General Counsel, early awareness of protocol needs and sponsor solutions could allow VA to pursue alternatives sooner.

Central-Level Systems and Processes

Not all challenges were at the VAMC level. As the ORD explored solutions, it learned that various tools and study platforms were available but not considered. Applications, such as eConsent, and file-sharing platforms that met existing information security and privacy requirements were needed but had to comply with the Privacy Act of 1974, Federal Information Security Modernization Act, and other requirements. Using sponsor-provided devices, such as drug temperature monitoring equipment, required additional review to ensure that they met system requirements for a national health care system. In addition, the VA uses a clinical trials management review system; however, its implementation was new at the time these trials began. Furthermore, the system engaged with some commercial IRBs but not all. This resulted in additional delays as VAMCs and central resources worked to familiarize themselves with the system and procedures.

The ability to work collaboratively across the VA includes having a framework in which key startup processes are standardized. This allows for efficiency and minimizes variability. Also, all stakeholders should understand the importance of holding discussions to identify appropriate solutions, guidance, and instruction. Finally, the VA must strive to be more nimble when adapting technological, regulatory, and financial processes.

 

 

Internal and External Communication

The value of communication—both internal and external—cannot be understated. Minimizing confusion, managing expectations, and ensuring consistent messaging were essential for rapid trial execution. Despite being the second largest federal agency, the VA did not have a seat at the study leadership table for several protocols. When it joined later, several study aspects were set and/or difficult to revise. Challenges affecting time and securing resources have been noted. The ability to plan and then share expectations and responsibilities across and within the respective participating organizations early in the process was perhaps the single factor that was most addressable. The VA enterprise organization and integration with other units could accentuate key communications that would be essential in time-sensitive activities.

VA as a Partner for Future Research

Before the pandemic, the VA had already undertaken a path to enhance its ability to partner as part of the national biomedical research enterprise. The need for COVID-19 therapeutic and vaccine trials accelerated opportunities to plan and develop processes and capabilities to advance this path. As a key strength for VA scientific activities, clinical trials represent a primary medium by which to develop its partnerships. Learning and development have become part of a culture that expedites opportunities for veterans who actively seek ways to contribute to medical knowledge and treatments for their peers and the nation.

CONCLUSIONS

Challenges associated with rapid startup and completion of clinical trials have been discussed for some time. During the pandemic, needs and barriers were magnified because of the heightened urgency for evidence-based therapeutics and vaccines. While the VA faced similar problems as well as those specific to it as a health care system, it had the opportunity to learn and more systematically implement solutions to help in its partnered efforts.10 As an enterprise, the VA hopes to apply lessons learned, strategies, and best practices to further its goals to enhance veteran access to clinical trials and respond to any future need to quickly establish evidence bases in pandemics and other health emergencies that warrant the rapid implementation of research.

Acknowledgments

The activities reported here were supported by the US Department of Veterans Affairs, Office of Research and Development.

The US Department of Veterans Affairs (VA), through its Office of Research and Development (ORD), supports an extensive and experienced clinical research enterprise, including the first multisite trials in the US.1 These resources contribute to the ORD support for the largest US integrated health care system, with a primary focus on the care and well-being of veterans. While the history of VA research has facilitated the creation of an experienced and organized research enterprise, the COVID-19 pandemic challenged VA to contribute even more significantly. These challenges became pronounced given the urgency associated with standing up VA sites for both therapeutic and vaccine trials.

VA Clinical Research Enterprise

The VA recognized an early need for an organized research response not only to address operational challenges resulting from COVID-19 but also ensure that the agency would be ready to support new scientific efforts focused specifically on the virus and related outcomes.2 As a result, the ORD took decisive action first by establishing itself as a central headquarters for VA COVID-19 research activities, and second, by leveraging existing resources, initiatives, and infrastructure to develop new mechanisms that would ensure that the VA was well positioned to develop or participate in research endeavors being driven by the VA as well federal, industry, and non-VA partners.

Prior to the pandemic, the ORD, through its Cooperative Studies Program (CSP), had strategies to address challenges associated with clinical trial startup and improved efficient conduct.3 For example, the VA Network of Dedicated Enrollment Sites (NODES) is a consortium of 23 VA medical centers (VAMCs) dedicated to rapid startup and recruitment into VA-sponsored clinical trials. NODES provides site-level expertise on clinical trial management, including troubleshooting challenges that may occur during clinical research execution.4 Another initiative, Access to Clinical Trials (ACT) for Veterans, engaged industry, academic, patient advocacy, and other partners to identify potential regulatory and operational hurdles to efficient startup activities specific to externally sponsored multisite clinical trials. Under ACT for Veterans, stakeholders emphasized the importance of developing a single VA point of contact for external partners to work with to more efficiently understand and navigate the VA system. In turn, such a resource could be designed to facilitate substantive research and long-term relationships with compatible external partners. Targeted to launch in April 2020, the Partnered Research Program (PRP) was expedited to respond to the pandemic.

During the pandemic, new VA efforts included the creation of the VA CoronavirUs Research and Efficacy Studies (VA CURES) network, initially established as a clinical trial master protocol framework to support and maximize VA-funded COVID-19 trial efficiency.5 VA CURES joined the consortium of trials networks funded by the National Heart, Lung, and Blood Institute. It began treatment trials under Accelerating COVID-19 Therapeutic Interventions and Vaccination (ACTIV), specifically ACTIV-4. The VA also partnered with the National Institutes of Allergy and Infectious Diseases (NIAID) by organizing the VA International Coordinating Center (VA ICC) for other ACTIV trials (ACTIV-2 and -3). When approached to startup studies that included veterans and the VA health care system, these capabilities comprised the VA research response.

A Need for a New Approach

As the impact of the pandemic expanded and the need for effective treatments and vaccines grew, national calls were made to assess the capabilities and readiness of available clinical trials networks. Additionally, the US Department of Health and Human Services Biomedical Advanced Research and Development Authority, ACTIV, NIAID Division of Clinical Research and Division of AIDS, and many pharmaceutical companies were starting to roll out trials of new therapeutics and vaccines. These groups approached the VA to help evaluate the safety and efficacy of several therapeutics and vaccines because they recognized several advantages of the VA enterprise, including its position as the nation’s largest integrated health care system, its diverse patient population, and its expertise in conducting clinical trials.

Although the VA was well positioned as an important player in a collaborative investigational approach to COVID-19 research, these trials required startup approaches that were significantly different from those it had employed in traditional, prepandemic, clinical research. Despite the VA being a single federal agency, each VAMC conducting research establishes its own practices to address both operational and regulatory requirements. This structure results in individual units that operate under different standard operating procedures. Efforts must be taken centrally to organize them into a singular network for the entire health care system. During a national crisis, when there was a need for rapid trial startup to answer safety and efficacy questions and participate under a common approach to protocol execution, this variability was neither manageable nor acceptable. Additionally, the intense resource demands associated with such research, coupled with frequent reporting requirements by VA leaders, Congress, and the White House, required that VAMCs function more like a single unit. Therefore, the ORD needed to develop VAMCs’ abilities to work collectively toward a common goal, share knowledge and experience, and capitalize on potential efficiencies concerning legal, regulatory, and operational processes.

table

Beginning August 2020, 39 VAMCs joined 7 large-scale collaborative COVID-19 therapeutic and vaccine trials. Through its COVID-19 Research Response Team, the ORD identified, engaged, and directed appropriate resources to support the VAMC under a centralized framework for study management (Table). Centralized management not only afforded VAMCs the opportunity to work more collectively and efficiently but also provided an important advantage by enabling the VA to collect and organize its experiences (and on occasion data) to provide a base for continual learning and improvement efforts. While others have described efforts undertaken across networks to advance learning health systems, the VA’s national scope and integration of research and clinical care allow greater opportunities to learn in a practical setting.6

 

 

Challenges and Best Practices

Using surveys, webinars, interviews, and observation from site and VA Central Office personnel, the ORD identified specific variables that prevented the VAMCs from quickly starting up as a clinical trial site. We also documented strategies, solutions, and recommendations for improving startup time lines. These were organized into 8 categories: (1) site infrastructure needs and capabilities; (2) study management roles and responsibilities; (3) educational resources and training; (4) local review requirements and procedures; (5) study design demands; (6) contracting and budgeting; (7) central-level systems and processes; and (8) communication between external partners and within the VA.

Site Infrastructure Needs and Capabilities

A primary impediment to rapid study startup was a lack of basic infrastructure, including staff, space, and the agility necessary for the changing demands of high-priority, high-enrolling trials. This observation is not unique to the VA.7 Initially, certain facilities located in hot spots where COVID-19 was more prevalent became high-interest targets for study placement, despite varying degrees of available research infrastructure. Furthermore, pandemic shutdowns and quarantines permitted fewer employees onsite. This resulted in inadequate staffing in personnel needed to support required startup activities and those needed to handle the high volume of study participants who were being recruited, screened, enrolled, and followed. Additionally, as clinical care needs and infection control practices were prioritized, clinical research space was often appropriated for these needs, making it difficult to find the space to conduct trials. Lastly, supply chain issues also posed unique challenges, sometimes making it difficult for participating VAMCs to obtain needed materials, such as IV solution bags of specific sizes and contents, safety injection needles, and IV line filters.

The VA was able to use central purchasing/contracting at coordinating centers or the VA Central Office to support investigators and assist with finding supplies and clinical research space. VAMCs with research operating budgets to cover startup costs were better positioned to handle funding delays. During the pandemic, the ORD further contracted to supply administrative support to research offices to address regulatory and other requirements needed for startup activities. The ability to expand such central contracts to procure clinical research staff and outpatient clinical research space may also prove useful in meeting key needs at a site.

Management Roles and Responsibilities

Ambiguous and variable roles and responsibilities among the various partners and stakeholders represented a challenge given the large-scale, national, or international operations involved in the trials. VA attempts to operate uniformly were further limited given that each sponsor or group had preferred methods for operating and/or organizing work under urgent time lines. For example, one trial involved a coordinating center, a contract research organization, and federal partners that each worked with individual sites. Consequently, VA study teams would receive messages that were conflicting or unclear.

The VA learned that studies need a single “source of truth” and/or central command structure in times of urgency. To mitigate conflicting messages, vaccine trials relied on a clearinghouse through the PRP to interpret requirements or work on behalf of all sites before key actions were taken. For studies with the NIAID, the VA relied on experienced staff at the CSP coordinating center at the Perry Point, Maryland, VAMC before beginning. This approach especially helped with the challenges of understaffing and sites’ lack of familiarity with complex platform trial designs and already-established network practices within the ACTIV-2 and ACTIV-3 studies.

Educational Resources and Training

Since VA participation in externally sponsored, multisite clinical trials traditionally relies on an individual VAMC study team and its local resources, transitioning to centralized approaches for COVID-19 multisite studies created barriers. Many VAMCs were unfamiliar with newer capabilities for more rapid regulatory reviews and approvals involving commercial institutional review boards (IRBs) and central VA information security and privacy reviews. While tools and resources were available to facilitate these processes, real-time use had not been fully tested. As a result, everyone had to learn as they went along.

The simultaneous establishment of workflows required the ORD to centralize operations and provide training and guidance to field personnel. Although many principal investigators and clinical research coordinators had trial experience, training required unlearning previous understandings of requirements to meet urgent time lines. ORD enterprise road maps, central tools, and training materials also were made available on a study-by-study basis. Open communication was vital to train on central study materials while opportunities to discuss, question, and share experiences and ideas were promoted. The ORD also sent regular emails to prepare for upcoming work and/or raise awareness of identified challenges.

 

 

Local Review Requirements/Procedures

The clinical trials were impacted by varying VAMC review requirements and approval processes. Although VA policy defines standard requirements, the timing and procedures are left to the individual facility to determine any local factors to accommodate and/or resource availability. While such an approach is well understood within the VA, external sponsors were not as familiar and assumed a more uniform approach across all sites. In response, some VAMCs established ad hoc research and development committee review procedures, allowing study teams to obtain the necessary reviews in a timely fashion. However, not all VAMCs had the infrastructure (especially when clinical personnel had been redeployed to other priorities) to respond with such agility. One critical role of the VA Central Office coordinating entities was to communicate and manage external sponsor and group expectations surrounding individual site review time lines. However, establishing policies and procedures that focus on streamlining local review processes helped to broadly mitigate the COVID-19 trial challenges.

Study Design Demands

The design of COVID-19 studies combined with the uncertainty of the pandemic required rapid protocol changes and adaptations that were often difficult to deliver. The multinetwork trials that the VA collaborated on were platform or master protocol designs. These designs emphasized overall goals (eg, treating patients requiring intensive care unit care). However, because this trial strategy also introduces complexities that may impact review and execution among those unfamiliar with it, there is a need for increased discussion and understanding of this methodology.8 For example, there can be shared control groups, reliance on specific criteria for halting because of safety or futility concerns, or continuation and expansion applied through an external review board. Delays may arise when changes to study protocols occur rapidly or frequently and necessitate new regulatory reviews, negotiation of new agreements, modifications to contracts, changes to entry criteria, etc.

While the VA has adopted a quality by design framework, VA investigators noted many missed opportunities related to looking at outcomes with new diagnostics, studies of serology, outcomes related to vaccinations, and understanding the natural history of disease in these trials.9 The limited opportunities for investigator input suggested that the advantages offered by platform designs were not maximized during pandemic-focused urgencies. It was unclear whether this barrier was created by a general lack of awareness by sponsors or a lack of opportunities. At the very least, quality by design approaches may help avoid redundancies in documentation or study processes at the central and site levels.

Contracting and Budgeting

Given external sponsorship of COVID-19 trials, efficient contracting and budgeting were critical for a rapid start up. The variability of processes associated with these trials created several challenges that were compounded by issues, such as site sub-agreements and budget documents that did not always go to the correct groups and individuals. Furthermore, the VA’s ability to use contracted resources (eg, tents, trailers, personnel) that external sponsors had built into their contracts was more difficult for VA as a federal agency governed by other statues and policies. This also put VAMCs at a disadvantage from a timing perspective, as the VA often required additional time to find equivalent solutions that met federal regulations.

Although the VA was able to establish contract solutions to some issues, time was still lost while working to secure initial funding. Additionally, for needs such as home phlebotomy—commended for convenience to veterans and research staff—and engaging a specialized research team in the Office of General Counsel, early awareness of protocol needs and sponsor solutions could allow VA to pursue alternatives sooner.

Central-Level Systems and Processes

Not all challenges were at the VAMC level. As the ORD explored solutions, it learned that various tools and study platforms were available but not considered. Applications, such as eConsent, and file-sharing platforms that met existing information security and privacy requirements were needed but had to comply with the Privacy Act of 1974, Federal Information Security Modernization Act, and other requirements. Using sponsor-provided devices, such as drug temperature monitoring equipment, required additional review to ensure that they met system requirements for a national health care system. In addition, the VA uses a clinical trials management review system; however, its implementation was new at the time these trials began. Furthermore, the system engaged with some commercial IRBs but not all. This resulted in additional delays as VAMCs and central resources worked to familiarize themselves with the system and procedures.

The ability to work collaboratively across the VA includes having a framework in which key startup processes are standardized. This allows for efficiency and minimizes variability. Also, all stakeholders should understand the importance of holding discussions to identify appropriate solutions, guidance, and instruction. Finally, the VA must strive to be more nimble when adapting technological, regulatory, and financial processes.

 

 

Internal and External Communication

The value of communication—both internal and external—cannot be understated. Minimizing confusion, managing expectations, and ensuring consistent messaging were essential for rapid trial execution. Despite being the second largest federal agency, the VA did not have a seat at the study leadership table for several protocols. When it joined later, several study aspects were set and/or difficult to revise. Challenges affecting time and securing resources have been noted. The ability to plan and then share expectations and responsibilities across and within the respective participating organizations early in the process was perhaps the single factor that was most addressable. The VA enterprise organization and integration with other units could accentuate key communications that would be essential in time-sensitive activities.

VA as a Partner for Future Research

Before the pandemic, the VA had already undertaken a path to enhance its ability to partner as part of the national biomedical research enterprise. The need for COVID-19 therapeutic and vaccine trials accelerated opportunities to plan and develop processes and capabilities to advance this path. As a key strength for VA scientific activities, clinical trials represent a primary medium by which to develop its partnerships. Learning and development have become part of a culture that expedites opportunities for veterans who actively seek ways to contribute to medical knowledge and treatments for their peers and the nation.

CONCLUSIONS

Challenges associated with rapid startup and completion of clinical trials have been discussed for some time. During the pandemic, needs and barriers were magnified because of the heightened urgency for evidence-based therapeutics and vaccines. While the VA faced similar problems as well as those specific to it as a health care system, it had the opportunity to learn and more systematically implement solutions to help in its partnered efforts.10 As an enterprise, the VA hopes to apply lessons learned, strategies, and best practices to further its goals to enhance veteran access to clinical trials and respond to any future need to quickly establish evidence bases in pandemics and other health emergencies that warrant the rapid implementation of research.

Acknowledgments

The activities reported here were supported by the US Department of Veterans Affairs, Office of Research and Development.

References

1. Hays MT; US Department of Veterans Affairs, Veterans Health Administration, Office of Research and Development. A historical look at the establishment of the Department of Veterans Affairs Research & Development Program. Accessed August 28, 2023. https://www.research.va.gov/pubs/docs/ORD-85yrHistory.pdf

2. Garcia AP, Huang GD, Arnheim L, Ramoni R, Clancy C. The VA research enterprise: a platform for national partnerships toward evidence building and scientific innovation. Fed Pract. 2023;40(suppl 5):S12-S17. doi:10.12788/fp.0425

3. Johnston SC, Lewis-Hall F, Bajpai A, et al. It’s time to harmonize clinical trial site standards. NAM Perspectives. October 9, 2017. Accessed August 28, 2023. https://nam.edu/wp-content/uploads/2017/10/Its-Time-to-Harmonize-Clinical-Trial-Site-1.pdf

4. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: the Department of Veterans Affairs’ Network of Dedicated Enrollment Sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

5. US Food and Drug Administration. Master protocols: efficient clinical trial design strategies to expedite development of oncology drugs and biologics guidance for industry. March 2022. Accessed August 23, 2023. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/master-protocols-efficient-clinical-trial-design-strategies-expedite-development-oncology-drugs-and

6. IOM Roundtable on Value & Science-Driven Care; Institute of Medicine. Continuous learning and improvement in health care. In: Integrating Research and Practice: Health System Leaders Working Toward High-Value Care: Workshop Summary. National Academies Press (US); 2015:chap 2. Accessed August 28, 2023. https://www.ncbi.nlm.nih.gov/books/NBK284654 7. Institute of Medicine (US). Building an infrastructure to support clinical trials. In: Envisioning a Transformed Clinical Trials Enterprise in the United States. National Academies Press (US); 2012:chap 5. Accessed August 28, 2023. https://www.ncbi.nlm.nih.gov/books/NBK114656

8. Park JJH, Harari O, Dron L, Lester RT, Thorlund K, Mills EJ. An overview of platform trials with a checklist for clinical readers. J Clin Epidemiol. 2020;125:1-8. doi:10.1016/j.jclinepi.2020.04.025

9. Meeker-O’Connell A, Glessner C, Behm M, et al. Enhancing clinical evidence by proactively building quality into clinical trials. Clin Trials. 2016;13(4):439-444. doi:10.1177/1740774516643491

10. McClure J, Asghar A, Krajec A, et al. Clinical trial facilitators: a novel approach to support the execution of clinical research at the study site level. Contemp Clin Trials Commun. 2023;33:101106. doi:10.1016/j.conctc.2023.101106

References

1. Hays MT; US Department of Veterans Affairs, Veterans Health Administration, Office of Research and Development. A historical look at the establishment of the Department of Veterans Affairs Research & Development Program. Accessed August 28, 2023. https://www.research.va.gov/pubs/docs/ORD-85yrHistory.pdf

2. Garcia AP, Huang GD, Arnheim L, Ramoni R, Clancy C. The VA research enterprise: a platform for national partnerships toward evidence building and scientific innovation. Fed Pract. 2023;40(suppl 5):S12-S17. doi:10.12788/fp.0425

3. Johnston SC, Lewis-Hall F, Bajpai A, et al. It’s time to harmonize clinical trial site standards. NAM Perspectives. October 9, 2017. Accessed August 28, 2023. https://nam.edu/wp-content/uploads/2017/10/Its-Time-to-Harmonize-Clinical-Trial-Site-1.pdf

4. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: the Department of Veterans Affairs’ Network of Dedicated Enrollment Sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

5. US Food and Drug Administration. Master protocols: efficient clinical trial design strategies to expedite development of oncology drugs and biologics guidance for industry. March 2022. Accessed August 23, 2023. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/master-protocols-efficient-clinical-trial-design-strategies-expedite-development-oncology-drugs-and

6. IOM Roundtable on Value & Science-Driven Care; Institute of Medicine. Continuous learning and improvement in health care. In: Integrating Research and Practice: Health System Leaders Working Toward High-Value Care: Workshop Summary. National Academies Press (US); 2015:chap 2. Accessed August 28, 2023. https://www.ncbi.nlm.nih.gov/books/NBK284654 7. Institute of Medicine (US). Building an infrastructure to support clinical trials. In: Envisioning a Transformed Clinical Trials Enterprise in the United States. National Academies Press (US); 2012:chap 5. Accessed August 28, 2023. https://www.ncbi.nlm.nih.gov/books/NBK114656

8. Park JJH, Harari O, Dron L, Lester RT, Thorlund K, Mills EJ. An overview of platform trials with a checklist for clinical readers. J Clin Epidemiol. 2020;125:1-8. doi:10.1016/j.jclinepi.2020.04.025

9. Meeker-O’Connell A, Glessner C, Behm M, et al. Enhancing clinical evidence by proactively building quality into clinical trials. Clin Trials. 2016;13(4):439-444. doi:10.1177/1740774516643491

10. McClure J, Asghar A, Krajec A, et al. Clinical trial facilitators: a novel approach to support the execution of clinical research at the study site level. Contemp Clin Trials Commun. 2023;33:101106. doi:10.1016/j.conctc.2023.101106

Issue
Federal Practitioner - 40(5)s
Issue
Federal Practitioner - 40(5)s
Page Number
S18
Page Number
S18
Publications
Publications
Topics
Article Type
Sections
Disallow All Ads
Content Gating
No Gating (article Unlocked/Free)
Alternative CME
Disqus Comments
Default
Use ProPublica
Hide sidebar & use full width
render the right sidebar.
Conference Recap Checkbox
Not Conference Recap
Clinical Edge
Display the Slideshow in this Article
Medscape Article
Display survey writer
Reuters content
Disable Inline Native ads
WebMD Article
Article PDF Media

The VA Research Enterprise: A Platform for National Partnerships Toward Evidence Building and Scientific Innovation

Article Type
Changed
Tue, 10/31/2023 - 15:58

The US Department of Veterans Affairs (VA) plays a substantial role in the nation’s public health through the Veterans Health Administration (VHA). Its statutory missions of teaching, clinical care, and research enable it to serve a foundational role in the US biomedical enterprise.1 Throughout its extensive network of VA medical centers (VAMCs) and partnering academic affiliates, thousands of clinicians and researchers have been trained to improve the lives of veterans and benefit the lives of all Americans. In supporting the largest US integrated health care system, the VA also has numerous capabilities and resources that distinctively position it to produce scientific and clinical results specifically within the context of providing care. The VA has formed partnerships with other federal agencies, industry, and nonprofit entities. Its ability to be a nexus of health care and practice, scientific discovery, and innovative ways to integrate shared interests in these areas have led to many transformative endeavors that save lives and improve the quality of care for veterans and the public.

The COVID-19 pandemic triggered another mission: service in times of national emergency. Known as the Fourth Mission, the VA rapidly shifted to highlight how its health care and research enterprises could apply strengths in a unique, coordinated manner. While the Fourth Mission is typically considered in the context of clinical care, the VA’s movement toward greater integration facilitated the role of research as a key component in efforts under a learning health care model.2

VA Office of Research and Development

Within the VHA, the Office of Research and Development (ORD) develops research policy and oversees interdisciplinary efforts focused on generating evidence to improve veteran health.3 These activities span at least 100 of 171 VAMCs and include thousands of investigators and staff across all major health research disciplines. Many of these investigators are also clinicians who provide patient care and are experts in the prevention, diagnosis, and treatment of diseases and disorders affecting veterans.

The ORD has invested in a range of scientific, operational, regulatory, and technological assets and infrastructure as part of its enterprise. These strengths come from a nearly 100-year history originating as part of a set of hospital-based medical studies. This established the model for a culture of cooperative research within the VA and with external groups who benefit from the VA’s foundational role in multisite clinical trials.2,4,5 Today, the VA prioritizes bench-to-bedside research covering a broad spectrum of investigations, which are integrated with clinical operations and systems that deliver care.3 The VA supports an extensive range of work that covers core areas in preclinical and clinical studies to health services research, rehabilitation and implementation science, establishing expertise in genomic and data sciences, and more recent activities in artificial intelligence.

In 2017, the ORD began a focused strategy to transform into a national enterprise that capitalized on its place within the VA and its particular ability to translate and implement scientific findings into real impact for veteran health and care through 5 initiatives: (1) enhancing veteran access to high-quality clinical trials; (2) increasing the substantial real-world impact of VA Research; (3) putting VA data to work for veteran health; (4) promoting diversity, equity, and inclusion within our sphere of influence; and (5) building community through research. These activities are interrelated and, where possible, the ORD works with other VA clinical and operational offices to accomplish multiple goals and coordinate within the health care system. As such, the VA continually seeks to increase efficiencies and improve abilities that provide veterans with best-in-class health care. While still in its early stages, this strategy and its initiatives established a path for the ORD response to the pandemic.

Within 2 weeks of the World Health Organization and the US declaring a COVID-19 pandemic, the ORD began to address the developing needs and challenges of the yet unknown emerging public health threat. This included outreach to and contact from federal, academic, and industry partners. At the same time, the ORD maintained its focus and energy to support its ongoing veteran-centric research portfolio and VHA health care system needs across its broad scope of activities.

This article discusses how the pandemic accelerated the VA’s research enterprise strategy and enacted a response, highlighting the advantages and strengths of this direction. We demonstrate how this evolving strategy enabled the VA to quickly leverage partnerships during a health emergency. While the ORD and VA Research have been used interchangeably, we will attempt to distinguish between the office that serves as headquarters for the national enterprise—the ORD—and the components of that enterprise composed of scientific personnel, equipment, operational units, and partners—VA Research. Finally, we present lessons from this experience toward a broader, post–COVID-19, enterprise-wide approach that the VA has for providing evidence-based care. These experiences may enrich our understanding of postpandemic future research opportunities with the VA as a leader and partner who leverages its commitment to veterans to improve the nation’s health.

 

 

ORGANIZING THE VA COVID-19 RESEARCH RESPONSE

VA Research seeks to internally standardize and integrate collaborations with clinical and operational partners throughout the agency. When possible, it seeks to streamline partnership efforts involving external groups less familiar with how the VA operates or its policies, as well as its capabilities. This need was more obvious during the pandemic, and the ORD assembled its COVID-19 response quickly.6

figure

In early January 2020, VA offices, including the ORD, were carefully observing COVID-19. On March 4, 2020, a week before the World Health Organization declared COVID-19 a pandemic, the ORD and its National Research Advisory Council arranged a briefing from VA public health leaders to deal with reported cases of COVID-19 and VA plans. Immediately afterward, the ORD Chief Research and Development Officer gathered a team of experts in clinical research, infectious disease, and public health to strategize a broader research enterprise approach to the pandemic. This group quickly framed 3 key targets: (1) identify critical research questions to prioritize; (2) provide operational guidance to the research community; and (3) uphold VA research staff safety. This discussion led to the creation of a larger ORD COVID-19 Research Response Team that managed activities within this scope. This team included other ORD leaders and staff with operational, scientific, and regulatory expertise charged with enterprise-level planning and execution for all research activities addressing or affected by the pandemic (Figure).

Effective and timely communication was chief among key ORD responsibilities. On March 19, 2020, the Response Team informed the VA Research community about ORD plans for organizing the VA COVID-19 research response.7 It also mobilized VA research programs and investigators to support an enterprise approach that would be coordinated centrally. We achieved communication goals by developing a dedicated website, which provided a means to distribute up-to-date notices and guidance, answer frequently asked questions, and alert investigators about research opportunities. The site enabled the field to report on its efforts, which enhanced leadership and community awareness. A working group of ORD and field personnel managed communications. Given the volume of existing non–COVID-19 research, we established a research continuity of operations plan to provide guidelines for study participant and research staff safety. The ORD issued an unprecedented full-stop administrative hold on in-person research activities after the global announcement of the pandemic. This policy provided formal protections for research programs to safeguard staff and research participants and to determine appropriate alternatives to conduct research activities within necessary social distancing, safety, and other clinical care parameters. It also aligned with guidance and requirements that local VAMCs issued for their operations and care priorities.

The Response Team also established a scientific steering committee of VA infectious disease, critical care, informatics, and epidemiology experts to prioritize research questions, identify research opportunities, and evaluate proposals using a modified expeditious scientific review process. This group also minimized duplicate scientific efforts that might be expected from a large pool of investigators simultaneously pursuing similar research questions. Committee recommendations set up a portfolio that included basic science efforts in diagnostics, clinical trials, population studies, and research infrastructure.

 

 

Leveraging Existing Infrastructure

Besides quickly organizing a central touchpoint for the VA COVID-19 research response, the ORD capitalized on its extensive nationwide infrastructure. One key component was the Cooperative Studies Program (CSP); the longstanding VA clinical research enterprise that supports the planning and conduct of large multicenter clinical trials and epidemiological studies. The CSP includes experts at 5 data and statistical coordinating centers, a clinical research pharmacy coordinating center, and 4 epidemiological resource centers.8 CSP studies provide definitive evidence for clinical practice and care of veterans and the nation. CSP’s CONFIRM trial (CSP 577) is the largest VA interventional study with > 50,000 veterans.9 CONFIRM followed the Trial of Varicella Zoster Vaccine for the Prevention of Herpes Zoster and Its Complications (CSP 403), which involved > 38,000 participants to evaluate a vaccine to reduce the burden of illness-associated herpes zoster (shingles). In the study, the vaccine markedly reduced the shingles burden of illness among older adults.10 These studies highlight the CSP cohort development ability as evidenced by the Million Veteran Program.11

VA Research, particularly through the CSP, contributed to multiple federal actions for COVID-19. The CSP had already established partnerships with federal and industry groups in multisite clinical trials and observational studies. During COVID-19, the ORD established a COVID-19 clinical trial master protocol framework: the VA CoronavirUs Research & Efficacy Studies network.9 The CSP also supported studies by the Coronavirus Prevention Network, the National Institute of Allergy and Infectious Disease (NIAID), and the US Food and Drug Administration (FDA). As such, the VA could translate requirements in working with an industry sponsor on the rapid execution of studies within a federal health care system. Much of the success arose when there was either earlier engagement in planning and/or existing familiarity among parties with operational and regulatory requirements.

table 1

Before the pandemic, the ORD had also been working on various external partnerships to increase opportunities for veterans in clinical trial participation, particularly for cancer, which Caroff and colleagues discuss further.12 A newly emerging Partnered Research Program (PRP) offered a strategy for participation in the major COVID-19 vaccine efficacy clinical trials. VA Research, through PRP and CSP, rapidly engaged others and managed critical communication (Table 1). In quickly pivoting to COVID-19 clinical studies, the VA also used the Networks of Dedicated Enrollment Sites (NODES), its site-based, CSP-supported infrastructure of existing investigators and coordinators with clinical, operational, and regulatory proficiency for large trials.13,14 Together, the CSP and PRP solidified the VA’s scientific, operational, and regulatory support basis for working with industry partners and federal agencies to conduct therapeutic and vaccine trials.

Speed, Knowledge, and Safety

The scope of VA Research partnerships covers several goals but can be broadly categorized in the following ways: research aimed at evaluating the efficacy of new treatments; development of infrastructure to facilitate more rapid and innovative approaches to research; and building connections within the health care system to take an enterprise approach to research.

Activities are not limited to COVID-19. The VA partners with federal entities on research primarily through interagency agreements whose authorities are derived from the Economy Act (31 USC § 1535). For industry and nonfederal groups, the VA enters into Cooperative Research and Development Agreements that are rooted in the Federal Technology Transfer Act (15 USC § 3710). Although the VA has experience in each of these processes, COVID-19 prompted many groups, existing partners and new ones, to engage with the VA. Consequently, the ORD needed to quickly understand the complexities of how to handle such engagements on a larger scale. The VA Research enterprise strategy also focused on facilitating these processes.

As part of VA integration goals, ORD leaders engaged VA clinical leaders, especially in Public Health, Preventive Medicine, Pharmacy Benefits Management, and Pathology and Laboratory services. The ORD also worked closely with operational leaders, including those responsible for the Veterans Integrated Service Networks and VAMC chiefs of staff and network chief medical officers. The ORD’s familiarity with coordinating complex activities for research further helped to organize nonresearch responses for clinical needs and resources to support the VA COVID-19 response. The Office of the Under Secretary for Health recognized VA Research’s critical role as part of the VA health care system. In turn, it served as a major champion to drive success among the active research efforts, especially the partnered efforts, responding to COVID-19. Continuously communicating support and offering resources for the agency’s overall COVID-19 response reinforced the positive impact of VA Research that extended beyond its traditional roles. That is, the research component of VHA was highlighted as an integral part of the COVID-19 response along with its clinical operations. This integrated approach was perhaps best demonstrated in a VHA-wide push to start and conduct the national vaccine efficacy trials.

Other COVID-19 research supported by the ORD included participation in the Mayo Clinic–led convalescent plasma expanded access treatment protocol, which had emerged as a potential therapeutic option.15 The ORD provided centralized regulatory support to nearly 100 VAMCs, helping to reduce inconsistencies in protocol approval processes for what was hoped to be a promising treatment for COVID-19.16 This rapid approach to address a real-time treatment option demonstrated the VA Research capability for swift mobilization in an emergency.

The ORD also coordinated with other federal agencies. For example, it collaborated with the US Department of Defense to begin a parallel observational study on COVID-19 infections and potential severe outcomes. The study enrolled > 3000 veterans who are being followed for up to 2 years to better understand the natural history and course of COVID-19.17 Other interagency efforts focused on vaccine and therapeutic trials, including Accelerating COVID-19 Therapeutic Interventions and Vaccines (ACTIV) with the National Institutes of Health. In these activities, VA Research helped increase recruitment, particularly of a more diverse patient population, in helping to assess promising treatments.10

table 2

Motivated by its expanding portfolio of COVID-19 intervention studies, the VA also created a COVID-19 research registry for all VA investigators. This registry included almost 59,000 veterans who indicated a willingness to volunteer for clinical studies. This registry exemplified a long-standing tradition of veterans willing to serve their nation again in a time of need. Iaquinto and colleagues showcased how VHA programs (eg, Office of Healthcare Innovation and Learning) collaborated by expediting a study on 3D-printed swabs to address supply chain shortages. The study, which involved the FDA, showed that the printed swabs were as effective as commercially available ones.18 It provided evidence supporting the production and dissemination of a greater number of testing swabs to the public while also reducing the cost and time requirements (Table 2).

Altogether, these collaborative efforts advanced a transformative approach within the VA that was already happening but was accelerated by the pandemic. Such activities enabled greater understanding throughout the VA for how research is not merely complementary but an integrated part of how veterans receive health care. By giving opportunities to veterans to participate in studies, especially clinical studies, the VA created a path in which such expectations, understanding, and operations were more fluid.

 

 

Future Directions

The VA continues to work for veterans by emphasizing its strategic goals and strengths in clinical, data science, and other pioneering activities at an enterprise level to provide the highest quality evidence for care. These capabilities perpetuate a scientific and learning environment that also builds toward the future by giving junior investigators and others opportunities to work within a national health care setting. In turn, this provides a more focused perspective on endeavors that align with the VA mission through ORD-supported career development, merit review (independent investigator submissions), and CSP.19 Preclinical, health services, genomic, and implementation research were given insights into more effective operational and methodological partnerships to help inform the health care system. The pandemic also served to strengthen our ability to mobilize and prepare even faster for emergencies and other potential disease outbreaks, including newer pandemic concerns (eg, mpox, Ebola) from research and public health perspectives.

Conclusions

Throughout its 100-year history, VA Research has been a critical, enduring institution within the national medical landscape. The ability to collaborate with partners has helped us to design and create even better processes, optimize and maximize our infrastructure, and learn more about common research interests that can be even more responsive to national health care needs. As an enterprise, VA Research also aims to continually learn and expand on these valuable lessons gained from internal, interagency, and industry collaborations to effectively meet and exceed our mission to serve our veterans.

Acknowledgments

The authors acknowledge Daphne Swancutt for her contribution as copywriter for this manuscript.

References

1. US Department of Veterans Affairs. Functional organization manual: description of organization, structure, missions, functions, tasks, and authorities. Version 6. 2020. Accessed September 11, 2023. https://www.va.gov/VA-Functional-Organization-Manual-2020-4.pdf

2. Kilbourne AM, Schmidt J, Edmunds M, Vega R, Bowersox N, Atkins D. How the VA is training the next-generation workforce for learning health systems. Learn Health Syst. 2022;6(4):e10333. Published 2022 Aug 16. doi:10.1002/lrh2.10333

3. O’Leary TJ, Dominitz JA, Chang KM. Veterans Affairs office of research and development: research programs and emerging opportunities in digestive diseases research. Gastroenterology. 2015;149(7):1652-1661. doi:10.1053/j.gastro.2015.10.021

4. Tucker WB. The evolution of the cooperative studies in the chemotherapy of tuberculosis of the Veterans Administration and armed forces of the U.S.A. An account of the evolving education of the physician in clinical pharmacology. Bibl Tuberc. 1960;15:1-68.

5. Hays MT; Veterans Health Administration. A historical look at the establishment of the Department of Veterans Affairs research & development program. https://www.research.va.gov/pubs/docs/ORD-85yrHistory.pdf

6. US Department of Veterans Affairs, Veterans Health Administration. Coronavirus Disease 2019 (COVID-19) response report – annex a. May 10, 2021. Accessed September 11, 2023. https://www.va.gov/health/docs/VHA-COVID-19-Response-2021.pdf

7. US Department of Veterans Affairs, Veterans Health Administration. ORD Research Response to COVID-19. US Department of Veterans Affairs. Updated March 24, 2020. Accessed September 11, 2023. www.research.va.gov/programs/orppe/education/webinars/orppe-031920.cfm

8. Burnaska DR, Huang GD, O’Leary TJ. Clinical trials proposed for the VA cooperative studies program: success rates and factors impacting approval. Contemp Clin Trials Commun. 2021;23:100811. Published 2021 Jul 9. doi:10.1016/j.conctc.2021.100811

9. US Department of Veterans Affairs. VA CoronavirUs Research & Efficacy Studies (VA CURES). Updated January 6, 2022. Accessed September 11, 2023. https://www.research.va.gov/services/csrd/va_cures/default.cfm

10. Oxman MN, Levin MJ, Johnson GR, et al. A vaccine to prevent herpes zoster and postherpetic neuralgia in older adults. N Engl J Med. 2005;352(22):2271-2284. doi:10.1056/NEJMoa051016

11. Whitbourne SB, Moser J, Cho K, et al. Leveraging the Million Veteran Program infrastructure and data for a rapid research response to COVID-19. Fed Pract. 2023;40(suppl 5):S23-S28. doi:10.12788/fp.0416

12. Caroff K, Davey V, Smyth M, et al. VA lessons from partnering in COVID-19 clinical trials. Fed Pract. 2023;40(suppl 5): S18-S22. doi:10.12788/fp.0415

13. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: the Department of Veterans Affairs’ network of dedicated enrollment sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

14. McClure J, Asghar A, Krajec A, et al. Clinical trial facilitators: a novel approach to support the execution of clinical research at the study site level. Contemp Clin Trials Commun. 2023;33:101106. doi:10.1016/j.conctc.2023.101106

15. Joyner M. Expanded access to convalescent plasma for the treatment of patients with COVID-19. ClinicalTrials.gov identifier: NCT04338360. April 8, 2020. Updated September 2, 2020. Accessed September 11, 2023. https://clinicaltrials.gov/ct2/show/NCT04338360

16. Joyner MJ, Wright RS, Fairweather D, et al. Early safety indicators of COVID-19 convalescent plasma in 5000 patients. J Clin Invest. 2020;130(9):4791-4797. doi:10.1172/JCI140200

17. Lee JS, Smith NL. Epidemiology, immunology and clinical characteristics of COVID-19 (EPIC3). ClinicalTrials.gov identifier: NCT05764083. March 10, 2023. Updated August 1, 2023. Accessed September 11, 2023. https://clinicaltrials.gov/ct2/show/NCT05764083

18. Iaquinto J, Ripley B, Dorn PA. How VA innovative partnerships and health care system can respond to national needs: NOSE trial example. Fed Pract. 2023;40(suppl 5):S52-S56. doi:10.12788/fp.0418

19. US Department of Veterans Affairs. Health Services Research & Development research career development program. Updated March 4, 2021. Accessed September 11, 2023. https://hsrd.research.va.gov/cdp/

Article PDF
Author and Disclosure Information

Amanda P. Garcia, MPHa; Grant D. Huang, MPH, PhDa; Louise Arnheim, MPAb; Rachel B. Ramoni, DMD, ScDa; Carolyn M. Clancy, MDb

Correspondence:  Amanda Garcia  (amanda.garcia@va.gov)

Author affiliations

aOffice of Research and Development, Department of Veterans Affairs, Washington, DC

bOffice of Discovery, Education and Affiliate Networks, Department of Veterans Affairs, Washington, DC

Author disclosures

The authors report no actual or potential conflicts of interest or outside sources of funding with regard to this article.

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the US Government, or any of its agencies.

Ethics and consent

Not applicable.

Issue
Federal Practitioner - 40(5)s
Publications
Topics
Page Number
S12
Sections
Author and Disclosure Information

Amanda P. Garcia, MPHa; Grant D. Huang, MPH, PhDa; Louise Arnheim, MPAb; Rachel B. Ramoni, DMD, ScDa; Carolyn M. Clancy, MDb

Correspondence:  Amanda Garcia  (amanda.garcia@va.gov)

Author affiliations

aOffice of Research and Development, Department of Veterans Affairs, Washington, DC

bOffice of Discovery, Education and Affiliate Networks, Department of Veterans Affairs, Washington, DC

Author disclosures

The authors report no actual or potential conflicts of interest or outside sources of funding with regard to this article.

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the US Government, or any of its agencies.

Ethics and consent

Not applicable.

Author and Disclosure Information

Amanda P. Garcia, MPHa; Grant D. Huang, MPH, PhDa; Louise Arnheim, MPAb; Rachel B. Ramoni, DMD, ScDa; Carolyn M. Clancy, MDb

Correspondence:  Amanda Garcia  (amanda.garcia@va.gov)

Author affiliations

aOffice of Research and Development, Department of Veterans Affairs, Washington, DC

bOffice of Discovery, Education and Affiliate Networks, Department of Veterans Affairs, Washington, DC

Author disclosures

The authors report no actual or potential conflicts of interest or outside sources of funding with regard to this article.

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the US Government, or any of its agencies.

Ethics and consent

Not applicable.

Article PDF
Article PDF

The US Department of Veterans Affairs (VA) plays a substantial role in the nation’s public health through the Veterans Health Administration (VHA). Its statutory missions of teaching, clinical care, and research enable it to serve a foundational role in the US biomedical enterprise.1 Throughout its extensive network of VA medical centers (VAMCs) and partnering academic affiliates, thousands of clinicians and researchers have been trained to improve the lives of veterans and benefit the lives of all Americans. In supporting the largest US integrated health care system, the VA also has numerous capabilities and resources that distinctively position it to produce scientific and clinical results specifically within the context of providing care. The VA has formed partnerships with other federal agencies, industry, and nonprofit entities. Its ability to be a nexus of health care and practice, scientific discovery, and innovative ways to integrate shared interests in these areas have led to many transformative endeavors that save lives and improve the quality of care for veterans and the public.

The COVID-19 pandemic triggered another mission: service in times of national emergency. Known as the Fourth Mission, the VA rapidly shifted to highlight how its health care and research enterprises could apply strengths in a unique, coordinated manner. While the Fourth Mission is typically considered in the context of clinical care, the VA’s movement toward greater integration facilitated the role of research as a key component in efforts under a learning health care model.2

VA Office of Research and Development

Within the VHA, the Office of Research and Development (ORD) develops research policy and oversees interdisciplinary efforts focused on generating evidence to improve veteran health.3 These activities span at least 100 of 171 VAMCs and include thousands of investigators and staff across all major health research disciplines. Many of these investigators are also clinicians who provide patient care and are experts in the prevention, diagnosis, and treatment of diseases and disorders affecting veterans.

The ORD has invested in a range of scientific, operational, regulatory, and technological assets and infrastructure as part of its enterprise. These strengths come from a nearly 100-year history originating as part of a set of hospital-based medical studies. This established the model for a culture of cooperative research within the VA and with external groups who benefit from the VA’s foundational role in multisite clinical trials.2,4,5 Today, the VA prioritizes bench-to-bedside research covering a broad spectrum of investigations, which are integrated with clinical operations and systems that deliver care.3 The VA supports an extensive range of work that covers core areas in preclinical and clinical studies to health services research, rehabilitation and implementation science, establishing expertise in genomic and data sciences, and more recent activities in artificial intelligence.

In 2017, the ORD began a focused strategy to transform into a national enterprise that capitalized on its place within the VA and its particular ability to translate and implement scientific findings into real impact for veteran health and care through 5 initiatives: (1) enhancing veteran access to high-quality clinical trials; (2) increasing the substantial real-world impact of VA Research; (3) putting VA data to work for veteran health; (4) promoting diversity, equity, and inclusion within our sphere of influence; and (5) building community through research. These activities are interrelated and, where possible, the ORD works with other VA clinical and operational offices to accomplish multiple goals and coordinate within the health care system. As such, the VA continually seeks to increase efficiencies and improve abilities that provide veterans with best-in-class health care. While still in its early stages, this strategy and its initiatives established a path for the ORD response to the pandemic.

Within 2 weeks of the World Health Organization and the US declaring a COVID-19 pandemic, the ORD began to address the developing needs and challenges of the yet unknown emerging public health threat. This included outreach to and contact from federal, academic, and industry partners. At the same time, the ORD maintained its focus and energy to support its ongoing veteran-centric research portfolio and VHA health care system needs across its broad scope of activities.

This article discusses how the pandemic accelerated the VA’s research enterprise strategy and enacted a response, highlighting the advantages and strengths of this direction. We demonstrate how this evolving strategy enabled the VA to quickly leverage partnerships during a health emergency. While the ORD and VA Research have been used interchangeably, we will attempt to distinguish between the office that serves as headquarters for the national enterprise—the ORD—and the components of that enterprise composed of scientific personnel, equipment, operational units, and partners—VA Research. Finally, we present lessons from this experience toward a broader, post–COVID-19, enterprise-wide approach that the VA has for providing evidence-based care. These experiences may enrich our understanding of postpandemic future research opportunities with the VA as a leader and partner who leverages its commitment to veterans to improve the nation’s health.

 

 

ORGANIZING THE VA COVID-19 RESEARCH RESPONSE

VA Research seeks to internally standardize and integrate collaborations with clinical and operational partners throughout the agency. When possible, it seeks to streamline partnership efforts involving external groups less familiar with how the VA operates or its policies, as well as its capabilities. This need was more obvious during the pandemic, and the ORD assembled its COVID-19 response quickly.6

figure

In early January 2020, VA offices, including the ORD, were carefully observing COVID-19. On March 4, 2020, a week before the World Health Organization declared COVID-19 a pandemic, the ORD and its National Research Advisory Council arranged a briefing from VA public health leaders to deal with reported cases of COVID-19 and VA plans. Immediately afterward, the ORD Chief Research and Development Officer gathered a team of experts in clinical research, infectious disease, and public health to strategize a broader research enterprise approach to the pandemic. This group quickly framed 3 key targets: (1) identify critical research questions to prioritize; (2) provide operational guidance to the research community; and (3) uphold VA research staff safety. This discussion led to the creation of a larger ORD COVID-19 Research Response Team that managed activities within this scope. This team included other ORD leaders and staff with operational, scientific, and regulatory expertise charged with enterprise-level planning and execution for all research activities addressing or affected by the pandemic (Figure).

Effective and timely communication was chief among key ORD responsibilities. On March 19, 2020, the Response Team informed the VA Research community about ORD plans for organizing the VA COVID-19 research response.7 It also mobilized VA research programs and investigators to support an enterprise approach that would be coordinated centrally. We achieved communication goals by developing a dedicated website, which provided a means to distribute up-to-date notices and guidance, answer frequently asked questions, and alert investigators about research opportunities. The site enabled the field to report on its efforts, which enhanced leadership and community awareness. A working group of ORD and field personnel managed communications. Given the volume of existing non–COVID-19 research, we established a research continuity of operations plan to provide guidelines for study participant and research staff safety. The ORD issued an unprecedented full-stop administrative hold on in-person research activities after the global announcement of the pandemic. This policy provided formal protections for research programs to safeguard staff and research participants and to determine appropriate alternatives to conduct research activities within necessary social distancing, safety, and other clinical care parameters. It also aligned with guidance and requirements that local VAMCs issued for their operations and care priorities.

The Response Team also established a scientific steering committee of VA infectious disease, critical care, informatics, and epidemiology experts to prioritize research questions, identify research opportunities, and evaluate proposals using a modified expeditious scientific review process. This group also minimized duplicate scientific efforts that might be expected from a large pool of investigators simultaneously pursuing similar research questions. Committee recommendations set up a portfolio that included basic science efforts in diagnostics, clinical trials, population studies, and research infrastructure.

 

 

Leveraging Existing Infrastructure

Besides quickly organizing a central touchpoint for the VA COVID-19 research response, the ORD capitalized on its extensive nationwide infrastructure. One key component was the Cooperative Studies Program (CSP); the longstanding VA clinical research enterprise that supports the planning and conduct of large multicenter clinical trials and epidemiological studies. The CSP includes experts at 5 data and statistical coordinating centers, a clinical research pharmacy coordinating center, and 4 epidemiological resource centers.8 CSP studies provide definitive evidence for clinical practice and care of veterans and the nation. CSP’s CONFIRM trial (CSP 577) is the largest VA interventional study with > 50,000 veterans.9 CONFIRM followed the Trial of Varicella Zoster Vaccine for the Prevention of Herpes Zoster and Its Complications (CSP 403), which involved > 38,000 participants to evaluate a vaccine to reduce the burden of illness-associated herpes zoster (shingles). In the study, the vaccine markedly reduced the shingles burden of illness among older adults.10 These studies highlight the CSP cohort development ability as evidenced by the Million Veteran Program.11

VA Research, particularly through the CSP, contributed to multiple federal actions for COVID-19. The CSP had already established partnerships with federal and industry groups in multisite clinical trials and observational studies. During COVID-19, the ORD established a COVID-19 clinical trial master protocol framework: the VA CoronavirUs Research & Efficacy Studies network.9 The CSP also supported studies by the Coronavirus Prevention Network, the National Institute of Allergy and Infectious Disease (NIAID), and the US Food and Drug Administration (FDA). As such, the VA could translate requirements in working with an industry sponsor on the rapid execution of studies within a federal health care system. Much of the success arose when there was either earlier engagement in planning and/or existing familiarity among parties with operational and regulatory requirements.

table 1

Before the pandemic, the ORD had also been working on various external partnerships to increase opportunities for veterans in clinical trial participation, particularly for cancer, which Caroff and colleagues discuss further.12 A newly emerging Partnered Research Program (PRP) offered a strategy for participation in the major COVID-19 vaccine efficacy clinical trials. VA Research, through PRP and CSP, rapidly engaged others and managed critical communication (Table 1). In quickly pivoting to COVID-19 clinical studies, the VA also used the Networks of Dedicated Enrollment Sites (NODES), its site-based, CSP-supported infrastructure of existing investigators and coordinators with clinical, operational, and regulatory proficiency for large trials.13,14 Together, the CSP and PRP solidified the VA’s scientific, operational, and regulatory support basis for working with industry partners and federal agencies to conduct therapeutic and vaccine trials.

Speed, Knowledge, and Safety

The scope of VA Research partnerships covers several goals but can be broadly categorized in the following ways: research aimed at evaluating the efficacy of new treatments; development of infrastructure to facilitate more rapid and innovative approaches to research; and building connections within the health care system to take an enterprise approach to research.

Activities are not limited to COVID-19. The VA partners with federal entities on research primarily through interagency agreements whose authorities are derived from the Economy Act (31 USC § 1535). For industry and nonfederal groups, the VA enters into Cooperative Research and Development Agreements that are rooted in the Federal Technology Transfer Act (15 USC § 3710). Although the VA has experience in each of these processes, COVID-19 prompted many groups, existing partners and new ones, to engage with the VA. Consequently, the ORD needed to quickly understand the complexities of how to handle such engagements on a larger scale. The VA Research enterprise strategy also focused on facilitating these processes.

As part of VA integration goals, ORD leaders engaged VA clinical leaders, especially in Public Health, Preventive Medicine, Pharmacy Benefits Management, and Pathology and Laboratory services. The ORD also worked closely with operational leaders, including those responsible for the Veterans Integrated Service Networks and VAMC chiefs of staff and network chief medical officers. The ORD’s familiarity with coordinating complex activities for research further helped to organize nonresearch responses for clinical needs and resources to support the VA COVID-19 response. The Office of the Under Secretary for Health recognized VA Research’s critical role as part of the VA health care system. In turn, it served as a major champion to drive success among the active research efforts, especially the partnered efforts, responding to COVID-19. Continuously communicating support and offering resources for the agency’s overall COVID-19 response reinforced the positive impact of VA Research that extended beyond its traditional roles. That is, the research component of VHA was highlighted as an integral part of the COVID-19 response along with its clinical operations. This integrated approach was perhaps best demonstrated in a VHA-wide push to start and conduct the national vaccine efficacy trials.

Other COVID-19 research supported by the ORD included participation in the Mayo Clinic–led convalescent plasma expanded access treatment protocol, which had emerged as a potential therapeutic option.15 The ORD provided centralized regulatory support to nearly 100 VAMCs, helping to reduce inconsistencies in protocol approval processes for what was hoped to be a promising treatment for COVID-19.16 This rapid approach to address a real-time treatment option demonstrated the VA Research capability for swift mobilization in an emergency.

The ORD also coordinated with other federal agencies. For example, it collaborated with the US Department of Defense to begin a parallel observational study on COVID-19 infections and potential severe outcomes. The study enrolled > 3000 veterans who are being followed for up to 2 years to better understand the natural history and course of COVID-19.17 Other interagency efforts focused on vaccine and therapeutic trials, including Accelerating COVID-19 Therapeutic Interventions and Vaccines (ACTIV) with the National Institutes of Health. In these activities, VA Research helped increase recruitment, particularly of a more diverse patient population, in helping to assess promising treatments.10

table 2

Motivated by its expanding portfolio of COVID-19 intervention studies, the VA also created a COVID-19 research registry for all VA investigators. This registry included almost 59,000 veterans who indicated a willingness to volunteer for clinical studies. This registry exemplified a long-standing tradition of veterans willing to serve their nation again in a time of need. Iaquinto and colleagues showcased how VHA programs (eg, Office of Healthcare Innovation and Learning) collaborated by expediting a study on 3D-printed swabs to address supply chain shortages. The study, which involved the FDA, showed that the printed swabs were as effective as commercially available ones.18 It provided evidence supporting the production and dissemination of a greater number of testing swabs to the public while also reducing the cost and time requirements (Table 2).

Altogether, these collaborative efforts advanced a transformative approach within the VA that was already happening but was accelerated by the pandemic. Such activities enabled greater understanding throughout the VA for how research is not merely complementary but an integrated part of how veterans receive health care. By giving opportunities to veterans to participate in studies, especially clinical studies, the VA created a path in which such expectations, understanding, and operations were more fluid.

 

 

Future Directions

The VA continues to work for veterans by emphasizing its strategic goals and strengths in clinical, data science, and other pioneering activities at an enterprise level to provide the highest quality evidence for care. These capabilities perpetuate a scientific and learning environment that also builds toward the future by giving junior investigators and others opportunities to work within a national health care setting. In turn, this provides a more focused perspective on endeavors that align with the VA mission through ORD-supported career development, merit review (independent investigator submissions), and CSP.19 Preclinical, health services, genomic, and implementation research were given insights into more effective operational and methodological partnerships to help inform the health care system. The pandemic also served to strengthen our ability to mobilize and prepare even faster for emergencies and other potential disease outbreaks, including newer pandemic concerns (eg, mpox, Ebola) from research and public health perspectives.

Conclusions

Throughout its 100-year history, VA Research has been a critical, enduring institution within the national medical landscape. The ability to collaborate with partners has helped us to design and create even better processes, optimize and maximize our infrastructure, and learn more about common research interests that can be even more responsive to national health care needs. As an enterprise, VA Research also aims to continually learn and expand on these valuable lessons gained from internal, interagency, and industry collaborations to effectively meet and exceed our mission to serve our veterans.

Acknowledgments

The authors acknowledge Daphne Swancutt for her contribution as copywriter for this manuscript.

The US Department of Veterans Affairs (VA) plays a substantial role in the nation’s public health through the Veterans Health Administration (VHA). Its statutory missions of teaching, clinical care, and research enable it to serve a foundational role in the US biomedical enterprise.1 Throughout its extensive network of VA medical centers (VAMCs) and partnering academic affiliates, thousands of clinicians and researchers have been trained to improve the lives of veterans and benefit the lives of all Americans. In supporting the largest US integrated health care system, the VA also has numerous capabilities and resources that distinctively position it to produce scientific and clinical results specifically within the context of providing care. The VA has formed partnerships with other federal agencies, industry, and nonprofit entities. Its ability to be a nexus of health care and practice, scientific discovery, and innovative ways to integrate shared interests in these areas have led to many transformative endeavors that save lives and improve the quality of care for veterans and the public.

The COVID-19 pandemic triggered another mission: service in times of national emergency. Known as the Fourth Mission, the VA rapidly shifted to highlight how its health care and research enterprises could apply strengths in a unique, coordinated manner. While the Fourth Mission is typically considered in the context of clinical care, the VA’s movement toward greater integration facilitated the role of research as a key component in efforts under a learning health care model.2

VA Office of Research and Development

Within the VHA, the Office of Research and Development (ORD) develops research policy and oversees interdisciplinary efforts focused on generating evidence to improve veteran health.3 These activities span at least 100 of 171 VAMCs and include thousands of investigators and staff across all major health research disciplines. Many of these investigators are also clinicians who provide patient care and are experts in the prevention, diagnosis, and treatment of diseases and disorders affecting veterans.

The ORD has invested in a range of scientific, operational, regulatory, and technological assets and infrastructure as part of its enterprise. These strengths come from a nearly 100-year history originating as part of a set of hospital-based medical studies. This established the model for a culture of cooperative research within the VA and with external groups who benefit from the VA’s foundational role in multisite clinical trials.2,4,5 Today, the VA prioritizes bench-to-bedside research covering a broad spectrum of investigations, which are integrated with clinical operations and systems that deliver care.3 The VA supports an extensive range of work that covers core areas in preclinical and clinical studies to health services research, rehabilitation and implementation science, establishing expertise in genomic and data sciences, and more recent activities in artificial intelligence.

In 2017, the ORD began a focused strategy to transform into a national enterprise that capitalized on its place within the VA and its particular ability to translate and implement scientific findings into real impact for veteran health and care through 5 initiatives: (1) enhancing veteran access to high-quality clinical trials; (2) increasing the substantial real-world impact of VA Research; (3) putting VA data to work for veteran health; (4) promoting diversity, equity, and inclusion within our sphere of influence; and (5) building community through research. These activities are interrelated and, where possible, the ORD works with other VA clinical and operational offices to accomplish multiple goals and coordinate within the health care system. As such, the VA continually seeks to increase efficiencies and improve abilities that provide veterans with best-in-class health care. While still in its early stages, this strategy and its initiatives established a path for the ORD response to the pandemic.

Within 2 weeks of the World Health Organization and the US declaring a COVID-19 pandemic, the ORD began to address the developing needs and challenges of the yet unknown emerging public health threat. This included outreach to and contact from federal, academic, and industry partners. At the same time, the ORD maintained its focus and energy to support its ongoing veteran-centric research portfolio and VHA health care system needs across its broad scope of activities.

This article discusses how the pandemic accelerated the VA’s research enterprise strategy and enacted a response, highlighting the advantages and strengths of this direction. We demonstrate how this evolving strategy enabled the VA to quickly leverage partnerships during a health emergency. While the ORD and VA Research have been used interchangeably, we will attempt to distinguish between the office that serves as headquarters for the national enterprise—the ORD—and the components of that enterprise composed of scientific personnel, equipment, operational units, and partners—VA Research. Finally, we present lessons from this experience toward a broader, post–COVID-19, enterprise-wide approach that the VA has for providing evidence-based care. These experiences may enrich our understanding of postpandemic future research opportunities with the VA as a leader and partner who leverages its commitment to veterans to improve the nation’s health.

 

 

ORGANIZING THE VA COVID-19 RESEARCH RESPONSE

VA Research seeks to internally standardize and integrate collaborations with clinical and operational partners throughout the agency. When possible, it seeks to streamline partnership efforts involving external groups less familiar with how the VA operates or its policies, as well as its capabilities. This need was more obvious during the pandemic, and the ORD assembled its COVID-19 response quickly.6

figure

In early January 2020, VA offices, including the ORD, were carefully observing COVID-19. On March 4, 2020, a week before the World Health Organization declared COVID-19 a pandemic, the ORD and its National Research Advisory Council arranged a briefing from VA public health leaders to deal with reported cases of COVID-19 and VA plans. Immediately afterward, the ORD Chief Research and Development Officer gathered a team of experts in clinical research, infectious disease, and public health to strategize a broader research enterprise approach to the pandemic. This group quickly framed 3 key targets: (1) identify critical research questions to prioritize; (2) provide operational guidance to the research community; and (3) uphold VA research staff safety. This discussion led to the creation of a larger ORD COVID-19 Research Response Team that managed activities within this scope. This team included other ORD leaders and staff with operational, scientific, and regulatory expertise charged with enterprise-level planning and execution for all research activities addressing or affected by the pandemic (Figure).

Effective and timely communication was chief among key ORD responsibilities. On March 19, 2020, the Response Team informed the VA Research community about ORD plans for organizing the VA COVID-19 research response.7 It also mobilized VA research programs and investigators to support an enterprise approach that would be coordinated centrally. We achieved communication goals by developing a dedicated website, which provided a means to distribute up-to-date notices and guidance, answer frequently asked questions, and alert investigators about research opportunities. The site enabled the field to report on its efforts, which enhanced leadership and community awareness. A working group of ORD and field personnel managed communications. Given the volume of existing non–COVID-19 research, we established a research continuity of operations plan to provide guidelines for study participant and research staff safety. The ORD issued an unprecedented full-stop administrative hold on in-person research activities after the global announcement of the pandemic. This policy provided formal protections for research programs to safeguard staff and research participants and to determine appropriate alternatives to conduct research activities within necessary social distancing, safety, and other clinical care parameters. It also aligned with guidance and requirements that local VAMCs issued for their operations and care priorities.

The Response Team also established a scientific steering committee of VA infectious disease, critical care, informatics, and epidemiology experts to prioritize research questions, identify research opportunities, and evaluate proposals using a modified expeditious scientific review process. This group also minimized duplicate scientific efforts that might be expected from a large pool of investigators simultaneously pursuing similar research questions. Committee recommendations set up a portfolio that included basic science efforts in diagnostics, clinical trials, population studies, and research infrastructure.

 

 

Leveraging Existing Infrastructure

Besides quickly organizing a central touchpoint for the VA COVID-19 research response, the ORD capitalized on its extensive nationwide infrastructure. One key component was the Cooperative Studies Program (CSP); the longstanding VA clinical research enterprise that supports the planning and conduct of large multicenter clinical trials and epidemiological studies. The CSP includes experts at 5 data and statistical coordinating centers, a clinical research pharmacy coordinating center, and 4 epidemiological resource centers.8 CSP studies provide definitive evidence for clinical practice and care of veterans and the nation. CSP’s CONFIRM trial (CSP 577) is the largest VA interventional study with > 50,000 veterans.9 CONFIRM followed the Trial of Varicella Zoster Vaccine for the Prevention of Herpes Zoster and Its Complications (CSP 403), which involved > 38,000 participants to evaluate a vaccine to reduce the burden of illness-associated herpes zoster (shingles). In the study, the vaccine markedly reduced the shingles burden of illness among older adults.10 These studies highlight the CSP cohort development ability as evidenced by the Million Veteran Program.11

VA Research, particularly through the CSP, contributed to multiple federal actions for COVID-19. The CSP had already established partnerships with federal and industry groups in multisite clinical trials and observational studies. During COVID-19, the ORD established a COVID-19 clinical trial master protocol framework: the VA CoronavirUs Research & Efficacy Studies network.9 The CSP also supported studies by the Coronavirus Prevention Network, the National Institute of Allergy and Infectious Disease (NIAID), and the US Food and Drug Administration (FDA). As such, the VA could translate requirements in working with an industry sponsor on the rapid execution of studies within a federal health care system. Much of the success arose when there was either earlier engagement in planning and/or existing familiarity among parties with operational and regulatory requirements.

table 1

Before the pandemic, the ORD had also been working on various external partnerships to increase opportunities for veterans in clinical trial participation, particularly for cancer, which Caroff and colleagues discuss further.12 A newly emerging Partnered Research Program (PRP) offered a strategy for participation in the major COVID-19 vaccine efficacy clinical trials. VA Research, through PRP and CSP, rapidly engaged others and managed critical communication (Table 1). In quickly pivoting to COVID-19 clinical studies, the VA also used the Networks of Dedicated Enrollment Sites (NODES), its site-based, CSP-supported infrastructure of existing investigators and coordinators with clinical, operational, and regulatory proficiency for large trials.13,14 Together, the CSP and PRP solidified the VA’s scientific, operational, and regulatory support basis for working with industry partners and federal agencies to conduct therapeutic and vaccine trials.

Speed, Knowledge, and Safety

The scope of VA Research partnerships covers several goals but can be broadly categorized in the following ways: research aimed at evaluating the efficacy of new treatments; development of infrastructure to facilitate more rapid and innovative approaches to research; and building connections within the health care system to take an enterprise approach to research.

Activities are not limited to COVID-19. The VA partners with federal entities on research primarily through interagency agreements whose authorities are derived from the Economy Act (31 USC § 1535). For industry and nonfederal groups, the VA enters into Cooperative Research and Development Agreements that are rooted in the Federal Technology Transfer Act (15 USC § 3710). Although the VA has experience in each of these processes, COVID-19 prompted many groups, existing partners and new ones, to engage with the VA. Consequently, the ORD needed to quickly understand the complexities of how to handle such engagements on a larger scale. The VA Research enterprise strategy also focused on facilitating these processes.

As part of VA integration goals, ORD leaders engaged VA clinical leaders, especially in Public Health, Preventive Medicine, Pharmacy Benefits Management, and Pathology and Laboratory services. The ORD also worked closely with operational leaders, including those responsible for the Veterans Integrated Service Networks and VAMC chiefs of staff and network chief medical officers. The ORD’s familiarity with coordinating complex activities for research further helped to organize nonresearch responses for clinical needs and resources to support the VA COVID-19 response. The Office of the Under Secretary for Health recognized VA Research’s critical role as part of the VA health care system. In turn, it served as a major champion to drive success among the active research efforts, especially the partnered efforts, responding to COVID-19. Continuously communicating support and offering resources for the agency’s overall COVID-19 response reinforced the positive impact of VA Research that extended beyond its traditional roles. That is, the research component of VHA was highlighted as an integral part of the COVID-19 response along with its clinical operations. This integrated approach was perhaps best demonstrated in a VHA-wide push to start and conduct the national vaccine efficacy trials.

Other COVID-19 research supported by the ORD included participation in the Mayo Clinic–led convalescent plasma expanded access treatment protocol, which had emerged as a potential therapeutic option.15 The ORD provided centralized regulatory support to nearly 100 VAMCs, helping to reduce inconsistencies in protocol approval processes for what was hoped to be a promising treatment for COVID-19.16 This rapid approach to address a real-time treatment option demonstrated the VA Research capability for swift mobilization in an emergency.

The ORD also coordinated with other federal agencies. For example, it collaborated with the US Department of Defense to begin a parallel observational study on COVID-19 infections and potential severe outcomes. The study enrolled > 3000 veterans who are being followed for up to 2 years to better understand the natural history and course of COVID-19.17 Other interagency efforts focused on vaccine and therapeutic trials, including Accelerating COVID-19 Therapeutic Interventions and Vaccines (ACTIV) with the National Institutes of Health. In these activities, VA Research helped increase recruitment, particularly of a more diverse patient population, in helping to assess promising treatments.10

table 2

Motivated by its expanding portfolio of COVID-19 intervention studies, the VA also created a COVID-19 research registry for all VA investigators. This registry included almost 59,000 veterans who indicated a willingness to volunteer for clinical studies. This registry exemplified a long-standing tradition of veterans willing to serve their nation again in a time of need. Iaquinto and colleagues showcased how VHA programs (eg, Office of Healthcare Innovation and Learning) collaborated by expediting a study on 3D-printed swabs to address supply chain shortages. The study, which involved the FDA, showed that the printed swabs were as effective as commercially available ones.18 It provided evidence supporting the production and dissemination of a greater number of testing swabs to the public while also reducing the cost and time requirements (Table 2).

Altogether, these collaborative efforts advanced a transformative approach within the VA that was already happening but was accelerated by the pandemic. Such activities enabled greater understanding throughout the VA for how research is not merely complementary but an integrated part of how veterans receive health care. By giving opportunities to veterans to participate in studies, especially clinical studies, the VA created a path in which such expectations, understanding, and operations were more fluid.

 

 

Future Directions

The VA continues to work for veterans by emphasizing its strategic goals and strengths in clinical, data science, and other pioneering activities at an enterprise level to provide the highest quality evidence for care. These capabilities perpetuate a scientific and learning environment that also builds toward the future by giving junior investigators and others opportunities to work within a national health care setting. In turn, this provides a more focused perspective on endeavors that align with the VA mission through ORD-supported career development, merit review (independent investigator submissions), and CSP.19 Preclinical, health services, genomic, and implementation research were given insights into more effective operational and methodological partnerships to help inform the health care system. The pandemic also served to strengthen our ability to mobilize and prepare even faster for emergencies and other potential disease outbreaks, including newer pandemic concerns (eg, mpox, Ebola) from research and public health perspectives.

Conclusions

Throughout its 100-year history, VA Research has been a critical, enduring institution within the national medical landscape. The ability to collaborate with partners has helped us to design and create even better processes, optimize and maximize our infrastructure, and learn more about common research interests that can be even more responsive to national health care needs. As an enterprise, VA Research also aims to continually learn and expand on these valuable lessons gained from internal, interagency, and industry collaborations to effectively meet and exceed our mission to serve our veterans.

Acknowledgments

The authors acknowledge Daphne Swancutt for her contribution as copywriter for this manuscript.

References

1. US Department of Veterans Affairs. Functional organization manual: description of organization, structure, missions, functions, tasks, and authorities. Version 6. 2020. Accessed September 11, 2023. https://www.va.gov/VA-Functional-Organization-Manual-2020-4.pdf

2. Kilbourne AM, Schmidt J, Edmunds M, Vega R, Bowersox N, Atkins D. How the VA is training the next-generation workforce for learning health systems. Learn Health Syst. 2022;6(4):e10333. Published 2022 Aug 16. doi:10.1002/lrh2.10333

3. O’Leary TJ, Dominitz JA, Chang KM. Veterans Affairs office of research and development: research programs and emerging opportunities in digestive diseases research. Gastroenterology. 2015;149(7):1652-1661. doi:10.1053/j.gastro.2015.10.021

4. Tucker WB. The evolution of the cooperative studies in the chemotherapy of tuberculosis of the Veterans Administration and armed forces of the U.S.A. An account of the evolving education of the physician in clinical pharmacology. Bibl Tuberc. 1960;15:1-68.

5. Hays MT; Veterans Health Administration. A historical look at the establishment of the Department of Veterans Affairs research & development program. https://www.research.va.gov/pubs/docs/ORD-85yrHistory.pdf

6. US Department of Veterans Affairs, Veterans Health Administration. Coronavirus Disease 2019 (COVID-19) response report – annex a. May 10, 2021. Accessed September 11, 2023. https://www.va.gov/health/docs/VHA-COVID-19-Response-2021.pdf

7. US Department of Veterans Affairs, Veterans Health Administration. ORD Research Response to COVID-19. US Department of Veterans Affairs. Updated March 24, 2020. Accessed September 11, 2023. www.research.va.gov/programs/orppe/education/webinars/orppe-031920.cfm

8. Burnaska DR, Huang GD, O’Leary TJ. Clinical trials proposed for the VA cooperative studies program: success rates and factors impacting approval. Contemp Clin Trials Commun. 2021;23:100811. Published 2021 Jul 9. doi:10.1016/j.conctc.2021.100811

9. US Department of Veterans Affairs. VA CoronavirUs Research & Efficacy Studies (VA CURES). Updated January 6, 2022. Accessed September 11, 2023. https://www.research.va.gov/services/csrd/va_cures/default.cfm

10. Oxman MN, Levin MJ, Johnson GR, et al. A vaccine to prevent herpes zoster and postherpetic neuralgia in older adults. N Engl J Med. 2005;352(22):2271-2284. doi:10.1056/NEJMoa051016

11. Whitbourne SB, Moser J, Cho K, et al. Leveraging the Million Veteran Program infrastructure and data for a rapid research response to COVID-19. Fed Pract. 2023;40(suppl 5):S23-S28. doi:10.12788/fp.0416

12. Caroff K, Davey V, Smyth M, et al. VA lessons from partnering in COVID-19 clinical trials. Fed Pract. 2023;40(suppl 5): S18-S22. doi:10.12788/fp.0415

13. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: the Department of Veterans Affairs’ network of dedicated enrollment sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

14. McClure J, Asghar A, Krajec A, et al. Clinical trial facilitators: a novel approach to support the execution of clinical research at the study site level. Contemp Clin Trials Commun. 2023;33:101106. doi:10.1016/j.conctc.2023.101106

15. Joyner M. Expanded access to convalescent plasma for the treatment of patients with COVID-19. ClinicalTrials.gov identifier: NCT04338360. April 8, 2020. Updated September 2, 2020. Accessed September 11, 2023. https://clinicaltrials.gov/ct2/show/NCT04338360

16. Joyner MJ, Wright RS, Fairweather D, et al. Early safety indicators of COVID-19 convalescent plasma in 5000 patients. J Clin Invest. 2020;130(9):4791-4797. doi:10.1172/JCI140200

17. Lee JS, Smith NL. Epidemiology, immunology and clinical characteristics of COVID-19 (EPIC3). ClinicalTrials.gov identifier: NCT05764083. March 10, 2023. Updated August 1, 2023. Accessed September 11, 2023. https://clinicaltrials.gov/ct2/show/NCT05764083

18. Iaquinto J, Ripley B, Dorn PA. How VA innovative partnerships and health care system can respond to national needs: NOSE trial example. Fed Pract. 2023;40(suppl 5):S52-S56. doi:10.12788/fp.0418

19. US Department of Veterans Affairs. Health Services Research & Development research career development program. Updated March 4, 2021. Accessed September 11, 2023. https://hsrd.research.va.gov/cdp/

References

1. US Department of Veterans Affairs. Functional organization manual: description of organization, structure, missions, functions, tasks, and authorities. Version 6. 2020. Accessed September 11, 2023. https://www.va.gov/VA-Functional-Organization-Manual-2020-4.pdf

2. Kilbourne AM, Schmidt J, Edmunds M, Vega R, Bowersox N, Atkins D. How the VA is training the next-generation workforce for learning health systems. Learn Health Syst. 2022;6(4):e10333. Published 2022 Aug 16. doi:10.1002/lrh2.10333

3. O’Leary TJ, Dominitz JA, Chang KM. Veterans Affairs office of research and development: research programs and emerging opportunities in digestive diseases research. Gastroenterology. 2015;149(7):1652-1661. doi:10.1053/j.gastro.2015.10.021

4. Tucker WB. The evolution of the cooperative studies in the chemotherapy of tuberculosis of the Veterans Administration and armed forces of the U.S.A. An account of the evolving education of the physician in clinical pharmacology. Bibl Tuberc. 1960;15:1-68.

5. Hays MT; Veterans Health Administration. A historical look at the establishment of the Department of Veterans Affairs research & development program. https://www.research.va.gov/pubs/docs/ORD-85yrHistory.pdf

6. US Department of Veterans Affairs, Veterans Health Administration. Coronavirus Disease 2019 (COVID-19) response report – annex a. May 10, 2021. Accessed September 11, 2023. https://www.va.gov/health/docs/VHA-COVID-19-Response-2021.pdf

7. US Department of Veterans Affairs, Veterans Health Administration. ORD Research Response to COVID-19. US Department of Veterans Affairs. Updated March 24, 2020. Accessed September 11, 2023. www.research.va.gov/programs/orppe/education/webinars/orppe-031920.cfm

8. Burnaska DR, Huang GD, O’Leary TJ. Clinical trials proposed for the VA cooperative studies program: success rates and factors impacting approval. Contemp Clin Trials Commun. 2021;23:100811. Published 2021 Jul 9. doi:10.1016/j.conctc.2021.100811

9. US Department of Veterans Affairs. VA CoronavirUs Research & Efficacy Studies (VA CURES). Updated January 6, 2022. Accessed September 11, 2023. https://www.research.va.gov/services/csrd/va_cures/default.cfm

10. Oxman MN, Levin MJ, Johnson GR, et al. A vaccine to prevent herpes zoster and postherpetic neuralgia in older adults. N Engl J Med. 2005;352(22):2271-2284. doi:10.1056/NEJMoa051016

11. Whitbourne SB, Moser J, Cho K, et al. Leveraging the Million Veteran Program infrastructure and data for a rapid research response to COVID-19. Fed Pract. 2023;40(suppl 5):S23-S28. doi:10.12788/fp.0416

12. Caroff K, Davey V, Smyth M, et al. VA lessons from partnering in COVID-19 clinical trials. Fed Pract. 2023;40(suppl 5): S18-S22. doi:10.12788/fp.0415

13. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: the Department of Veterans Affairs’ network of dedicated enrollment sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

14. McClure J, Asghar A, Krajec A, et al. Clinical trial facilitators: a novel approach to support the execution of clinical research at the study site level. Contemp Clin Trials Commun. 2023;33:101106. doi:10.1016/j.conctc.2023.101106

15. Joyner M. Expanded access to convalescent plasma for the treatment of patients with COVID-19. ClinicalTrials.gov identifier: NCT04338360. April 8, 2020. Updated September 2, 2020. Accessed September 11, 2023. https://clinicaltrials.gov/ct2/show/NCT04338360

16. Joyner MJ, Wright RS, Fairweather D, et al. Early safety indicators of COVID-19 convalescent plasma in 5000 patients. J Clin Invest. 2020;130(9):4791-4797. doi:10.1172/JCI140200

17. Lee JS, Smith NL. Epidemiology, immunology and clinical characteristics of COVID-19 (EPIC3). ClinicalTrials.gov identifier: NCT05764083. March 10, 2023. Updated August 1, 2023. Accessed September 11, 2023. https://clinicaltrials.gov/ct2/show/NCT05764083

18. Iaquinto J, Ripley B, Dorn PA. How VA innovative partnerships and health care system can respond to national needs: NOSE trial example. Fed Pract. 2023;40(suppl 5):S52-S56. doi:10.12788/fp.0418

19. US Department of Veterans Affairs. Health Services Research & Development research career development program. Updated March 4, 2021. Accessed September 11, 2023. https://hsrd.research.va.gov/cdp/

Issue
Federal Practitioner - 40(5)s
Issue
Federal Practitioner - 40(5)s
Page Number
S12
Page Number
S12
Publications
Publications
Topics
Article Type
Sections
Disallow All Ads
Content Gating
No Gating (article Unlocked/Free)
Alternative CME
Disqus Comments
Default
Use ProPublica
Hide sidebar & use full width
render the right sidebar.
Conference Recap Checkbox
Not Conference Recap
Clinical Edge
Display the Slideshow in this Article
Medscape Article
Display survey writer
Reuters content
Disable Inline Native ads
WebMD Article
Article PDF Media

Introduction

Article Type
Changed
Tue, 10/31/2023 - 15:57

Bad times have a scientific value. These are occasions a good learner would not miss.

Ralph Waldo Emerson

Like the flip of a light switch, the world in March 2020 went into lockdown. Suddenly the novel coronavirus disease (COVID-19) was ever-present and everywhere. At a time when very little was certain, scientific inquiry—along with its related skills and disciplines—offered a much-needed pathway for navigating the virus’s myriad unknowns.

From the pandemic’s onset, the Veterans Health Administration (VHA) of the US Department of Veterans Affairs (VA) made singular contributions to the advancement and acceleration of national and international research activity. This special issue of Federal Practitioner demonstrates how the VHA, through its Office of Research and Development (ORD), took advantage of its newly deployed enterprise strategy to meet the unprecedented demands of this public health emergency.

Launched in 2017, the ORD enterprise strategy enabled the VHA not only to capitalize on existing collaborations—both internal and external—but also move swiftly in forging new ones. Additionally, the strategy was key to leveraging unique VHA assets as the nation’s largest integrated health care system, including: (1) nationwide clinical trials infrastructure, including its longstanding Cooperative Studies Program; (2) a tightly integrated system of clinical care and research that serves as a ready platform for big data science, the world’s largest genomic database, and emergent capabilities; and (3) an established innovation ecosystem that worked with VA research to address rapidly changing circumstances.

In The VA Research Enterprise (p. S12), Garcia and colleagues demonstrate how the VHA pandemic response “arose from an enterprise strategy that was already in motion and aimed at identifying needs for supporting the clinical care mission, more rapidly leveraging resources, and coordinating research across the national VA health care system.” Thus, the VHA took a “model for a culture of cooperative research within the VA and with external groups” and translated it beyond the scope of clinical trials, which had been its foundation.

Led by Chief Research and Development Officer Rachel Ramoni, DMD, ScD, this strategy forged 121 VA medical centers conducting research into an integrated enterprise that could respond to needs for scientific evidence in a coordinated fashion, thereby translating research into practice for real impact on veterans. This approach built on relationships with not only scientific communities but also clinical and operational partners working within the VA to address the immediate pandemic-related needs.

In tandem with its physical infrastructure, the VA’s longstanding network of collaborators, physical infrastructure, and ability to develop new partnerships became drivers of success. Because of previous, ongoing, multisite clinical trials and observational studies, the VA had already partnered with numerous federal government agencies and industry groups and was able to quickly set up a VA COVID-19 clinical trial master protocol framework called the CURES (VA Coronavirus Research and Efficacy studies) network. The ORD enterprise strategy is noted by several other authors, including Caroff and colleagues, who show how the VA efforts to broaden partnerships prepandemic were critical to its participation in 7 large-scale COVID-19 therapeutic and vaccine trials (p. S18).

Similarly, in discussing the VA Million Veteran Program (MVP), Whitbourne and colleagues (p. S23) demonstrate how the VA research strategy and infrastructure were key to leveraging “unique MVP and VA electronic health record data to drive rapid scientific discovery and inform clinical operations.”

Launched in 2011, the MVP is one of the world’s largest genomic cohorts, with more than 985,000 veterans enrolled. MVP developers had the prescience to foresee how a robust genomic database could inform public health emergencies. Whitbourne and colleagues show the many ways the MVP facilitated the VHA COVID-19 response. By extending the MVP centralized recruitment and enrollment infrastructure, an ORD COVID-19 volunteer registry successfully registered 50,000 veterans interested in volunteering for clinical trials.

This tight integration between research and clinical care is one of the VHA’s greatest assets as a health care system. More than 60% of VA researchers are also clinicians who provide direct patient care. This enables VA physician-researchers to learn directly from veteran patients and quickly translate new findings into improved care. It also supported numerous capabilities that played a key role during the pandemic.

For example, in the article VA Big Data Science (p. S39), Young-Xu and colleagues note that the VA use of health care data proved medical research could be performed “quickly and judiciously.” Foundational to this research was a data sharing framework, electronic health record, and VA Corporate Data Warehouse that were accessible to all VA researchers. Researchers had access to clinical data and patient health records that allowed them to perform targeted, time-sensitive research. By building a cohort of 1,363,180 veterans who received ≥ 1 vaccine dose by March 7, 2021, VA researchers added significantly to our understanding of the real-world COVID-19 vaccine clinical performance.

In addition to leveraging existing capabilities, VHA clinicians and researchers created new ones in response. Krishnan and colleagues discuss the launch of 2 clinical and research consortiums focused on COVID-19 genomic surveillance (p. S44). SeqFORCE positioned the VHA to rapidly detect emergent variants and better inform the care of patients with COVID-19. SeqCURE focused on the broader study and trends of variants through sequencing.

The tightly integrated nature of VA care also supported the creation of a large-scale biorepository of specimens with accompanying clinical data to advance research and improve diagnostic and therapeutic research. Epstein and colleagues share the developmental history of the VA SHIELD biorepository, its structure, and its current and future contributions to research science (p. S48).

Finally, the same forward-learning culture which gave rise to the ORD enterprise strategy also resulted in an innovation ecosystem that was well established prior to March 2020. Now a firmly established portfolio within the VHA Office of Healthcare Innovation and Learning (OHIL), the VHA Innovation Ecosystem engages frontline clinicians in reimagining veteran health care. Iaquinto and colleagues discuss how the ecosystem’s preexisting partnerships were critical to addressing shortages in personal protective equipment and other vital resources (p. S52). The OHIL provided the quality system and manufacturing oversight and delivery of swabs for testing, while the ORD furnished research infrastructure and human subjects oversight. Together, these offices not only addressed the shortage by producing swabs but also validated the swabs’ safety and efficacy in the clinical setting.

The articles in this special issue chronicle how the VA quickly mobilized its considerable enterprise-wide resources—especially during the pandemic’s acute phases—to contribute to timely veteran, national, and global evidence about what interventions were effective, what factors were associated with better care and outcomes, and how to flip the switch back to a nonemergency response. As Emerson might have observed, the scientific value of these recent “bad times” did not go unnoticed by VHA learners. In addition to catalyzing opportunities that accelerated the VHA enterprise strategy, the pandemic strengthened existing partnerships, led to new ones, and yielded lessons learned. With variants of the virus continuing to circulate, the VHA continues to harness the lessons learned from the emergency response perspective of the pandemic in order to effectively meet and exceed our mission to serve veterans.

The 35 authors whose work is featured in this issue—and their 3665 colleagues across the VHA research enterprise—offer testament not only to the power of scientific inquiry but of dedication to the mission by the individuals whose lives and families were also impacted by the pandemic.

VA Research continues working to unravel the ongoing impact of COVID-19. As the nation observes an increase in cases again, the VA is ready and well positioned to help lead and address needs for this and other public health crises.

Acknowledgments

This special issue is dedicated to Mitchell (Mitch) Mirkin and his enduring legacy at VA Research, helping to make the contributions of VA Research known as broadly as possible. A superb writer and “editor’s editor,” Mitch had an outstanding ability to translate complex scientific findings into layman’s terms. From the start of the pandemic to his unexpected passing in 2022, Mitch was Acting Director of VA Research Communications. He was a key member of the VA Office of Research and Development COVID-19 research response team. His contributions included his work leading to the generation of this Issue.

Article PDF
Author and Disclosure Information

Louise Arnheim, MPAa; Grant D. Huang, MPH, PhDb; Amanda P. Garcia, MPHb; Rachel B. Ramoni, DMD, ScDb;  Carolyn M. Clancy, MDa

Correspondence:  Louise Arnheim  (louise.arnheim@va.gov)

Author affiliations

aOffice of Discovery, Education and Affiliate Networks, Department of Veterans Affairs,

bOffice of Research and Development, Department of Veterans Affairs

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the U.S. Government, or any of its agencies.

Issue
Federal Practitioner - 40(5)s
Publications
Topics
Page Number
S9
Sections
Author and Disclosure Information

Louise Arnheim, MPAa; Grant D. Huang, MPH, PhDb; Amanda P. Garcia, MPHb; Rachel B. Ramoni, DMD, ScDb;  Carolyn M. Clancy, MDa

Correspondence:  Louise Arnheim  (louise.arnheim@va.gov)

Author affiliations

aOffice of Discovery, Education and Affiliate Networks, Department of Veterans Affairs,

bOffice of Research and Development, Department of Veterans Affairs

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the U.S. Government, or any of its agencies.

Author and Disclosure Information

Louise Arnheim, MPAa; Grant D. Huang, MPH, PhDb; Amanda P. Garcia, MPHb; Rachel B. Ramoni, DMD, ScDb;  Carolyn M. Clancy, MDa

Correspondence:  Louise Arnheim  (louise.arnheim@va.gov)

Author affiliations

aOffice of Discovery, Education and Affiliate Networks, Department of Veterans Affairs,

bOffice of Research and Development, Department of Veterans Affairs

Disclaimer

The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the U.S. Government, or any of its agencies.

Article PDF
Article PDF

Bad times have a scientific value. These are occasions a good learner would not miss.

Ralph Waldo Emerson

Like the flip of a light switch, the world in March 2020 went into lockdown. Suddenly the novel coronavirus disease (COVID-19) was ever-present and everywhere. At a time when very little was certain, scientific inquiry—along with its related skills and disciplines—offered a much-needed pathway for navigating the virus’s myriad unknowns.

From the pandemic’s onset, the Veterans Health Administration (VHA) of the US Department of Veterans Affairs (VA) made singular contributions to the advancement and acceleration of national and international research activity. This special issue of Federal Practitioner demonstrates how the VHA, through its Office of Research and Development (ORD), took advantage of its newly deployed enterprise strategy to meet the unprecedented demands of this public health emergency.

Launched in 2017, the ORD enterprise strategy enabled the VHA not only to capitalize on existing collaborations—both internal and external—but also move swiftly in forging new ones. Additionally, the strategy was key to leveraging unique VHA assets as the nation’s largest integrated health care system, including: (1) nationwide clinical trials infrastructure, including its longstanding Cooperative Studies Program; (2) a tightly integrated system of clinical care and research that serves as a ready platform for big data science, the world’s largest genomic database, and emergent capabilities; and (3) an established innovation ecosystem that worked with VA research to address rapidly changing circumstances.

In The VA Research Enterprise (p. S12), Garcia and colleagues demonstrate how the VHA pandemic response “arose from an enterprise strategy that was already in motion and aimed at identifying needs for supporting the clinical care mission, more rapidly leveraging resources, and coordinating research across the national VA health care system.” Thus, the VHA took a “model for a culture of cooperative research within the VA and with external groups” and translated it beyond the scope of clinical trials, which had been its foundation.

Led by Chief Research and Development Officer Rachel Ramoni, DMD, ScD, this strategy forged 121 VA medical centers conducting research into an integrated enterprise that could respond to needs for scientific evidence in a coordinated fashion, thereby translating research into practice for real impact on veterans. This approach built on relationships with not only scientific communities but also clinical and operational partners working within the VA to address the immediate pandemic-related needs.

In tandem with its physical infrastructure, the VA’s longstanding network of collaborators, physical infrastructure, and ability to develop new partnerships became drivers of success. Because of previous, ongoing, multisite clinical trials and observational studies, the VA had already partnered with numerous federal government agencies and industry groups and was able to quickly set up a VA COVID-19 clinical trial master protocol framework called the CURES (VA Coronavirus Research and Efficacy studies) network. The ORD enterprise strategy is noted by several other authors, including Caroff and colleagues, who show how the VA efforts to broaden partnerships prepandemic were critical to its participation in 7 large-scale COVID-19 therapeutic and vaccine trials (p. S18).

Similarly, in discussing the VA Million Veteran Program (MVP), Whitbourne and colleagues (p. S23) demonstrate how the VA research strategy and infrastructure were key to leveraging “unique MVP and VA electronic health record data to drive rapid scientific discovery and inform clinical operations.”

Launched in 2011, the MVP is one of the world’s largest genomic cohorts, with more than 985,000 veterans enrolled. MVP developers had the prescience to foresee how a robust genomic database could inform public health emergencies. Whitbourne and colleagues show the many ways the MVP facilitated the VHA COVID-19 response. By extending the MVP centralized recruitment and enrollment infrastructure, an ORD COVID-19 volunteer registry successfully registered 50,000 veterans interested in volunteering for clinical trials.

This tight integration between research and clinical care is one of the VHA’s greatest assets as a health care system. More than 60% of VA researchers are also clinicians who provide direct patient care. This enables VA physician-researchers to learn directly from veteran patients and quickly translate new findings into improved care. It also supported numerous capabilities that played a key role during the pandemic.

For example, in the article VA Big Data Science (p. S39), Young-Xu and colleagues note that the VA use of health care data proved medical research could be performed “quickly and judiciously.” Foundational to this research was a data sharing framework, electronic health record, and VA Corporate Data Warehouse that were accessible to all VA researchers. Researchers had access to clinical data and patient health records that allowed them to perform targeted, time-sensitive research. By building a cohort of 1,363,180 veterans who received ≥ 1 vaccine dose by March 7, 2021, VA researchers added significantly to our understanding of the real-world COVID-19 vaccine clinical performance.

In addition to leveraging existing capabilities, VHA clinicians and researchers created new ones in response. Krishnan and colleagues discuss the launch of 2 clinical and research consortiums focused on COVID-19 genomic surveillance (p. S44). SeqFORCE positioned the VHA to rapidly detect emergent variants and better inform the care of patients with COVID-19. SeqCURE focused on the broader study and trends of variants through sequencing.

The tightly integrated nature of VA care also supported the creation of a large-scale biorepository of specimens with accompanying clinical data to advance research and improve diagnostic and therapeutic research. Epstein and colleagues share the developmental history of the VA SHIELD biorepository, its structure, and its current and future contributions to research science (p. S48).

Finally, the same forward-learning culture which gave rise to the ORD enterprise strategy also resulted in an innovation ecosystem that was well established prior to March 2020. Now a firmly established portfolio within the VHA Office of Healthcare Innovation and Learning (OHIL), the VHA Innovation Ecosystem engages frontline clinicians in reimagining veteran health care. Iaquinto and colleagues discuss how the ecosystem’s preexisting partnerships were critical to addressing shortages in personal protective equipment and other vital resources (p. S52). The OHIL provided the quality system and manufacturing oversight and delivery of swabs for testing, while the ORD furnished research infrastructure and human subjects oversight. Together, these offices not only addressed the shortage by producing swabs but also validated the swabs’ safety and efficacy in the clinical setting.

The articles in this special issue chronicle how the VA quickly mobilized its considerable enterprise-wide resources—especially during the pandemic’s acute phases—to contribute to timely veteran, national, and global evidence about what interventions were effective, what factors were associated with better care and outcomes, and how to flip the switch back to a nonemergency response. As Emerson might have observed, the scientific value of these recent “bad times” did not go unnoticed by VHA learners. In addition to catalyzing opportunities that accelerated the VHA enterprise strategy, the pandemic strengthened existing partnerships, led to new ones, and yielded lessons learned. With variants of the virus continuing to circulate, the VHA continues to harness the lessons learned from the emergency response perspective of the pandemic in order to effectively meet and exceed our mission to serve veterans.

The 35 authors whose work is featured in this issue—and their 3665 colleagues across the VHA research enterprise—offer testament not only to the power of scientific inquiry but of dedication to the mission by the individuals whose lives and families were also impacted by the pandemic.

VA Research continues working to unravel the ongoing impact of COVID-19. As the nation observes an increase in cases again, the VA is ready and well positioned to help lead and address needs for this and other public health crises.

Acknowledgments

This special issue is dedicated to Mitchell (Mitch) Mirkin and his enduring legacy at VA Research, helping to make the contributions of VA Research known as broadly as possible. A superb writer and “editor’s editor,” Mitch had an outstanding ability to translate complex scientific findings into layman’s terms. From the start of the pandemic to his unexpected passing in 2022, Mitch was Acting Director of VA Research Communications. He was a key member of the VA Office of Research and Development COVID-19 research response team. His contributions included his work leading to the generation of this Issue.

Bad times have a scientific value. These are occasions a good learner would not miss.

Ralph Waldo Emerson

Like the flip of a light switch, the world in March 2020 went into lockdown. Suddenly the novel coronavirus disease (COVID-19) was ever-present and everywhere. At a time when very little was certain, scientific inquiry—along with its related skills and disciplines—offered a much-needed pathway for navigating the virus’s myriad unknowns.

From the pandemic’s onset, the Veterans Health Administration (VHA) of the US Department of Veterans Affairs (VA) made singular contributions to the advancement and acceleration of national and international research activity. This special issue of Federal Practitioner demonstrates how the VHA, through its Office of Research and Development (ORD), took advantage of its newly deployed enterprise strategy to meet the unprecedented demands of this public health emergency.

Launched in 2017, the ORD enterprise strategy enabled the VHA not only to capitalize on existing collaborations—both internal and external—but also move swiftly in forging new ones. Additionally, the strategy was key to leveraging unique VHA assets as the nation’s largest integrated health care system, including: (1) nationwide clinical trials infrastructure, including its longstanding Cooperative Studies Program; (2) a tightly integrated system of clinical care and research that serves as a ready platform for big data science, the world’s largest genomic database, and emergent capabilities; and (3) an established innovation ecosystem that worked with VA research to address rapidly changing circumstances.

In The VA Research Enterprise (p. S12), Garcia and colleagues demonstrate how the VHA pandemic response “arose from an enterprise strategy that was already in motion and aimed at identifying needs for supporting the clinical care mission, more rapidly leveraging resources, and coordinating research across the national VA health care system.” Thus, the VHA took a “model for a culture of cooperative research within the VA and with external groups” and translated it beyond the scope of clinical trials, which had been its foundation.

Led by Chief Research and Development Officer Rachel Ramoni, DMD, ScD, this strategy forged 121 VA medical centers conducting research into an integrated enterprise that could respond to needs for scientific evidence in a coordinated fashion, thereby translating research into practice for real impact on veterans. This approach built on relationships with not only scientific communities but also clinical and operational partners working within the VA to address the immediate pandemic-related needs.

In tandem with its physical infrastructure, the VA’s longstanding network of collaborators, physical infrastructure, and ability to develop new partnerships became drivers of success. Because of previous, ongoing, multisite clinical trials and observational studies, the VA had already partnered with numerous federal government agencies and industry groups and was able to quickly set up a VA COVID-19 clinical trial master protocol framework called the CURES (VA Coronavirus Research and Efficacy studies) network. The ORD enterprise strategy is noted by several other authors, including Caroff and colleagues, who show how the VA efforts to broaden partnerships prepandemic were critical to its participation in 7 large-scale COVID-19 therapeutic and vaccine trials (p. S18).

Similarly, in discussing the VA Million Veteran Program (MVP), Whitbourne and colleagues (p. S23) demonstrate how the VA research strategy and infrastructure were key to leveraging “unique MVP and VA electronic health record data to drive rapid scientific discovery and inform clinical operations.”

Launched in 2011, the MVP is one of the world’s largest genomic cohorts, with more than 985,000 veterans enrolled. MVP developers had the prescience to foresee how a robust genomic database could inform public health emergencies. Whitbourne and colleagues show the many ways the MVP facilitated the VHA COVID-19 response. By extending the MVP centralized recruitment and enrollment infrastructure, an ORD COVID-19 volunteer registry successfully registered 50,000 veterans interested in volunteering for clinical trials.

This tight integration between research and clinical care is one of the VHA’s greatest assets as a health care system. More than 60% of VA researchers are also clinicians who provide direct patient care. This enables VA physician-researchers to learn directly from veteran patients and quickly translate new findings into improved care. It also supported numerous capabilities that played a key role during the pandemic.

For example, in the article VA Big Data Science (p. S39), Young-Xu and colleagues note that the VA use of health care data proved medical research could be performed “quickly and judiciously.” Foundational to this research was a data sharing framework, electronic health record, and VA Corporate Data Warehouse that were accessible to all VA researchers. Researchers had access to clinical data and patient health records that allowed them to perform targeted, time-sensitive research. By building a cohort of 1,363,180 veterans who received ≥ 1 vaccine dose by March 7, 2021, VA researchers added significantly to our understanding of the real-world COVID-19 vaccine clinical performance.

In addition to leveraging existing capabilities, VHA clinicians and researchers created new ones in response. Krishnan and colleagues discuss the launch of 2 clinical and research consortiums focused on COVID-19 genomic surveillance (p. S44). SeqFORCE positioned the VHA to rapidly detect emergent variants and better inform the care of patients with COVID-19. SeqCURE focused on the broader study and trends of variants through sequencing.

The tightly integrated nature of VA care also supported the creation of a large-scale biorepository of specimens with accompanying clinical data to advance research and improve diagnostic and therapeutic research. Epstein and colleagues share the developmental history of the VA SHIELD biorepository, its structure, and its current and future contributions to research science (p. S48).

Finally, the same forward-learning culture which gave rise to the ORD enterprise strategy also resulted in an innovation ecosystem that was well established prior to March 2020. Now a firmly established portfolio within the VHA Office of Healthcare Innovation and Learning (OHIL), the VHA Innovation Ecosystem engages frontline clinicians in reimagining veteran health care. Iaquinto and colleagues discuss how the ecosystem’s preexisting partnerships were critical to addressing shortages in personal protective equipment and other vital resources (p. S52). The OHIL provided the quality system and manufacturing oversight and delivery of swabs for testing, while the ORD furnished research infrastructure and human subjects oversight. Together, these offices not only addressed the shortage by producing swabs but also validated the swabs’ safety and efficacy in the clinical setting.

The articles in this special issue chronicle how the VA quickly mobilized its considerable enterprise-wide resources—especially during the pandemic’s acute phases—to contribute to timely veteran, national, and global evidence about what interventions were effective, what factors were associated with better care and outcomes, and how to flip the switch back to a nonemergency response. As Emerson might have observed, the scientific value of these recent “bad times” did not go unnoticed by VHA learners. In addition to catalyzing opportunities that accelerated the VHA enterprise strategy, the pandemic strengthened existing partnerships, led to new ones, and yielded lessons learned. With variants of the virus continuing to circulate, the VHA continues to harness the lessons learned from the emergency response perspective of the pandemic in order to effectively meet and exceed our mission to serve veterans.

The 35 authors whose work is featured in this issue—and their 3665 colleagues across the VHA research enterprise—offer testament not only to the power of scientific inquiry but of dedication to the mission by the individuals whose lives and families were also impacted by the pandemic.

VA Research continues working to unravel the ongoing impact of COVID-19. As the nation observes an increase in cases again, the VA is ready and well positioned to help lead and address needs for this and other public health crises.

Acknowledgments

This special issue is dedicated to Mitchell (Mitch) Mirkin and his enduring legacy at VA Research, helping to make the contributions of VA Research known as broadly as possible. A superb writer and “editor’s editor,” Mitch had an outstanding ability to translate complex scientific findings into layman’s terms. From the start of the pandemic to his unexpected passing in 2022, Mitch was Acting Director of VA Research Communications. He was a key member of the VA Office of Research and Development COVID-19 research response team. His contributions included his work leading to the generation of this Issue.

Issue
Federal Practitioner - 40(5)s
Issue
Federal Practitioner - 40(5)s
Page Number
S9
Page Number
S9
Publications
Publications
Topics
Article Type
Sections
Disallow All Ads
Content Gating
No Gating (article Unlocked/Free)
Alternative CME
Disqus Comments
Default
Use ProPublica
Hide sidebar & use full width
render the right sidebar.
Conference Recap Checkbox
Not Conference Recap
Clinical Edge
Display the Slideshow in this Article
Medscape Article
Display survey writer
Reuters content
Disable Inline Native ads
WebMD Article
Article PDF Media

Leveraging Veterans Health Administration Clinical and Research Resources to Accelerate Discovery and Testing in Precision Oncology(FULL)

Article Type
Changed
Mon, 08/02/2021 - 02:45
Display Headline
Leveraging Veterans Health Administration Clinical and Research Resources to Accelerate Discovery and Testing in Precision Oncology

In May 2020, the US Food and Drug Administration (FDA) approved the first 2 targeted treatments for prostate cancer, specifically, the poly-(adenosine diphosphate-ribose) polymerase (PARP) inhibitors rucaparib and olaparib.1,2 For these medications to work, the tumor must have a homologous recombination deficiency (HRD), which is a form of DNA repair deficiency. The PARP pathway is important for DNA repair, and PARP inhibition leads to “synthetic lethality” in cancer cells that already are deficient in DNA repair mechanisms.3 Now, there is evidence that patients with prostate cancer who have HRD tumors and receive PARP inhibitors live longer when compared with those who receive standard of care options.4 These findings offer hope for patients with prostate cancer. They also demonstrate the process and potential benefits of precision oncology efforts; namely, targeted treatments for specific tumor types in cancer patients.

This article discusses the challenges and opportunities of precision oncology for US Department of Veterans Affairs (VA) Veterans Health Administration (VHA). First, the article will discuss working with relatively rare mutations. Second, the article will examine how the trials of olaparib and rucaparib illuminate the VHA contribution to research on new therapies for patients with cancer. Finally, the article will explore the ways in which VHA is becoming a major national contributor in drug discovery and approval of precision medications.

Precision Oncology

Despite advances in screening and treatment, an estimated 600,000 people in the US will die of cancer in 2020.5 Meaningful advances in cancer care depend on both laboratory and clinical research. This combination, known as translational research, takes discoveries in the laboratory and applies them to patients and vice versa. Successful translational research requires many components. These include talented scientists to form hypotheses and perform the work; money for supplies and equipment; platforms for timely dissemination of knowledge; well-trained clinicians to treat patients and lead research teams; and patients to participate in clinical trials. In precision oncology, the ability to find patients for the trials can be daunting, particularly in cases where the frequency of the mutation of interest is low.

 

 

During the 20th century, with few exceptions, physicians caring for patients with cancer had blunt instruments at their disposal. Surgery and radiation could lead to survival if the cancer was caught early enough. Systemic therapies, such as chemotherapy, rarely cured but could prolong life in some patients. However, chemotherapy is imprecise and targets any cell growing rapidly, including blood, hair, and gastrointestinal tract cells, which often leads to adverse effects. Sometimes complications from chemotherapy may shorten a person’s life, and certainly the quality of life during and after these treatments could be diminished. The improvements in cancer care occurred more rapidly once scientists had the tools to learn about individual tumors.

In the summer of 2000, researchers announced that the human genome had been sequenced.6 The genome (ie, DNA) consists of introns and exons that form a map for human development. Exons can be converted to proteins that carry out specific actions, such as helping in cell growth, cell death, or DNA repair. Solving the human genome itself did not lead directly to cures, but it did represent a huge advance in medical research. As time passed, sequencing genomes became more affordable, and sequencing just the exome alone was even cheaper.7 Treatments for cancer began to expand with the help of these tools, but questions as to the true benefit of targeted therapy also grew.8

Physicians and scientists have amassed more information about cancer cells and have applied this knowledge to active drug development. In 2001, the FDA approved the first targeted therapy, imatinib, for the treatment of chronic myelogenous leukemia (CML). This rapidly improved patient survival through targeting the mutated protein that leads to CML, rather than just aiming for rapidly dividing cells.9 Those mutations for which there is a drug to target, such as the BCR-ABL translocation in CML, are called actionable mutations.

 

Precision Oncology Program for Prostate Cancer

In 2016, the VA and the Prostate Cancer Foundation (PCF) established the Precision Oncology Program for Prostate Cancer (POPCaP) Centers of Excellence (COE). This partnership was formed to accelerate treatment and cure for veterans with prostate cancer. The VA Greater Los Angeles Healthcare System in California and VA Puget Sound Health Care System in Washington led this effort, and their principal investigators continue to co-lead POPCaP. Since its inception, 9 additional funded POPCaP COEs have joined, each with a mandate to sequence the tumors of men with metastatic prostate cancer.

The more that is learned about a tumor, the more likely it is that researchers can find mutations that are that tumor’s Achilles heel and defeat it. In fact, many drugs that can target mutations are already available. For example, BRCA2 is an actionable mutation that can be exploited by knocking out another key DNA repair mechanism in the cell, PARP. Today, the effort of sequencing has led to a rich database of mutations present in men with metastatic prostate cancer.

Although there are many targeted therapies, most have not been studied formally in prostate cancer. Occasionally, clinicians treating patients will use these drugs in an unapproved way, hoping that there will be anticancer activity. It is difficult to estimate the likelihood of success with a drug in this situation, and the safety profile may not be well described in that setting. Treatment decisions for incurable cancers must be made knowing the risks and benefits. This helps in shared decision making between the clinician and patient and informs choices concerning which laboratory tests to order and how often to see the patient. However, treatment decisions are sometimes made with the hope of activity when a cancer is known to be incurable. Very little data, which are critical to determine whether this helps or hurts patients, support this approach.

Some data suggest that sequencing and giving a drug for an actionable mutation may lead to better outcomes for patients. Sequencing of pancreatic tumors by Pishvaian and colleagues revealed that 282 of 1,082 (26%) samples harbored actionable mutations.10 Those patients who received a drug that targeted their actionable mutation (n = 46; 24%) lived longer when compared with those who had an actionable mutation but did not receive a drug that targeted it (hazard ratio [HR] 0.42 [95% CI, 0.26-0.68; P = .0004]). Additionally, those who received therapy for an actionable mutation lived longer when compared with those who did not have an actionable mutation (HR 0.34 [95% CI, 0.22-0.53; P < .001]). While this finding is intriguing, it does not mean that treating actionable mutations outside of a clinical trial should be done. To this end, VA established Prostate cancer Analysis for Therapy CHoice (PATCH) as a clinical trials network within POPCaP.

 

 

Prostate Cancer Analysis

The overall PATCH vision is designed for clinical care and research work to together toward improved care for those with prostate cancer (Figure 1). The resources necessary for successful translational research are substantial, and PATCH aims to streamline those resources. PATCH will support innovative, precision-based clinical research at the POPCaP COEs through its 5 arms.

Arm 1. Dedicated personnel ensure veteran access to trials in PATCH by giving patients and providers accurate information about available trial options; aiding veterans in traveling from home VA to a POPCaP COE for participation on a study; and maintaining the Committee for Veteran Participation in PATCH, where veterans will be represented and asked to provide input into the PATCH process.

Arm 2. Coordinators at the coordinating COE in Portland, Orgeon, train investigators and study staff at the local POPCaP COEs to ensure research can be performed in a safe and responsible way.

Arm 3. Personnel experienced in conducting clinical trials liaise with investigators at VA Central Institutional Review Board, monitor trials, build databases for appropriate and efficient data collection, and manage high-risk studies conducted under an Investigational New Drug application. This group works closely with biostatisticians to choose appropriate trial designs, estimate numbers of patients needed, and interpret data once they are collected.

Arm 4. Protocol development and data dissemination is coordinated by a group to assist investigators in drafting protocols and reviewing abstracts and manuscripts.

Arm 5. A core group manages contracts and budgets, as well as relationships between VA and industry, where funding and drugs may be obtained.



Perhaps most importantly, PATCH leverages the genetic data collected by POPCaP COEs to find patients for clinical trials. For example, the trials that examined olaparib and rucaparib assumed that the prevalence of HRD was about 25% in men with advanced prostate cancer.11 As these trials began enrollment, however, researchers discovered that the prevalence was < 20%. In fact, the study of olaparib screened 4,425 patients at 206 sites in 20 countries to identify 778 (18% of screened) patients with HRD.4 With widespread sequencing within VA, it could be possible to identify a substantial number of patients who are already known to have the mutation of interest (Figure 2).

Clinical Trials

There are currently 2 clinical trials in PATCH; 4 additional trials await funding decisions, and more trials are in the concept stage. BRACeD (NCT04038502) is a phase 2 trial examining platinum and taxane chemotherapy in tumors with HRD (specifically, BRCA1, BRCA2, and PALB2). About 15% to 20% of men with advanced prostate cancer will have a DNA repair defect in the tumor that could make them eligible for this study. The primary endpoint is progression-free survival.

A second study, CHOMP (NCT04104893), is a phase 2 trial examining the efficacy of immunotherapy (PD-1 inhibition) in tumors having mismatch repair deficiency or CDK12-/-. Each of those is found in about 7% of men with metastatic prostate cancer, and full accrual of a trial with rare mutations could take 5 to 10 years without a systematic approach of sequencing and identifying potential participants. The primary endpoint is a composite of radiographic response by iRECIST (immune response evaluation criteria in solid tumors), progression-free survival at 6 months and prostate specific antigen reduction by ≥ 50% in ≤ 12 weeks. With 11 POPCaP COEs sequencing the tumors of every man with metastatic prostate cancer, identifying men with the appropriate mutation is possible. PATCH will aid the sites in recruitment through outreach and coordination of travel.

 

 

Industry Partnerships

PATCH depends upon pharmaceutical industry partners, as clinical trials of even 40 patients can require significant funding and trial resources to operate. Furthermore, many drugs of interest are not available outside of a clinical trial, and partnerships enable VA researchers to access these medications. PATCH also benefits greatly from foundation partners, such as the PCF, which has made POPCaP possible and will continue to connect talented researchers with VA resources. Finally, access to other publicly available research funds, such as those from VA Office of Research and Development, National Institutes of Health, and US Department of Defense (DoD) Congressionally Directed Research Program are needed for trials.

Funding for these trials remains limited despite public health and broader interests in addressing important questions. Accelerated accrual through PATCH may be an attractive partnership opportunity for companies, foundations and government funding agencies to support the PATCH efforts.

Both POPCaP and PATCH highlight the potential promise of precision oncology within the nation’s largest integrated health care system. The VHA patient population enables prostate cancer researchers to serve an important early target. It also provides a foundational platform for a broader set of activities. These include a tailored approach to identifying tumor profiles and other patient characteristics that may help to elevate standard of care for other common cancers including ones affecting the lungs and/or head and neck.

To this end, VA has been working with the National Cancer Institute (NCI) and DoD to establish a national infrastructure for precision oncology across multiple cancer types.12 In addition to clinical capabilities and the ability to run clinical trials that can accrue sufficient patients to answer key questions, we have developed capabilities for data collection and sharing, and analytical tools to support a learning health care system approach as a core element to precision oncology.

Besides having a research-specific context, such informatics and information technology systems enable clinicians to obtain and apply decision-making data rapidly for a specific patient and cancer type. These systems take particular advantage of the extensive electronic health record that underlies the VHA system, integrating real-world evidence into rigorous trials for precision oncology and other diseases. This is important for facilitating prerequisite activities for quality assessments for incorporation into databases (with appropriate permissions) to enhance treatment options. These activities are a key focus of the APOLLO initiative.13 While a more in-depth discussion of the importance of informatics is beyond the scope of this article, the field represents an important investment that is needed to achieve the goals of precision oncology.

In addition to informatics and data handling capabilities, VA has a longstanding tradition of designing and coordinating multisite clinical trials. This dates to the time of World War II when returning veterans had a high prevalence of tuberculosis. Since then, VA has contributed extensively to landmark findings in cardiovascular disease and surgery, mental health, infectious disease, and cancer. It was a VA study that helped establish colonoscopy as a standard for colorectal cancer screening by detecting colonic neoplasms in asymptomatic patients.14

From such investigations, the VA Cooperative Studies Program (CSP) has developed many strategies to conduct multisite clinical trials. But, CSP also has organized its sites methodically for operational efficiency and the ability to maintain institutional knowledge that crosses different types of studies and diseases. Using its Network of Dedicated Enrollment Sites (NODES) model, VA partnered with NCI to more effectively address administrative and regulatory requirements for initiating trials and recruiting veterans into cancer clinical trials.15 This partnership—the NCI And VA Interagency Group to Accelerate Trials Enrollment (NAVIGATE)—supports 12 sites with a central CSP Coordinating Center (CSPCC).

CSPCC provides support, shares best practices and provides organizational commitment at the senior levels of both agencies to overcome potential barriers. The goals and strategies are described by Schiller and colleagues.16 While still in its early stage as a cancer research network, NAVIGATE may be integrated with POPCaP and other parts of VA clinical research enterprise. This would allow us to specialize in advancing oncology care and to leverage capabilities more specifically to precision oncology. With an emphasis on recruitment, NAVIGATE has established capabilities with VA Informatics and Computing Infrastructure to quickly identify patients who may be eligible for particular clinical trials. We envision further refining these capabilities for precision oncology trials that incorporate genetic and other information for individual patients. VA also hopes to inform trial sponsors about design considerations. This is important since networked investigators will have direct insights into patient-level factors, which may help with more effectively identifying and enrolling them into trials for their particular cancers.

 

 

Conclusions

VA may have an opportunity to reach out to veterans who may not have immediate access to facilities running clinical trials. As it develops capabilities to bring the trial to the veteran, VA could have more virtual and/or centralized recruitment strategies. This would broaden opportunities for considering novel approaches that may not rely on a more traditional facility-based recruitment approach.

Ultimately, VA can be a critical part of a national effort to fight and, perhaps even, defeat cancers. With its extensive resources and capabilities, VA has the ability to advance a precision oncology agenda that provides veterans with the highest standard of care. It has built upon many key elements in clinical, technological and scientific fields of study that would challenge most health care systems given the extensive costs involved. In addition, creating strong partnerships with organizations such as PCF, NCI, and DoD that are complementary in resources and expertise will help VA to build a national network for cancer care. Putting this all together will support and facilitate a vision for more precise care for any veteran with cancer by more rapidly enabling the testing and approval of medications developed for this purpose.

Acknowledgments

The authors would like to thank Daphne Swancutt for comments and edits on drafts of this article.

References

1. Lynparza (Olaparib) [package insert]. Wilmington, DE: AstraZeneca Pharmaceuticals LP Inc, 2019.

2. Rubraca (rucaparib) [package insert]: Clovis Oncology, Inc., Boulder, CO: 2018.

3. McLornan DP, List A, Mufti GJ. Applying synthetic lethality for the selective targeting of cancer. N Engl J Med. 2014;371(18):1725-1735. doi:10.1056/NEJMra1407390

4. de Bono J, Mateo J, Fizazi K, et al. Olaparib for metastatic castration-resistant prostate cancer. N Engl J Med. 2020;382(22):2091-2102. doi:10.1056/NEJMoa1911440

5. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2020. CA Cancer J Clin. 2020;70(1):7-30. doi:10.3322/caac.21590

6. Bentley DR. Decoding the human genome sequence. Hum Mol Genet. 2000;9(16):2353-2358. doi:10.1093/hmg/9.16.2353

7. National Human Genome Research institute. The cost of sequencing a human genome. https://www.genome.gov/about-genomics/fact-sheets/Sequencing-Human-Genome-cost. Updated October 30, 2019. Accessed July 31, 2020. 8. Paggio JCD, Sullivan R, Booth CM. Targeting the value of targeted therapy. Oncotarget. 2017;8(53):90612-90613. Published 2017 Oct 7. doi:10.18632/oncotarget.21596

9. Druker BJ, Guilhot F, O’Brien SG, et al; IRIS Investigators. Five-year follow-up of patients receiving imatinib for chronic myeloid leukemia. N Engl J Med. 2006;355(23):2408-2417. doi:10.1056/NEJMoa062867

10. Pishvaian MJ, Blais EM, Brody JR, et al. Overall survival in patients with pancreatic cancer receiving matched therapies following molecular profiling: a retrospective analysis of the Know Your Tumor registry trial [published correction appears in Lancet Oncol. 2020 Apr;21(4):e182]. Lancet Oncol. 2020;21(4):508-518. doi:10.1016/S1470-2045(20)30074-7

11. Robinson D, Van Allen EM, Wu YM, et al. Integrative clinical genomics of advanced prostate cancer [published correction appears in Cell. 2015 Jul 16;162(2):454]. Cell. 2015;161(5):1215-1228. doi:10.1016/j.cell.2015.05.001

12. Fiore LD, Brophy MT, Ferguson RE, et al. Data sharing, clinical trials, and biomarkers in precision oncology: challenges, opportunities, and programs at the Department of Veterans Affairs. Clin Pharmacol Ther. 2017;101(5):586-589. doi:10.1002/cpt.660

13. Lee JSH, Darcy KM, Hu H, et al. From discovery to practice and survivorship: building a national real-world data learning healthcare framework for military and veteran cancer patients. Clin Pharmacol Ther. 2019;106(1):52-57. doi:10.1002/cpt.1425

14. Lieberman DA, Weiss DG, Bond JH, Ahnen DJ, Garewal H, Chejfec G. Use of colonoscopy to screen asymptomatic adults for colorectal cancer. Veterans Affairs Cooperative Study Group 380 [published correction appears in N Engl J Med 2000 Oct 19;343(16):1204]. N Engl J Med. 2000;343(3):162-168. doi:10.1056/NEJM200007203430301

15. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: The Department of Veterans Affairs’ Network of Dedicated Enrollment Sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

16. Schiller SJ, Shannon C, Brophy MT, et al. The National Cancer Institute and Department of Veterans Affairs Interagency Group to Accelerate Trials Enrollment (NAVIGATE): A federal collaboration to improve cancer care. Semin Oncol. 2019;46(4-5):308-313. doi:10.1053/j.seminoncol.2019.09.005

Article PDF
Author and Disclosure Information

Julie Graff is Section Chief of Hematology/Oncology at VA Portland Health Care System in Oregon. Grant Huang is Acting Deputy Chief Research and Development – Enterprise Optimization and Director, Cooperative Studies Program in the Office of Research and Development, Veterans Health Administration, U.S. Department of Veterans Affairs, Washington, DC. Julie Graff is also an Associate Professor of Medicine at Knight Cancer Institute, Oregon Health Sciences University in Portland.
Correspondence: Julie Graff (graffj@ohsu.edu)

Author disclosures
The authors report no actual or potential conflicts of interest with regard to this article.

Disclaimer
The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the US Government, or any of its agencies.

Issue
Federal Practitioner - 37(4)s
Publications
Topics
Page Number
S62-S67
Sections
Author and Disclosure Information

Julie Graff is Section Chief of Hematology/Oncology at VA Portland Health Care System in Oregon. Grant Huang is Acting Deputy Chief Research and Development – Enterprise Optimization and Director, Cooperative Studies Program in the Office of Research and Development, Veterans Health Administration, U.S. Department of Veterans Affairs, Washington, DC. Julie Graff is also an Associate Professor of Medicine at Knight Cancer Institute, Oregon Health Sciences University in Portland.
Correspondence: Julie Graff (graffj@ohsu.edu)

Author disclosures
The authors report no actual or potential conflicts of interest with regard to this article.

Disclaimer
The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the US Government, or any of its agencies.

Author and Disclosure Information

Julie Graff is Section Chief of Hematology/Oncology at VA Portland Health Care System in Oregon. Grant Huang is Acting Deputy Chief Research and Development – Enterprise Optimization and Director, Cooperative Studies Program in the Office of Research and Development, Veterans Health Administration, U.S. Department of Veterans Affairs, Washington, DC. Julie Graff is also an Associate Professor of Medicine at Knight Cancer Institute, Oregon Health Sciences University in Portland.
Correspondence: Julie Graff (graffj@ohsu.edu)

Author disclosures
The authors report no actual or potential conflicts of interest with regard to this article.

Disclaimer
The opinions expressed herein are those of the authors and do not necessarily reflect those of Federal Practitioner, Frontline Medical Communications Inc., the US Government, or any of its agencies.

Article PDF
Article PDF
Related Articles

In May 2020, the US Food and Drug Administration (FDA) approved the first 2 targeted treatments for prostate cancer, specifically, the poly-(adenosine diphosphate-ribose) polymerase (PARP) inhibitors rucaparib and olaparib.1,2 For these medications to work, the tumor must have a homologous recombination deficiency (HRD), which is a form of DNA repair deficiency. The PARP pathway is important for DNA repair, and PARP inhibition leads to “synthetic lethality” in cancer cells that already are deficient in DNA repair mechanisms.3 Now, there is evidence that patients with prostate cancer who have HRD tumors and receive PARP inhibitors live longer when compared with those who receive standard of care options.4 These findings offer hope for patients with prostate cancer. They also demonstrate the process and potential benefits of precision oncology efforts; namely, targeted treatments for specific tumor types in cancer patients.

This article discusses the challenges and opportunities of precision oncology for US Department of Veterans Affairs (VA) Veterans Health Administration (VHA). First, the article will discuss working with relatively rare mutations. Second, the article will examine how the trials of olaparib and rucaparib illuminate the VHA contribution to research on new therapies for patients with cancer. Finally, the article will explore the ways in which VHA is becoming a major national contributor in drug discovery and approval of precision medications.

Precision Oncology

Despite advances in screening and treatment, an estimated 600,000 people in the US will die of cancer in 2020.5 Meaningful advances in cancer care depend on both laboratory and clinical research. This combination, known as translational research, takes discoveries in the laboratory and applies them to patients and vice versa. Successful translational research requires many components. These include talented scientists to form hypotheses and perform the work; money for supplies and equipment; platforms for timely dissemination of knowledge; well-trained clinicians to treat patients and lead research teams; and patients to participate in clinical trials. In precision oncology, the ability to find patients for the trials can be daunting, particularly in cases where the frequency of the mutation of interest is low.

 

 

During the 20th century, with few exceptions, physicians caring for patients with cancer had blunt instruments at their disposal. Surgery and radiation could lead to survival if the cancer was caught early enough. Systemic therapies, such as chemotherapy, rarely cured but could prolong life in some patients. However, chemotherapy is imprecise and targets any cell growing rapidly, including blood, hair, and gastrointestinal tract cells, which often leads to adverse effects. Sometimes complications from chemotherapy may shorten a person’s life, and certainly the quality of life during and after these treatments could be diminished. The improvements in cancer care occurred more rapidly once scientists had the tools to learn about individual tumors.

In the summer of 2000, researchers announced that the human genome had been sequenced.6 The genome (ie, DNA) consists of introns and exons that form a map for human development. Exons can be converted to proteins that carry out specific actions, such as helping in cell growth, cell death, or DNA repair. Solving the human genome itself did not lead directly to cures, but it did represent a huge advance in medical research. As time passed, sequencing genomes became more affordable, and sequencing just the exome alone was even cheaper.7 Treatments for cancer began to expand with the help of these tools, but questions as to the true benefit of targeted therapy also grew.8

Physicians and scientists have amassed more information about cancer cells and have applied this knowledge to active drug development. In 2001, the FDA approved the first targeted therapy, imatinib, for the treatment of chronic myelogenous leukemia (CML). This rapidly improved patient survival through targeting the mutated protein that leads to CML, rather than just aiming for rapidly dividing cells.9 Those mutations for which there is a drug to target, such as the BCR-ABL translocation in CML, are called actionable mutations.

 

Precision Oncology Program for Prostate Cancer

In 2016, the VA and the Prostate Cancer Foundation (PCF) established the Precision Oncology Program for Prostate Cancer (POPCaP) Centers of Excellence (COE). This partnership was formed to accelerate treatment and cure for veterans with prostate cancer. The VA Greater Los Angeles Healthcare System in California and VA Puget Sound Health Care System in Washington led this effort, and their principal investigators continue to co-lead POPCaP. Since its inception, 9 additional funded POPCaP COEs have joined, each with a mandate to sequence the tumors of men with metastatic prostate cancer.

The more that is learned about a tumor, the more likely it is that researchers can find mutations that are that tumor’s Achilles heel and defeat it. In fact, many drugs that can target mutations are already available. For example, BRCA2 is an actionable mutation that can be exploited by knocking out another key DNA repair mechanism in the cell, PARP. Today, the effort of sequencing has led to a rich database of mutations present in men with metastatic prostate cancer.

Although there are many targeted therapies, most have not been studied formally in prostate cancer. Occasionally, clinicians treating patients will use these drugs in an unapproved way, hoping that there will be anticancer activity. It is difficult to estimate the likelihood of success with a drug in this situation, and the safety profile may not be well described in that setting. Treatment decisions for incurable cancers must be made knowing the risks and benefits. This helps in shared decision making between the clinician and patient and informs choices concerning which laboratory tests to order and how often to see the patient. However, treatment decisions are sometimes made with the hope of activity when a cancer is known to be incurable. Very little data, which are critical to determine whether this helps or hurts patients, support this approach.

Some data suggest that sequencing and giving a drug for an actionable mutation may lead to better outcomes for patients. Sequencing of pancreatic tumors by Pishvaian and colleagues revealed that 282 of 1,082 (26%) samples harbored actionable mutations.10 Those patients who received a drug that targeted their actionable mutation (n = 46; 24%) lived longer when compared with those who had an actionable mutation but did not receive a drug that targeted it (hazard ratio [HR] 0.42 [95% CI, 0.26-0.68; P = .0004]). Additionally, those who received therapy for an actionable mutation lived longer when compared with those who did not have an actionable mutation (HR 0.34 [95% CI, 0.22-0.53; P < .001]). While this finding is intriguing, it does not mean that treating actionable mutations outside of a clinical trial should be done. To this end, VA established Prostate cancer Analysis for Therapy CHoice (PATCH) as a clinical trials network within POPCaP.

 

 

Prostate Cancer Analysis

The overall PATCH vision is designed for clinical care and research work to together toward improved care for those with prostate cancer (Figure 1). The resources necessary for successful translational research are substantial, and PATCH aims to streamline those resources. PATCH will support innovative, precision-based clinical research at the POPCaP COEs through its 5 arms.

Arm 1. Dedicated personnel ensure veteran access to trials in PATCH by giving patients and providers accurate information about available trial options; aiding veterans in traveling from home VA to a POPCaP COE for participation on a study; and maintaining the Committee for Veteran Participation in PATCH, where veterans will be represented and asked to provide input into the PATCH process.

Arm 2. Coordinators at the coordinating COE in Portland, Orgeon, train investigators and study staff at the local POPCaP COEs to ensure research can be performed in a safe and responsible way.

Arm 3. Personnel experienced in conducting clinical trials liaise with investigators at VA Central Institutional Review Board, monitor trials, build databases for appropriate and efficient data collection, and manage high-risk studies conducted under an Investigational New Drug application. This group works closely with biostatisticians to choose appropriate trial designs, estimate numbers of patients needed, and interpret data once they are collected.

Arm 4. Protocol development and data dissemination is coordinated by a group to assist investigators in drafting protocols and reviewing abstracts and manuscripts.

Arm 5. A core group manages contracts and budgets, as well as relationships between VA and industry, where funding and drugs may be obtained.



Perhaps most importantly, PATCH leverages the genetic data collected by POPCaP COEs to find patients for clinical trials. For example, the trials that examined olaparib and rucaparib assumed that the prevalence of HRD was about 25% in men with advanced prostate cancer.11 As these trials began enrollment, however, researchers discovered that the prevalence was < 20%. In fact, the study of olaparib screened 4,425 patients at 206 sites in 20 countries to identify 778 (18% of screened) patients with HRD.4 With widespread sequencing within VA, it could be possible to identify a substantial number of patients who are already known to have the mutation of interest (Figure 2).

Clinical Trials

There are currently 2 clinical trials in PATCH; 4 additional trials await funding decisions, and more trials are in the concept stage. BRACeD (NCT04038502) is a phase 2 trial examining platinum and taxane chemotherapy in tumors with HRD (specifically, BRCA1, BRCA2, and PALB2). About 15% to 20% of men with advanced prostate cancer will have a DNA repair defect in the tumor that could make them eligible for this study. The primary endpoint is progression-free survival.

A second study, CHOMP (NCT04104893), is a phase 2 trial examining the efficacy of immunotherapy (PD-1 inhibition) in tumors having mismatch repair deficiency or CDK12-/-. Each of those is found in about 7% of men with metastatic prostate cancer, and full accrual of a trial with rare mutations could take 5 to 10 years without a systematic approach of sequencing and identifying potential participants. The primary endpoint is a composite of radiographic response by iRECIST (immune response evaluation criteria in solid tumors), progression-free survival at 6 months and prostate specific antigen reduction by ≥ 50% in ≤ 12 weeks. With 11 POPCaP COEs sequencing the tumors of every man with metastatic prostate cancer, identifying men with the appropriate mutation is possible. PATCH will aid the sites in recruitment through outreach and coordination of travel.

 

 

Industry Partnerships

PATCH depends upon pharmaceutical industry partners, as clinical trials of even 40 patients can require significant funding and trial resources to operate. Furthermore, many drugs of interest are not available outside of a clinical trial, and partnerships enable VA researchers to access these medications. PATCH also benefits greatly from foundation partners, such as the PCF, which has made POPCaP possible and will continue to connect talented researchers with VA resources. Finally, access to other publicly available research funds, such as those from VA Office of Research and Development, National Institutes of Health, and US Department of Defense (DoD) Congressionally Directed Research Program are needed for trials.

Funding for these trials remains limited despite public health and broader interests in addressing important questions. Accelerated accrual through PATCH may be an attractive partnership opportunity for companies, foundations and government funding agencies to support the PATCH efforts.

Both POPCaP and PATCH highlight the potential promise of precision oncology within the nation’s largest integrated health care system. The VHA patient population enables prostate cancer researchers to serve an important early target. It also provides a foundational platform for a broader set of activities. These include a tailored approach to identifying tumor profiles and other patient characteristics that may help to elevate standard of care for other common cancers including ones affecting the lungs and/or head and neck.

To this end, VA has been working with the National Cancer Institute (NCI) and DoD to establish a national infrastructure for precision oncology across multiple cancer types.12 In addition to clinical capabilities and the ability to run clinical trials that can accrue sufficient patients to answer key questions, we have developed capabilities for data collection and sharing, and analytical tools to support a learning health care system approach as a core element to precision oncology.

Besides having a research-specific context, such informatics and information technology systems enable clinicians to obtain and apply decision-making data rapidly for a specific patient and cancer type. These systems take particular advantage of the extensive electronic health record that underlies the VHA system, integrating real-world evidence into rigorous trials for precision oncology and other diseases. This is important for facilitating prerequisite activities for quality assessments for incorporation into databases (with appropriate permissions) to enhance treatment options. These activities are a key focus of the APOLLO initiative.13 While a more in-depth discussion of the importance of informatics is beyond the scope of this article, the field represents an important investment that is needed to achieve the goals of precision oncology.

In addition to informatics and data handling capabilities, VA has a longstanding tradition of designing and coordinating multisite clinical trials. This dates to the time of World War II when returning veterans had a high prevalence of tuberculosis. Since then, VA has contributed extensively to landmark findings in cardiovascular disease and surgery, mental health, infectious disease, and cancer. It was a VA study that helped establish colonoscopy as a standard for colorectal cancer screening by detecting colonic neoplasms in asymptomatic patients.14

From such investigations, the VA Cooperative Studies Program (CSP) has developed many strategies to conduct multisite clinical trials. But, CSP also has organized its sites methodically for operational efficiency and the ability to maintain institutional knowledge that crosses different types of studies and diseases. Using its Network of Dedicated Enrollment Sites (NODES) model, VA partnered with NCI to more effectively address administrative and regulatory requirements for initiating trials and recruiting veterans into cancer clinical trials.15 This partnership—the NCI And VA Interagency Group to Accelerate Trials Enrollment (NAVIGATE)—supports 12 sites with a central CSP Coordinating Center (CSPCC).

CSPCC provides support, shares best practices and provides organizational commitment at the senior levels of both agencies to overcome potential barriers. The goals and strategies are described by Schiller and colleagues.16 While still in its early stage as a cancer research network, NAVIGATE may be integrated with POPCaP and other parts of VA clinical research enterprise. This would allow us to specialize in advancing oncology care and to leverage capabilities more specifically to precision oncology. With an emphasis on recruitment, NAVIGATE has established capabilities with VA Informatics and Computing Infrastructure to quickly identify patients who may be eligible for particular clinical trials. We envision further refining these capabilities for precision oncology trials that incorporate genetic and other information for individual patients. VA also hopes to inform trial sponsors about design considerations. This is important since networked investigators will have direct insights into patient-level factors, which may help with more effectively identifying and enrolling them into trials for their particular cancers.

 

 

Conclusions

VA may have an opportunity to reach out to veterans who may not have immediate access to facilities running clinical trials. As it develops capabilities to bring the trial to the veteran, VA could have more virtual and/or centralized recruitment strategies. This would broaden opportunities for considering novel approaches that may not rely on a more traditional facility-based recruitment approach.

Ultimately, VA can be a critical part of a national effort to fight and, perhaps even, defeat cancers. With its extensive resources and capabilities, VA has the ability to advance a precision oncology agenda that provides veterans with the highest standard of care. It has built upon many key elements in clinical, technological and scientific fields of study that would challenge most health care systems given the extensive costs involved. In addition, creating strong partnerships with organizations such as PCF, NCI, and DoD that are complementary in resources and expertise will help VA to build a national network for cancer care. Putting this all together will support and facilitate a vision for more precise care for any veteran with cancer by more rapidly enabling the testing and approval of medications developed for this purpose.

Acknowledgments

The authors would like to thank Daphne Swancutt for comments and edits on drafts of this article.

In May 2020, the US Food and Drug Administration (FDA) approved the first 2 targeted treatments for prostate cancer, specifically, the poly-(adenosine diphosphate-ribose) polymerase (PARP) inhibitors rucaparib and olaparib.1,2 For these medications to work, the tumor must have a homologous recombination deficiency (HRD), which is a form of DNA repair deficiency. The PARP pathway is important for DNA repair, and PARP inhibition leads to “synthetic lethality” in cancer cells that already are deficient in DNA repair mechanisms.3 Now, there is evidence that patients with prostate cancer who have HRD tumors and receive PARP inhibitors live longer when compared with those who receive standard of care options.4 These findings offer hope for patients with prostate cancer. They also demonstrate the process and potential benefits of precision oncology efforts; namely, targeted treatments for specific tumor types in cancer patients.

This article discusses the challenges and opportunities of precision oncology for US Department of Veterans Affairs (VA) Veterans Health Administration (VHA). First, the article will discuss working with relatively rare mutations. Second, the article will examine how the trials of olaparib and rucaparib illuminate the VHA contribution to research on new therapies for patients with cancer. Finally, the article will explore the ways in which VHA is becoming a major national contributor in drug discovery and approval of precision medications.

Precision Oncology

Despite advances in screening and treatment, an estimated 600,000 people in the US will die of cancer in 2020.5 Meaningful advances in cancer care depend on both laboratory and clinical research. This combination, known as translational research, takes discoveries in the laboratory and applies them to patients and vice versa. Successful translational research requires many components. These include talented scientists to form hypotheses and perform the work; money for supplies and equipment; platforms for timely dissemination of knowledge; well-trained clinicians to treat patients and lead research teams; and patients to participate in clinical trials. In precision oncology, the ability to find patients for the trials can be daunting, particularly in cases where the frequency of the mutation of interest is low.

 

 

During the 20th century, with few exceptions, physicians caring for patients with cancer had blunt instruments at their disposal. Surgery and radiation could lead to survival if the cancer was caught early enough. Systemic therapies, such as chemotherapy, rarely cured but could prolong life in some patients. However, chemotherapy is imprecise and targets any cell growing rapidly, including blood, hair, and gastrointestinal tract cells, which often leads to adverse effects. Sometimes complications from chemotherapy may shorten a person’s life, and certainly the quality of life during and after these treatments could be diminished. The improvements in cancer care occurred more rapidly once scientists had the tools to learn about individual tumors.

In the summer of 2000, researchers announced that the human genome had been sequenced.6 The genome (ie, DNA) consists of introns and exons that form a map for human development. Exons can be converted to proteins that carry out specific actions, such as helping in cell growth, cell death, or DNA repair. Solving the human genome itself did not lead directly to cures, but it did represent a huge advance in medical research. As time passed, sequencing genomes became more affordable, and sequencing just the exome alone was even cheaper.7 Treatments for cancer began to expand with the help of these tools, but questions as to the true benefit of targeted therapy also grew.8

Physicians and scientists have amassed more information about cancer cells and have applied this knowledge to active drug development. In 2001, the FDA approved the first targeted therapy, imatinib, for the treatment of chronic myelogenous leukemia (CML). This rapidly improved patient survival through targeting the mutated protein that leads to CML, rather than just aiming for rapidly dividing cells.9 Those mutations for which there is a drug to target, such as the BCR-ABL translocation in CML, are called actionable mutations.

 

Precision Oncology Program for Prostate Cancer

In 2016, the VA and the Prostate Cancer Foundation (PCF) established the Precision Oncology Program for Prostate Cancer (POPCaP) Centers of Excellence (COE). This partnership was formed to accelerate treatment and cure for veterans with prostate cancer. The VA Greater Los Angeles Healthcare System in California and VA Puget Sound Health Care System in Washington led this effort, and their principal investigators continue to co-lead POPCaP. Since its inception, 9 additional funded POPCaP COEs have joined, each with a mandate to sequence the tumors of men with metastatic prostate cancer.

The more that is learned about a tumor, the more likely it is that researchers can find mutations that are that tumor’s Achilles heel and defeat it. In fact, many drugs that can target mutations are already available. For example, BRCA2 is an actionable mutation that can be exploited by knocking out another key DNA repair mechanism in the cell, PARP. Today, the effort of sequencing has led to a rich database of mutations present in men with metastatic prostate cancer.

Although there are many targeted therapies, most have not been studied formally in prostate cancer. Occasionally, clinicians treating patients will use these drugs in an unapproved way, hoping that there will be anticancer activity. It is difficult to estimate the likelihood of success with a drug in this situation, and the safety profile may not be well described in that setting. Treatment decisions for incurable cancers must be made knowing the risks and benefits. This helps in shared decision making between the clinician and patient and informs choices concerning which laboratory tests to order and how often to see the patient. However, treatment decisions are sometimes made with the hope of activity when a cancer is known to be incurable. Very little data, which are critical to determine whether this helps or hurts patients, support this approach.

Some data suggest that sequencing and giving a drug for an actionable mutation may lead to better outcomes for patients. Sequencing of pancreatic tumors by Pishvaian and colleagues revealed that 282 of 1,082 (26%) samples harbored actionable mutations.10 Those patients who received a drug that targeted their actionable mutation (n = 46; 24%) lived longer when compared with those who had an actionable mutation but did not receive a drug that targeted it (hazard ratio [HR] 0.42 [95% CI, 0.26-0.68; P = .0004]). Additionally, those who received therapy for an actionable mutation lived longer when compared with those who did not have an actionable mutation (HR 0.34 [95% CI, 0.22-0.53; P < .001]). While this finding is intriguing, it does not mean that treating actionable mutations outside of a clinical trial should be done. To this end, VA established Prostate cancer Analysis for Therapy CHoice (PATCH) as a clinical trials network within POPCaP.

 

 

Prostate Cancer Analysis

The overall PATCH vision is designed for clinical care and research work to together toward improved care for those with prostate cancer (Figure 1). The resources necessary for successful translational research are substantial, and PATCH aims to streamline those resources. PATCH will support innovative, precision-based clinical research at the POPCaP COEs through its 5 arms.

Arm 1. Dedicated personnel ensure veteran access to trials in PATCH by giving patients and providers accurate information about available trial options; aiding veterans in traveling from home VA to a POPCaP COE for participation on a study; and maintaining the Committee for Veteran Participation in PATCH, where veterans will be represented and asked to provide input into the PATCH process.

Arm 2. Coordinators at the coordinating COE in Portland, Orgeon, train investigators and study staff at the local POPCaP COEs to ensure research can be performed in a safe and responsible way.

Arm 3. Personnel experienced in conducting clinical trials liaise with investigators at VA Central Institutional Review Board, monitor trials, build databases for appropriate and efficient data collection, and manage high-risk studies conducted under an Investigational New Drug application. This group works closely with biostatisticians to choose appropriate trial designs, estimate numbers of patients needed, and interpret data once they are collected.

Arm 4. Protocol development and data dissemination is coordinated by a group to assist investigators in drafting protocols and reviewing abstracts and manuscripts.

Arm 5. A core group manages contracts and budgets, as well as relationships between VA and industry, where funding and drugs may be obtained.



Perhaps most importantly, PATCH leverages the genetic data collected by POPCaP COEs to find patients for clinical trials. For example, the trials that examined olaparib and rucaparib assumed that the prevalence of HRD was about 25% in men with advanced prostate cancer.11 As these trials began enrollment, however, researchers discovered that the prevalence was < 20%. In fact, the study of olaparib screened 4,425 patients at 206 sites in 20 countries to identify 778 (18% of screened) patients with HRD.4 With widespread sequencing within VA, it could be possible to identify a substantial number of patients who are already known to have the mutation of interest (Figure 2).

Clinical Trials

There are currently 2 clinical trials in PATCH; 4 additional trials await funding decisions, and more trials are in the concept stage. BRACeD (NCT04038502) is a phase 2 trial examining platinum and taxane chemotherapy in tumors with HRD (specifically, BRCA1, BRCA2, and PALB2). About 15% to 20% of men with advanced prostate cancer will have a DNA repair defect in the tumor that could make them eligible for this study. The primary endpoint is progression-free survival.

A second study, CHOMP (NCT04104893), is a phase 2 trial examining the efficacy of immunotherapy (PD-1 inhibition) in tumors having mismatch repair deficiency or CDK12-/-. Each of those is found in about 7% of men with metastatic prostate cancer, and full accrual of a trial with rare mutations could take 5 to 10 years without a systematic approach of sequencing and identifying potential participants. The primary endpoint is a composite of radiographic response by iRECIST (immune response evaluation criteria in solid tumors), progression-free survival at 6 months and prostate specific antigen reduction by ≥ 50% in ≤ 12 weeks. With 11 POPCaP COEs sequencing the tumors of every man with metastatic prostate cancer, identifying men with the appropriate mutation is possible. PATCH will aid the sites in recruitment through outreach and coordination of travel.

 

 

Industry Partnerships

PATCH depends upon pharmaceutical industry partners, as clinical trials of even 40 patients can require significant funding and trial resources to operate. Furthermore, many drugs of interest are not available outside of a clinical trial, and partnerships enable VA researchers to access these medications. PATCH also benefits greatly from foundation partners, such as the PCF, which has made POPCaP possible and will continue to connect talented researchers with VA resources. Finally, access to other publicly available research funds, such as those from VA Office of Research and Development, National Institutes of Health, and US Department of Defense (DoD) Congressionally Directed Research Program are needed for trials.

Funding for these trials remains limited despite public health and broader interests in addressing important questions. Accelerated accrual through PATCH may be an attractive partnership opportunity for companies, foundations and government funding agencies to support the PATCH efforts.

Both POPCaP and PATCH highlight the potential promise of precision oncology within the nation’s largest integrated health care system. The VHA patient population enables prostate cancer researchers to serve an important early target. It also provides a foundational platform for a broader set of activities. These include a tailored approach to identifying tumor profiles and other patient characteristics that may help to elevate standard of care for other common cancers including ones affecting the lungs and/or head and neck.

To this end, VA has been working with the National Cancer Institute (NCI) and DoD to establish a national infrastructure for precision oncology across multiple cancer types.12 In addition to clinical capabilities and the ability to run clinical trials that can accrue sufficient patients to answer key questions, we have developed capabilities for data collection and sharing, and analytical tools to support a learning health care system approach as a core element to precision oncology.

Besides having a research-specific context, such informatics and information technology systems enable clinicians to obtain and apply decision-making data rapidly for a specific patient and cancer type. These systems take particular advantage of the extensive electronic health record that underlies the VHA system, integrating real-world evidence into rigorous trials for precision oncology and other diseases. This is important for facilitating prerequisite activities for quality assessments for incorporation into databases (with appropriate permissions) to enhance treatment options. These activities are a key focus of the APOLLO initiative.13 While a more in-depth discussion of the importance of informatics is beyond the scope of this article, the field represents an important investment that is needed to achieve the goals of precision oncology.

In addition to informatics and data handling capabilities, VA has a longstanding tradition of designing and coordinating multisite clinical trials. This dates to the time of World War II when returning veterans had a high prevalence of tuberculosis. Since then, VA has contributed extensively to landmark findings in cardiovascular disease and surgery, mental health, infectious disease, and cancer. It was a VA study that helped establish colonoscopy as a standard for colorectal cancer screening by detecting colonic neoplasms in asymptomatic patients.14

From such investigations, the VA Cooperative Studies Program (CSP) has developed many strategies to conduct multisite clinical trials. But, CSP also has organized its sites methodically for operational efficiency and the ability to maintain institutional knowledge that crosses different types of studies and diseases. Using its Network of Dedicated Enrollment Sites (NODES) model, VA partnered with NCI to more effectively address administrative and regulatory requirements for initiating trials and recruiting veterans into cancer clinical trials.15 This partnership—the NCI And VA Interagency Group to Accelerate Trials Enrollment (NAVIGATE)—supports 12 sites with a central CSP Coordinating Center (CSPCC).

CSPCC provides support, shares best practices and provides organizational commitment at the senior levels of both agencies to overcome potential barriers. The goals and strategies are described by Schiller and colleagues.16 While still in its early stage as a cancer research network, NAVIGATE may be integrated with POPCaP and other parts of VA clinical research enterprise. This would allow us to specialize in advancing oncology care and to leverage capabilities more specifically to precision oncology. With an emphasis on recruitment, NAVIGATE has established capabilities with VA Informatics and Computing Infrastructure to quickly identify patients who may be eligible for particular clinical trials. We envision further refining these capabilities for precision oncology trials that incorporate genetic and other information for individual patients. VA also hopes to inform trial sponsors about design considerations. This is important since networked investigators will have direct insights into patient-level factors, which may help with more effectively identifying and enrolling them into trials for their particular cancers.

 

 

Conclusions

VA may have an opportunity to reach out to veterans who may not have immediate access to facilities running clinical trials. As it develops capabilities to bring the trial to the veteran, VA could have more virtual and/or centralized recruitment strategies. This would broaden opportunities for considering novel approaches that may not rely on a more traditional facility-based recruitment approach.

Ultimately, VA can be a critical part of a national effort to fight and, perhaps even, defeat cancers. With its extensive resources and capabilities, VA has the ability to advance a precision oncology agenda that provides veterans with the highest standard of care. It has built upon many key elements in clinical, technological and scientific fields of study that would challenge most health care systems given the extensive costs involved. In addition, creating strong partnerships with organizations such as PCF, NCI, and DoD that are complementary in resources and expertise will help VA to build a national network for cancer care. Putting this all together will support and facilitate a vision for more precise care for any veteran with cancer by more rapidly enabling the testing and approval of medications developed for this purpose.

Acknowledgments

The authors would like to thank Daphne Swancutt for comments and edits on drafts of this article.

References

1. Lynparza (Olaparib) [package insert]. Wilmington, DE: AstraZeneca Pharmaceuticals LP Inc, 2019.

2. Rubraca (rucaparib) [package insert]: Clovis Oncology, Inc., Boulder, CO: 2018.

3. McLornan DP, List A, Mufti GJ. Applying synthetic lethality for the selective targeting of cancer. N Engl J Med. 2014;371(18):1725-1735. doi:10.1056/NEJMra1407390

4. de Bono J, Mateo J, Fizazi K, et al. Olaparib for metastatic castration-resistant prostate cancer. N Engl J Med. 2020;382(22):2091-2102. doi:10.1056/NEJMoa1911440

5. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2020. CA Cancer J Clin. 2020;70(1):7-30. doi:10.3322/caac.21590

6. Bentley DR. Decoding the human genome sequence. Hum Mol Genet. 2000;9(16):2353-2358. doi:10.1093/hmg/9.16.2353

7. National Human Genome Research institute. The cost of sequencing a human genome. https://www.genome.gov/about-genomics/fact-sheets/Sequencing-Human-Genome-cost. Updated October 30, 2019. Accessed July 31, 2020. 8. Paggio JCD, Sullivan R, Booth CM. Targeting the value of targeted therapy. Oncotarget. 2017;8(53):90612-90613. Published 2017 Oct 7. doi:10.18632/oncotarget.21596

9. Druker BJ, Guilhot F, O’Brien SG, et al; IRIS Investigators. Five-year follow-up of patients receiving imatinib for chronic myeloid leukemia. N Engl J Med. 2006;355(23):2408-2417. doi:10.1056/NEJMoa062867

10. Pishvaian MJ, Blais EM, Brody JR, et al. Overall survival in patients with pancreatic cancer receiving matched therapies following molecular profiling: a retrospective analysis of the Know Your Tumor registry trial [published correction appears in Lancet Oncol. 2020 Apr;21(4):e182]. Lancet Oncol. 2020;21(4):508-518. doi:10.1016/S1470-2045(20)30074-7

11. Robinson D, Van Allen EM, Wu YM, et al. Integrative clinical genomics of advanced prostate cancer [published correction appears in Cell. 2015 Jul 16;162(2):454]. Cell. 2015;161(5):1215-1228. doi:10.1016/j.cell.2015.05.001

12. Fiore LD, Brophy MT, Ferguson RE, et al. Data sharing, clinical trials, and biomarkers in precision oncology: challenges, opportunities, and programs at the Department of Veterans Affairs. Clin Pharmacol Ther. 2017;101(5):586-589. doi:10.1002/cpt.660

13. Lee JSH, Darcy KM, Hu H, et al. From discovery to practice and survivorship: building a national real-world data learning healthcare framework for military and veteran cancer patients. Clin Pharmacol Ther. 2019;106(1):52-57. doi:10.1002/cpt.1425

14. Lieberman DA, Weiss DG, Bond JH, Ahnen DJ, Garewal H, Chejfec G. Use of colonoscopy to screen asymptomatic adults for colorectal cancer. Veterans Affairs Cooperative Study Group 380 [published correction appears in N Engl J Med 2000 Oct 19;343(16):1204]. N Engl J Med. 2000;343(3):162-168. doi:10.1056/NEJM200007203430301

15. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: The Department of Veterans Affairs’ Network of Dedicated Enrollment Sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

16. Schiller SJ, Shannon C, Brophy MT, et al. The National Cancer Institute and Department of Veterans Affairs Interagency Group to Accelerate Trials Enrollment (NAVIGATE): A federal collaboration to improve cancer care. Semin Oncol. 2019;46(4-5):308-313. doi:10.1053/j.seminoncol.2019.09.005

References

1. Lynparza (Olaparib) [package insert]. Wilmington, DE: AstraZeneca Pharmaceuticals LP Inc, 2019.

2. Rubraca (rucaparib) [package insert]: Clovis Oncology, Inc., Boulder, CO: 2018.

3. McLornan DP, List A, Mufti GJ. Applying synthetic lethality for the selective targeting of cancer. N Engl J Med. 2014;371(18):1725-1735. doi:10.1056/NEJMra1407390

4. de Bono J, Mateo J, Fizazi K, et al. Olaparib for metastatic castration-resistant prostate cancer. N Engl J Med. 2020;382(22):2091-2102. doi:10.1056/NEJMoa1911440

5. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2020. CA Cancer J Clin. 2020;70(1):7-30. doi:10.3322/caac.21590

6. Bentley DR. Decoding the human genome sequence. Hum Mol Genet. 2000;9(16):2353-2358. doi:10.1093/hmg/9.16.2353

7. National Human Genome Research institute. The cost of sequencing a human genome. https://www.genome.gov/about-genomics/fact-sheets/Sequencing-Human-Genome-cost. Updated October 30, 2019. Accessed July 31, 2020. 8. Paggio JCD, Sullivan R, Booth CM. Targeting the value of targeted therapy. Oncotarget. 2017;8(53):90612-90613. Published 2017 Oct 7. doi:10.18632/oncotarget.21596

9. Druker BJ, Guilhot F, O’Brien SG, et al; IRIS Investigators. Five-year follow-up of patients receiving imatinib for chronic myeloid leukemia. N Engl J Med. 2006;355(23):2408-2417. doi:10.1056/NEJMoa062867

10. Pishvaian MJ, Blais EM, Brody JR, et al. Overall survival in patients with pancreatic cancer receiving matched therapies following molecular profiling: a retrospective analysis of the Know Your Tumor registry trial [published correction appears in Lancet Oncol. 2020 Apr;21(4):e182]. Lancet Oncol. 2020;21(4):508-518. doi:10.1016/S1470-2045(20)30074-7

11. Robinson D, Van Allen EM, Wu YM, et al. Integrative clinical genomics of advanced prostate cancer [published correction appears in Cell. 2015 Jul 16;162(2):454]. Cell. 2015;161(5):1215-1228. doi:10.1016/j.cell.2015.05.001

12. Fiore LD, Brophy MT, Ferguson RE, et al. Data sharing, clinical trials, and biomarkers in precision oncology: challenges, opportunities, and programs at the Department of Veterans Affairs. Clin Pharmacol Ther. 2017;101(5):586-589. doi:10.1002/cpt.660

13. Lee JSH, Darcy KM, Hu H, et al. From discovery to practice and survivorship: building a national real-world data learning healthcare framework for military and veteran cancer patients. Clin Pharmacol Ther. 2019;106(1):52-57. doi:10.1002/cpt.1425

14. Lieberman DA, Weiss DG, Bond JH, Ahnen DJ, Garewal H, Chejfec G. Use of colonoscopy to screen asymptomatic adults for colorectal cancer. Veterans Affairs Cooperative Study Group 380 [published correction appears in N Engl J Med 2000 Oct 19;343(16):1204]. N Engl J Med. 2000;343(3):162-168. doi:10.1056/NEJM200007203430301

15. Condon DL, Beck D, Kenworthy-Heinige T, et al. A cross-cutting approach to enhancing clinical trial site success: The Department of Veterans Affairs’ Network of Dedicated Enrollment Sites (NODES) model. Contemp Clin Trials Commun. 2017;6:78-84. Published 2017 Mar 29. doi:10.1016/j.conctc.2017.03.006

16. Schiller SJ, Shannon C, Brophy MT, et al. The National Cancer Institute and Department of Veterans Affairs Interagency Group to Accelerate Trials Enrollment (NAVIGATE): A federal collaboration to improve cancer care. Semin Oncol. 2019;46(4-5):308-313. doi:10.1053/j.seminoncol.2019.09.005

Issue
Federal Practitioner - 37(4)s
Issue
Federal Practitioner - 37(4)s
Page Number
S62-S67
Page Number
S62-S67
Publications
Publications
Topics
Article Type
Display Headline
Leveraging Veterans Health Administration Clinical and Research Resources to Accelerate Discovery and Testing in Precision Oncology
Display Headline
Leveraging Veterans Health Administration Clinical and Research Resources to Accelerate Discovery and Testing in Precision Oncology
Sections
Disallow All Ads
Content Gating
No Gating (article Unlocked/Free)
Alternative CME
Disqus Comments
Default
Use ProPublica
Hide sidebar & use full width
render the right sidebar.
Conference Recap Checkbox
Not Conference Recap
Clinical Edge
Display the Slideshow in this Article
Article PDF Media