Alex Krist, MD

One day a residency program decided to put its evidence-based medicine (EBM) curriculum to good use. A group of faculty and residents conducted a thorough review of the evidence regarding liquid-based cytoloutilizegy vs conventional Pap smears. They identified the key national recommendations and reviewed the supporting evidence behind each recommendation, tracing back to the individual studies themselves.^1-3

Based on the review, the group concluded that there was insufficient evidence to recommend one method of screening over another, but that there were situations in which one method might be preferred. They presented the evidence and their conclusions to the majority of faculty and residents at grand rounds. Following the presentation, the larger group discussed the relative merits of each screening method and decided the elements of evidence that supported the liquid test were more relevant to the practice than the conventional Pap smear. As a result, a decision was made by the group to stop carrying supplies for the conventional Pap smear. While the decision seemed reasonable on the level of an individual practitioner, several faculty and residents were unhappy with the “evidence-based” decision.

KAP theory and EBM

KAP theory identifies Knowledge, Attitudes, and Practice beliefs as key elements that drive healthcare providers’ decisions about medical care. In a sense EBM represents knowledge.⁴ There is a collective body of medical knowledge in the form of research, which represents “the evidence.” And there is what the healthcare provider himself “knows.” A major purpose of healthcare recommendations, point of care information systems, and best practice guidelines is to help the healthcare provider’s individual medical knowledge reflect the collective body of evidence.

For the purposes of this example, evidence will be considered absolute, inadequate, conditional, or relative. Absolute evidence occurs when there is clearly a correct answer. For example, the net benefits of aspirin for the treatment of myocardial infarction are clear. However, for most topics the evidence is not absolute; rather, it is inconclusive.⁵ The evidence may be inconclusive because it is inadequate—eg, insufficient research, conflicting studies, or research on peripheral topics. As an example, studies have demonstrated that aspirin decreases colorectal polyps, which may or may not be peripheral to the question of whether aspirin prevents colorectal cancer.

The evidence can also be conditional, meaning that in some defined instances the net benefit is clear. However, extending this net benefit beyond these instances is less clear. For example, patients at high risk for cardiovascular disease have a clear net benefit in taking aspirin for myocardial infarction prevention. Finally, the evidence may be relative, with a balance of known benefits and known risks.⁶ Using the aspirin example for cardiovascular disease prevention, patients at moderate risk receive benefit from aspirin in preventing myocardial infarction but at a risk cost of increased bleeding.

When the evidence is inconclusive, the second and third aspects of KAP theory—attitudes and practice beliefs—become very important. Healthcare providers and patients may arrive at different conclusions based on different viewpoints. On an individual level, healthcare practitioners use tools such as shared decision-making and patient-centered care to reach decisions.^6,7 However, inconclusive evidence provides a unique challenge when trying to develop local, regional, or national standards.

Evidence heresy

EBM frequently has negative connotations. In a room full of healthcare providers, some will believe that EBM should revolutionize the practice of medicine,⁸ and some that EBM has limited utility.⁹ How does this happen? The above scenario serves as a useful example, highlighting 3 misuses of the term “evidence” that frequently give EBM a bad name.

First, inconclusive evidence should not be stated in absolute terms; rather, it is more helpful to explicitly state what we know and the limits of what we know. Shaughnessy and Slawson wrote, “Absolute certainty is absolutely impossible, and we do not have to wait for that, of course.”¹⁰ This reflects the paucity of topics with certain evidence and highlights the need for clinicians to act on the available information. Every clinician necessarily utilizes this skill on a daily basis. The clinician has to become an Information Master¹¹ and know not only the end result of what the evidence indicates but also the facts supporting the end results and how those facts apply to the care of an unique individual.¹² However, taking this a step further and stating that one answer or option is absolutely correct in all cases ventures into dangerous ground. During the residency’s discussion of cervical cancer screening tests, the group recognized the merits of both options verbally but, the act of removing all conventional Pap smear supplies implied the nonverbal judgment that liquid-based technology was an absolute correct answer.

Second, while attitudes and practice beliefs can be used to weigh elements of evidence to reach a final conclusion, the conclusion should not negate other perspectives. An important skill of an adept clinician is the ability to interweave the healthcare provider’s and the patient’s attitudes and practice beliefs into the body of existing evidence to determine the appropriate intervention.¹³ However, attitudes and practice beliefs vary from individual to individual and from community to community. When these factors play a critical role in defining the appropriate action based on the evidence, how attitudes and practice beliefs are used should be explicitly stated. In the Pap smear example, the pivotal issue of contention was the belief about whether individual practitioners should act as stewards of limited healthcare resources. Proponents of using solely the liquid-based Pap smear felt the cost problem was a national issue and that the actions of the individual clinician had little impact on global healthcare costs. Others felt their local actions affected insurance premiums, leading directly to decreased healthcare access.¹¹ For cervical cancer, the key impact on mortality is getting any form of screening.¹ Using the liquid-based method for low-risk women may increase cervical cancer mortality by increasing costs and decreasing healthcare access. Removing conventional Pap smears disempowered the latter group of clinicians from implementing their practice beliefs and attitudes.

Finally, a conclusion should not be labeled as “evidence-based” when it is really made on other grounds such as economics, law, ethics, convenience, social values, or policy. Certainly, reviewing medical evidence is an important step in making decisions. However, the process for making decisions on these factors should be held to the same standards as making medical evidence decisions. This includes defining the process and explicitly stating the basis by which final decision will be made. The US is very conflicted when it comes to dealing with these non-evidence issues. We have no national standard for incorporating costs into healthcare decisions.^14,15 With respect to healthcare delivery, we have a wide range of social values that are sometimes disproportionate to logical expectations.¹⁶ Few effective systems are in place to incorporate these elements in healthcare decisions and, as a result, “evidence” is often used as a code word to focus on other issues.

For the Pap smear example, the decision factors were really economics, law, and systems of care. Proponents of the liquid-based method cited the community standard of care, fear of malpractice, patient expectations of receiving the latest technology, and the ease of adopting one screening method for the entire office. Others felt these issues, although important, were secondary to the lack of evidence supporting a liquid-based system as a sole screening method. For lowrisk women, adopting the liquid-based method only makes economic sense if screening is done every 2 or 3 years.¹⁷ However, many low-risk women still favor performing a Pap smear annually.¹⁸ As a result a decision-making process other than the strict EBM method, focusing on other factors would be necessary to change the practice standard.

Conclusions: Recognize the limitations of EBM

Cervical cancer screening serves as a common example of a difficult decision healthcare providers are faced with on a daily basis—what to do when evidence, based on patient oriented outcomes, is inconclusive. Providers do not have the luxury of merely stating the evidence is inconclusive; they must act. Frequently decisions are based on attitudes and practice beliefs in a broader context of unique economic, legal, and practice environments.

EBM is one tool in the decision-making armamentarium. It is a very powerful tool and has had a very positive impact on healthcare. Its methods have been well defined and explicitly stated. However, failing to recognize its limitations and making a decision under the rubric of EBM, when other variables are clearly playing a role, perpetuates the perception of its limited utility. Advocates of EBM need to wield this instrument carefully and judiciously.

CORRESPONDENCE
Alex Krist, MD, 3825 Charles Stewart Drive, Fairfax VA 22033. E-mail: ahkrist@vcu.edu

One day a residency program decided to put its evidence-based medicine (EBM) curriculum to good use. A group of faculty and residents conducted a thorough review of the evidence regarding liquid-based cytoloutilizegy vs conventional Pap smears. They identified the key national recommendations and reviewed the supporting evidence behind each recommendation, tracing back to the individual studies themselves.^1-3

Based on the review, the group concluded that there was insufficient evidence to recommend one method of screening over another, but that there were situations in which one method might be preferred. They presented the evidence and their conclusions to the majority of faculty and residents at grand rounds. Following the presentation, the larger group discussed the relative merits of each screening method and decided the elements of evidence that supported the liquid test were more relevant to the practice than the conventional Pap smear. As a result, a decision was made by the group to stop carrying supplies for the conventional Pap smear. While the decision seemed reasonable on the level of an individual practitioner, several faculty and residents were unhappy with the “evidence-based” decision.

KAP theory and EBM

KAP theory identifies Knowledge, Attitudes, and Practice beliefs as key elements that drive healthcare providers’ decisions about medical care. In a sense EBM represents knowledge.⁴ There is a collective body of medical knowledge in the form of research, which represents “the evidence.” And there is what the healthcare provider himself “knows.” A major purpose of healthcare recommendations, point of care information systems, and best practice guidelines is to help the healthcare provider’s individual medical knowledge reflect the collective body of evidence.

For the purposes of this example, evidence will be considered absolute, inadequate, conditional, or relative. Absolute evidence occurs when there is clearly a correct answer. For example, the net benefits of aspirin for the treatment of myocardial infarction are clear. However, for most topics the evidence is not absolute; rather, it is inconclusive.⁵ The evidence may be inconclusive because it is inadequate—eg, insufficient research, conflicting studies, or research on peripheral topics. As an example, studies have demonstrated that aspirin decreases colorectal polyps, which may or may not be peripheral to the question of whether aspirin prevents colorectal cancer.

The evidence can also be conditional, meaning that in some defined instances the net benefit is clear. However, extending this net benefit beyond these instances is less clear. For example, patients at high risk for cardiovascular disease have a clear net benefit in taking aspirin for myocardial infarction prevention. Finally, the evidence may be relative, with a balance of known benefits and known risks.⁶ Using the aspirin example for cardiovascular disease prevention, patients at moderate risk receive benefit from aspirin in preventing myocardial infarction but at a risk cost of increased bleeding.

When the evidence is inconclusive, the second and third aspects of KAP theory—attitudes and practice beliefs—become very important. Healthcare providers and patients may arrive at different conclusions based on different viewpoints. On an individual level, healthcare practitioners use tools such as shared decision-making and patient-centered care to reach decisions.^6,7 However, inconclusive evidence provides a unique challenge when trying to develop local, regional, or national standards.

Evidence heresy

EBM frequently has negative connotations. In a room full of healthcare providers, some will believe that EBM should revolutionize the practice of medicine,⁸ and some that EBM has limited utility.⁹ How does this happen? The above scenario serves as a useful example, highlighting 3 misuses of the term “evidence” that frequently give EBM a bad name.

First, inconclusive evidence should not be stated in absolute terms; rather, it is more helpful to explicitly state what we know and the limits of what we know. Shaughnessy and Slawson wrote, “Absolute certainty is absolutely impossible, and we do not have to wait for that, of course.”¹⁰ This reflects the paucity of topics with certain evidence and highlights the need for clinicians to act on the available information. Every clinician necessarily utilizes this skill on a daily basis. The clinician has to become an Information Master¹¹ and know not only the end result of what the evidence indicates but also the facts supporting the end results and how those facts apply to the care of an unique individual.¹² However, taking this a step further and stating that one answer or option is absolutely correct in all cases ventures into dangerous ground. During the residency’s discussion of cervical cancer screening tests, the group recognized the merits of both options verbally but, the act of removing all conventional Pap smear supplies implied the nonverbal judgment that liquid-based technology was an absolute correct answer.

Second, while attitudes and practice beliefs can be used to weigh elements of evidence to reach a final conclusion, the conclusion should not negate other perspectives. An important skill of an adept clinician is the ability to interweave the healthcare provider’s and the patient’s attitudes and practice beliefs into the body of existing evidence to determine the appropriate intervention.¹³ However, attitudes and practice beliefs vary from individual to individual and from community to community. When these factors play a critical role in defining the appropriate action based on the evidence, how attitudes and practice beliefs are used should be explicitly stated. In the Pap smear example, the pivotal issue of contention was the belief about whether individual practitioners should act as stewards of limited healthcare resources. Proponents of using solely the liquid-based Pap smear felt the cost problem was a national issue and that the actions of the individual clinician had little impact on global healthcare costs. Others felt their local actions affected insurance premiums, leading directly to decreased healthcare access.¹¹ For cervical cancer, the key impact on mortality is getting any form of screening.¹ Using the liquid-based method for low-risk women may increase cervical cancer mortality by increasing costs and decreasing healthcare access. Removing conventional Pap smears disempowered the latter group of clinicians from implementing their practice beliefs and attitudes.

Finally, a conclusion should not be labeled as “evidence-based” when it is really made on other grounds such as economics, law, ethics, convenience, social values, or policy. Certainly, reviewing medical evidence is an important step in making decisions. However, the process for making decisions on these factors should be held to the same standards as making medical evidence decisions. This includes defining the process and explicitly stating the basis by which final decision will be made. The US is very conflicted when it comes to dealing with these non-evidence issues. We have no national standard for incorporating costs into healthcare decisions.^14,15 With respect to healthcare delivery, we have a wide range of social values that are sometimes disproportionate to logical expectations.¹⁶ Few effective systems are in place to incorporate these elements in healthcare decisions and, as a result, “evidence” is often used as a code word to focus on other issues.

For the Pap smear example, the decision factors were really economics, law, and systems of care. Proponents of the liquid-based method cited the community standard of care, fear of malpractice, patient expectations of receiving the latest technology, and the ease of adopting one screening method for the entire office. Others felt these issues, although important, were secondary to the lack of evidence supporting a liquid-based system as a sole screening method. For lowrisk women, adopting the liquid-based method only makes economic sense if screening is done every 2 or 3 years.¹⁷ However, many low-risk women still favor performing a Pap smear annually.¹⁸ As a result a decision-making process other than the strict EBM method, focusing on other factors would be necessary to change the practice standard.

Conclusions: Recognize the limitations of EBM

Cervical cancer screening serves as a common example of a difficult decision healthcare providers are faced with on a daily basis—what to do when evidence, based on patient oriented outcomes, is inconclusive. Providers do not have the luxury of merely stating the evidence is inconclusive; they must act. Frequently decisions are based on attitudes and practice beliefs in a broader context of unique economic, legal, and practice environments.

EBM is one tool in the decision-making armamentarium. It is a very powerful tool and has had a very positive impact on healthcare. Its methods have been well defined and explicitly stated. However, failing to recognize its limitations and making a decision under the rubric of EBM, when other variables are clearly playing a role, perpetuates the perception of its limited utility. Advocates of EBM need to wield this instrument carefully and judiciously.

CORRESPONDENCE
Alex Krist, MD, 3825 Charles Stewart Drive, Fairfax VA 22033. E-mail: ahkrist@vcu.edu

One day a residency program decided to put its evidence-based medicine (EBM) curriculum to good use. A group of faculty and residents conducted a thorough review of the evidence regarding liquid-based cytoloutilizegy vs conventional Pap smears. They identified the key national recommendations and reviewed the supporting evidence behind each recommendation, tracing back to the individual studies themselves.^1-3

Based on the review, the group concluded that there was insufficient evidence to recommend one method of screening over another, but that there were situations in which one method might be preferred. They presented the evidence and their conclusions to the majority of faculty and residents at grand rounds. Following the presentation, the larger group discussed the relative merits of each screening method and decided the elements of evidence that supported the liquid test were more relevant to the practice than the conventional Pap smear. As a result, a decision was made by the group to stop carrying supplies for the conventional Pap smear. While the decision seemed reasonable on the level of an individual practitioner, several faculty and residents were unhappy with the “evidence-based” decision.

KAP theory and EBM

KAP theory identifies Knowledge, Attitudes, and Practice beliefs as key elements that drive healthcare providers’ decisions about medical care. In a sense EBM represents knowledge.⁴ There is a collective body of medical knowledge in the form of research, which represents “the evidence.” And there is what the healthcare provider himself “knows.” A major purpose of healthcare recommendations, point of care information systems, and best practice guidelines is to help the healthcare provider’s individual medical knowledge reflect the collective body of evidence.

For the purposes of this example, evidence will be considered absolute, inadequate, conditional, or relative. Absolute evidence occurs when there is clearly a correct answer. For example, the net benefits of aspirin for the treatment of myocardial infarction are clear. However, for most topics the evidence is not absolute; rather, it is inconclusive.⁵ The evidence may be inconclusive because it is inadequate—eg, insufficient research, conflicting studies, or research on peripheral topics. As an example, studies have demonstrated that aspirin decreases colorectal polyps, which may or may not be peripheral to the question of whether aspirin prevents colorectal cancer.

The evidence can also be conditional, meaning that in some defined instances the net benefit is clear. However, extending this net benefit beyond these instances is less clear. For example, patients at high risk for cardiovascular disease have a clear net benefit in taking aspirin for myocardial infarction prevention. Finally, the evidence may be relative, with a balance of known benefits and known risks.⁶ Using the aspirin example for cardiovascular disease prevention, patients at moderate risk receive benefit from aspirin in preventing myocardial infarction but at a risk cost of increased bleeding.

When the evidence is inconclusive, the second and third aspects of KAP theory—attitudes and practice beliefs—become very important. Healthcare providers and patients may arrive at different conclusions based on different viewpoints. On an individual level, healthcare practitioners use tools such as shared decision-making and patient-centered care to reach decisions.^6,7 However, inconclusive evidence provides a unique challenge when trying to develop local, regional, or national standards.

Evidence heresy

EBM frequently has negative connotations. In a room full of healthcare providers, some will believe that EBM should revolutionize the practice of medicine,⁸ and some that EBM has limited utility.⁹ How does this happen? The above scenario serves as a useful example, highlighting 3 misuses of the term “evidence” that frequently give EBM a bad name.

First, inconclusive evidence should not be stated in absolute terms; rather, it is more helpful to explicitly state what we know and the limits of what we know. Shaughnessy and Slawson wrote, “Absolute certainty is absolutely impossible, and we do not have to wait for that, of course.”¹⁰ This reflects the paucity of topics with certain evidence and highlights the need for clinicians to act on the available information. Every clinician necessarily utilizes this skill on a daily basis. The clinician has to become an Information Master¹¹ and know not only the end result of what the evidence indicates but also the facts supporting the end results and how those facts apply to the care of an unique individual.¹² However, taking this a step further and stating that one answer or option is absolutely correct in all cases ventures into dangerous ground. During the residency’s discussion of cervical cancer screening tests, the group recognized the merits of both options verbally but, the act of removing all conventional Pap smear supplies implied the nonverbal judgment that liquid-based technology was an absolute correct answer.

Second, while attitudes and practice beliefs can be used to weigh elements of evidence to reach a final conclusion, the conclusion should not negate other perspectives. An important skill of an adept clinician is the ability to interweave the healthcare provider’s and the patient’s attitudes and practice beliefs into the body of existing evidence to determine the appropriate intervention.¹³ However, attitudes and practice beliefs vary from individual to individual and from community to community. When these factors play a critical role in defining the appropriate action based on the evidence, how attitudes and practice beliefs are used should be explicitly stated. In the Pap smear example, the pivotal issue of contention was the belief about whether individual practitioners should act as stewards of limited healthcare resources. Proponents of using solely the liquid-based Pap smear felt the cost problem was a national issue and that the actions of the individual clinician had little impact on global healthcare costs. Others felt their local actions affected insurance premiums, leading directly to decreased healthcare access.¹¹ For cervical cancer, the key impact on mortality is getting any form of screening.¹ Using the liquid-based method for low-risk women may increase cervical cancer mortality by increasing costs and decreasing healthcare access. Removing conventional Pap smears disempowered the latter group of clinicians from implementing their practice beliefs and attitudes.

Finally, a conclusion should not be labeled as “evidence-based” when it is really made on other grounds such as economics, law, ethics, convenience, social values, or policy. Certainly, reviewing medical evidence is an important step in making decisions. However, the process for making decisions on these factors should be held to the same standards as making medical evidence decisions. This includes defining the process and explicitly stating the basis by which final decision will be made. The US is very conflicted when it comes to dealing with these non-evidence issues. We have no national standard for incorporating costs into healthcare decisions.^14,15 With respect to healthcare delivery, we have a wide range of social values that are sometimes disproportionate to logical expectations.¹⁶ Few effective systems are in place to incorporate these elements in healthcare decisions and, as a result, “evidence” is often used as a code word to focus on other issues.

For the Pap smear example, the decision factors were really economics, law, and systems of care. Proponents of the liquid-based method cited the community standard of care, fear of malpractice, patient expectations of receiving the latest technology, and the ease of adopting one screening method for the entire office. Others felt these issues, although important, were secondary to the lack of evidence supporting a liquid-based system as a sole screening method. For lowrisk women, adopting the liquid-based method only makes economic sense if screening is done every 2 or 3 years.¹⁷ However, many low-risk women still favor performing a Pap smear annually.¹⁸ As a result a decision-making process other than the strict EBM method, focusing on other factors would be necessary to change the practice standard.

Conclusions: Recognize the limitations of EBM

Cervical cancer screening serves as a common example of a difficult decision healthcare providers are faced with on a daily basis—what to do when evidence, based on patient oriented outcomes, is inconclusive. Providers do not have the luxury of merely stating the evidence is inconclusive; they must act. Frequently decisions are based on attitudes and practice beliefs in a broader context of unique economic, legal, and practice environments.

EBM is one tool in the decision-making armamentarium. It is a very powerful tool and has had a very positive impact on healthcare. Its methods have been well defined and explicitly stated. However, failing to recognize its limitations and making a decision under the rubric of EBM, when other variables are clearly playing a role, perpetuates the perception of its limited utility. Advocates of EBM need to wield this instrument carefully and judiciously.

CORRESPONDENCE
Alex Krist, MD, 3825 Charles Stewart Drive, Fairfax VA 22033. E-mail: ahkrist@vcu.edu

Evidence summary

Osteoporosis results in significant morbidity and mortality. In a prospective observational study of women over 50 years of age, 39.6% had osteopenia and 7.2% had osteoporosis. Osteoporosis was associated with a fracture rate 4 times that of normal bone mineral density.¹ People with vertebral or hip fractures have a reduced relative 5-year survival of 0.81. Excess mortality occurred within the first 6 months following fracture.²

One prospective cohort study identified 14 independent risk factors for hip fracture.³ The best predictors were female gender, age, low weight, and no current estrogen use. For women aged >65 years with no other risks, 12% to 28% have osteoporosis.⁴ Multiple risk assessment scales have been studied to identify women aged >65 years who are at increased risk; however, none of the scales had good discriminatory performance.⁵ As a result, it is unclear which factors for women under 65 years should trigger screening.

While multiple technologies exist to measure bone mineral density, dual-energy x-ray absorptiometry (DEXA) has been the most validated test for predicting fractures. A meta-analysis of 11 prospective cohort trials showed that all sites of bone mineral density measurements correlated with fractures (relative risk [RR], 1.5; 95% confi-dence interval [CI], 1.4–1.6.). However, DEXA of the femoral neck predicted hip fracture better than other measures (RR, 2.6; 95% CI, 2.0–3.5).⁶

Additionally, heel ultrasonography was compa-rable with hip DEXA for predicting hip fractures for women over 65 years (probability of fracture 0.018 vs. 0.023); no studies have compared effec-tiveness for women under 65 years.

Multiple therapeutic interventions for osteo-porosis have been demonstrated to reduce frac-tures. Adequate calcium and vitamin D appear to prevent fractures. Alendronate and rise-dronate are the only prescription medications with evidence showing they prevent hip fractures.

A meta-analysis of 11 randomized controlled trials including 11,808 women found fewer hip fractures in women taking 10 mg/day of alendronate (RR, 0.51; 95% CI, 0.38–0.69; number needed to treat [NNT]=24), and fewer vertebral fractures in women taking 5 mg/day of alendronate (RR, 0.52; 95% CI, 0.43–0.65; NNT=72).⁷

For these results to apply to screening, study participants must be similar to those identified by general population screening. All trials included healthy women with low bone mineral density who were not using estrogen, which is similar to women identified by general screening. However, 57% of women recruited for the second Fracture Intervention Trial (FIT-II), the largest study, were classified as ineligible. This raises concern about the study’s generalizability.⁸

The US Preventive Services Task Force did an outcomes estimation of screening effectiveness, combining all of the above data (Table).⁹ Screening 731 women aged 65 to 69 years would prevent 1 hip fracture if those with indications for treat-ment took it; screening 248 women would prevent 1 vertebral fracture. As the table demonstrates, benefits increase with age. For women under 65 years, benefits are relatively small, unless they have other risk factors for osteoporosis.

TABLE
Hip and vertebral fracture outcomes for osteoporosis screening in 10,000 postmenopausal women ⁹

Recommendations from others

Based on their outcomes model, the US Preventive Services Task Force recommends screening for women aged >65 years, and those aged 60 to 65 years who have risk factors.⁹ In 1998, the National Osteoporosis Foundation, in collaboration with many other professional organ-izations, recommended bone mineral density test-ing for all women aged >65 years and younger postmenopausal women who have had or are at risk for fractures.¹⁰ The 2000 Consensus Development Conference from the National Institutes of Health recommended an individual-ized approach to screening, stating evidence for universal osteoporosis screening is inconclusive.¹¹ The American Association of Clinical Endo-crinologists revised guidelines in 2001 to include screening younger postmenopausal women with a body weight <127 lbs or a family history of nontraumatic spine or hip fracture.¹²

Evidence summary

Osteoporosis results in significant morbidity and mortality. In a prospective observational study of women over 50 years of age, 39.6% had osteopenia and 7.2% had osteoporosis. Osteoporosis was associated with a fracture rate 4 times that of normal bone mineral density.¹ People with vertebral or hip fractures have a reduced relative 5-year survival of 0.81. Excess mortality occurred within the first 6 months following fracture.²

One prospective cohort study identified 14 independent risk factors for hip fracture.³ The best predictors were female gender, age, low weight, and no current estrogen use. For women aged >65 years with no other risks, 12% to 28% have osteoporosis.⁴ Multiple risk assessment scales have been studied to identify women aged >65 years who are at increased risk; however, none of the scales had good discriminatory performance.⁵ As a result, it is unclear which factors for women under 65 years should trigger screening.

While multiple technologies exist to measure bone mineral density, dual-energy x-ray absorptiometry (DEXA) has been the most validated test for predicting fractures. A meta-analysis of 11 prospective cohort trials showed that all sites of bone mineral density measurements correlated with fractures (relative risk [RR], 1.5; 95% confi-dence interval [CI], 1.4–1.6.). However, DEXA of the femoral neck predicted hip fracture better than other measures (RR, 2.6; 95% CI, 2.0–3.5).⁶

Additionally, heel ultrasonography was compa-rable with hip DEXA for predicting hip fractures for women over 65 years (probability of fracture 0.018 vs. 0.023); no studies have compared effec-tiveness for women under 65 years.

Multiple therapeutic interventions for osteo-porosis have been demonstrated to reduce frac-tures. Adequate calcium and vitamin D appear to prevent fractures. Alendronate and rise-dronate are the only prescription medications with evidence showing they prevent hip fractures.

A meta-analysis of 11 randomized controlled trials including 11,808 women found fewer hip fractures in women taking 10 mg/day of alendronate (RR, 0.51; 95% CI, 0.38–0.69; number needed to treat [NNT]=24), and fewer vertebral fractures in women taking 5 mg/day of alendronate (RR, 0.52; 95% CI, 0.43–0.65; NNT=72).⁷

For these results to apply to screening, study participants must be similar to those identified by general population screening. All trials included healthy women with low bone mineral density who were not using estrogen, which is similar to women identified by general screening. However, 57% of women recruited for the second Fracture Intervention Trial (FIT-II), the largest study, were classified as ineligible. This raises concern about the study’s generalizability.⁸

The US Preventive Services Task Force did an outcomes estimation of screening effectiveness, combining all of the above data (Table).⁹ Screening 731 women aged 65 to 69 years would prevent 1 hip fracture if those with indications for treat-ment took it; screening 248 women would prevent 1 vertebral fracture. As the table demonstrates, benefits increase with age. For women under 65 years, benefits are relatively small, unless they have other risk factors for osteoporosis.

TABLE
Hip and vertebral fracture outcomes for osteoporosis screening in 10,000 postmenopausal women ⁹

Recommendations from others

Based on their outcomes model, the US Preventive Services Task Force recommends screening for women aged >65 years, and those aged 60 to 65 years who have risk factors.⁹ In 1998, the National Osteoporosis Foundation, in collaboration with many other professional organ-izations, recommended bone mineral density test-ing for all women aged >65 years and younger postmenopausal women who have had or are at risk for fractures.¹⁰ The 2000 Consensus Development Conference from the National Institutes of Health recommended an individual-ized approach to screening, stating evidence for universal osteoporosis screening is inconclusive.¹¹ The American Association of Clinical Endo-crinologists revised guidelines in 2001 to include screening younger postmenopausal women with a body weight <127 lbs or a family history of nontraumatic spine or hip fracture.¹²

Evidence summary

Osteoporosis results in significant morbidity and mortality. In a prospective observational study of women over 50 years of age, 39.6% had osteopenia and 7.2% had osteoporosis. Osteoporosis was associated with a fracture rate 4 times that of normal bone mineral density.¹ People with vertebral or hip fractures have a reduced relative 5-year survival of 0.81. Excess mortality occurred within the first 6 months following fracture.²

One prospective cohort study identified 14 independent risk factors for hip fracture.³ The best predictors were female gender, age, low weight, and no current estrogen use. For women aged >65 years with no other risks, 12% to 28% have osteoporosis.⁴ Multiple risk assessment scales have been studied to identify women aged >65 years who are at increased risk; however, none of the scales had good discriminatory performance.⁵ As a result, it is unclear which factors for women under 65 years should trigger screening.

While multiple technologies exist to measure bone mineral density, dual-energy x-ray absorptiometry (DEXA) has been the most validated test for predicting fractures. A meta-analysis of 11 prospective cohort trials showed that all sites of bone mineral density measurements correlated with fractures (relative risk [RR], 1.5; 95% confi-dence interval [CI], 1.4–1.6.). However, DEXA of the femoral neck predicted hip fracture better than other measures (RR, 2.6; 95% CI, 2.0–3.5).⁶

Additionally, heel ultrasonography was compa-rable with hip DEXA for predicting hip fractures for women over 65 years (probability of fracture 0.018 vs. 0.023); no studies have compared effec-tiveness for women under 65 years.

Multiple therapeutic interventions for osteo-porosis have been demonstrated to reduce frac-tures. Adequate calcium and vitamin D appear to prevent fractures. Alendronate and rise-dronate are the only prescription medications with evidence showing they prevent hip fractures.

A meta-analysis of 11 randomized controlled trials including 11,808 women found fewer hip fractures in women taking 10 mg/day of alendronate (RR, 0.51; 95% CI, 0.38–0.69; number needed to treat [NNT]=24), and fewer vertebral fractures in women taking 5 mg/day of alendronate (RR, 0.52; 95% CI, 0.43–0.65; NNT=72).⁷

For these results to apply to screening, study participants must be similar to those identified by general population screening. All trials included healthy women with low bone mineral density who were not using estrogen, which is similar to women identified by general screening. However, 57% of women recruited for the second Fracture Intervention Trial (FIT-II), the largest study, were classified as ineligible. This raises concern about the study’s generalizability.⁸

The US Preventive Services Task Force did an outcomes estimation of screening effectiveness, combining all of the above data (Table).⁹ Screening 731 women aged 65 to 69 years would prevent 1 hip fracture if those with indications for treat-ment took it; screening 248 women would prevent 1 vertebral fracture. As the table demonstrates, benefits increase with age. For women under 65 years, benefits are relatively small, unless they have other risk factors for osteoporosis.

TABLE
Hip and vertebral fracture outcomes for osteoporosis screening in 10,000 postmenopausal women ⁹

Recommendations from others

Based on their outcomes model, the US Preventive Services Task Force recommends screening for women aged >65 years, and those aged 60 to 65 years who have risk factors.⁹ In 1998, the National Osteoporosis Foundation, in collaboration with many other professional organ-izations, recommended bone mineral density test-ing for all women aged >65 years and younger postmenopausal women who have had or are at risk for fractures.¹⁰ The 2000 Consensus Development Conference from the National Institutes of Health recommended an individual-ized approach to screening, stating evidence for universal osteoporosis screening is inconclusive.¹¹ The American Association of Clinical Endo-crinologists revised guidelines in 2001 to include screening younger postmenopausal women with a body weight <127 lbs or a family history of nontraumatic spine or hip fracture.¹²

BACKGROUND: The current recommendation for management of uncomplicated pyelonephritis is a 14-day course of ciprofloxacin.¹ Studies have shown this to be 90% effective.² Few studies have evaluated shorter courses of therapy for pyelonephritis. The purpose of this study was to compare the effectiveness of 7 days of ciprofloxacin with 14 days of trimethoprim-sulfamethoxazole (TMP-SMZ) for treatment of acute uncomplicated pyelonephritis in an outpatient setting.

POPULATION STUDIED: The study participants were premenopausal women aged 18 years or older with a clinical diagnosis of pyelonephritis, defined as flank pain or costovertebral angle tenderness, fever, and pyuria. Patients were excluded if they had abnormal renal function (creatinine >2.7), severe sepsis, urologic abnormalities, persistent vomiting, or if they were immunocompromised, had diabetes, were admitted to the hospital, or were pregnant or lactating.

STUDY DESIGN AND VALIDITY: A total of 378 patients were randomized to receive either 7 days of ciprofloxacin 500 mg twice daily or 14 days of TMP-SMZ 800/160 mg twice daily. In both groups, managing physicians had the option to treat patients with an initial dose of intravenous antibiotic, if clinically indicated (400 mg of ciprofloxacin in the ciprofloxacin group or 1 gram of ceftriaxone in the TMP-SMZ group). Blood cultures and a urine culture were obtained by either clean catch or catheterization before therapy was initiated. Urine cultures were repeated on days 3 to 5 of treatment. Patients were evaluated at 4 to 11 days and 22 to 48 days following treatment to assess for clinical cure and to repeat urine cultures.

OUTCOMES MEASURED: Primary study outcomes were bacteriologic and clinical cures at a visit 4 to 11 days post-therapy, as determined by urine culture and signs and symptoms, respectively. Secondary outcomes included bacteriologic and clinical responses at the visit 22 to 48 days post-therapy, adverse drug events, and a health resource analysis.

RESULTS: At 4 to 11 days post-therapy, the efficacy analysis showed that patients treated with ciprofloxacin had a better bacteriologic cure rate than the patients treated with TMP-SMZ (99% vs 89%, P=.004; number needed to treat [NNT]=10) and a better clinical cure rate (96% vs 83%, P=.002; NNT=7.6). Escherichia coli represented 90% of cultured organisms, of which 18% were resistant to TMP-SMZ, and <1% were resistant to ciprofloxacin. When the analysis was done using only organisms sensitive to TMP-SMZ, the efficacy rates were similar. An initial IV dose was associated with a greater cure rate in the TMP-SMZ group, but not in the ciprofloxacin group. In the intention-to-treat analysis, clinical cure rates for ciprofloxacin were better than TMP-SMZ at 22 to 48 days post-therapy (82% vs 72%; 95% confidence interval [CI], 0.01-0.19; NNT=10). Benefits were also seen when comparing ciprofloxacin with TMP-SMZ for bacteriologic cure (84% vs 74%; 95% CI, 0.01-0.19; NNT=10). Adverse events occurred in 24% of the ciprofloxacin and 33% of the TMP-SMZ group; 6% of patients taking ciprofloxacin and 11% taking TMP-SMZ discontinued the drug. The cost per cure was $615 for ciprofloxacin compared with $770 for TMP-SMZ; however, this study did not have enough power to detect a statistically significant difference.

BACKGROUND: The current recommendation for management of uncomplicated pyelonephritis is a 14-day course of ciprofloxacin.¹ Studies have shown this to be 90% effective.² Few studies have evaluated shorter courses of therapy for pyelonephritis. The purpose of this study was to compare the effectiveness of 7 days of ciprofloxacin with 14 days of trimethoprim-sulfamethoxazole (TMP-SMZ) for treatment of acute uncomplicated pyelonephritis in an outpatient setting.

POPULATION STUDIED: The study participants were premenopausal women aged 18 years or older with a clinical diagnosis of pyelonephritis, defined as flank pain or costovertebral angle tenderness, fever, and pyuria. Patients were excluded if they had abnormal renal function (creatinine >2.7), severe sepsis, urologic abnormalities, persistent vomiting, or if they were immunocompromised, had diabetes, were admitted to the hospital, or were pregnant or lactating.

STUDY DESIGN AND VALIDITY: A total of 378 patients were randomized to receive either 7 days of ciprofloxacin 500 mg twice daily or 14 days of TMP-SMZ 800/160 mg twice daily. In both groups, managing physicians had the option to treat patients with an initial dose of intravenous antibiotic, if clinically indicated (400 mg of ciprofloxacin in the ciprofloxacin group or 1 gram of ceftriaxone in the TMP-SMZ group). Blood cultures and a urine culture were obtained by either clean catch or catheterization before therapy was initiated. Urine cultures were repeated on days 3 to 5 of treatment. Patients were evaluated at 4 to 11 days and 22 to 48 days following treatment to assess for clinical cure and to repeat urine cultures.

OUTCOMES MEASURED: Primary study outcomes were bacteriologic and clinical cures at a visit 4 to 11 days post-therapy, as determined by urine culture and signs and symptoms, respectively. Secondary outcomes included bacteriologic and clinical responses at the visit 22 to 48 days post-therapy, adverse drug events, and a health resource analysis.

RESULTS: At 4 to 11 days post-therapy, the efficacy analysis showed that patients treated with ciprofloxacin had a better bacteriologic cure rate than the patients treated with TMP-SMZ (99% vs 89%, P=.004; number needed to treat [NNT]=10) and a better clinical cure rate (96% vs 83%, P=.002; NNT=7.6). Escherichia coli represented 90% of cultured organisms, of which 18% were resistant to TMP-SMZ, and <1% were resistant to ciprofloxacin. When the analysis was done using only organisms sensitive to TMP-SMZ, the efficacy rates were similar. An initial IV dose was associated with a greater cure rate in the TMP-SMZ group, but not in the ciprofloxacin group. In the intention-to-treat analysis, clinical cure rates for ciprofloxacin were better than TMP-SMZ at 22 to 48 days post-therapy (82% vs 72%; 95% confidence interval [CI], 0.01-0.19; NNT=10). Benefits were also seen when comparing ciprofloxacin with TMP-SMZ for bacteriologic cure (84% vs 74%; 95% CI, 0.01-0.19; NNT=10). Adverse events occurred in 24% of the ciprofloxacin and 33% of the TMP-SMZ group; 6% of patients taking ciprofloxacin and 11% taking TMP-SMZ discontinued the drug. The cost per cure was $615 for ciprofloxacin compared with $770 for TMP-SMZ; however, this study did not have enough power to detect a statistically significant difference.

BACKGROUND: The current recommendation for management of uncomplicated pyelonephritis is a 14-day course of ciprofloxacin.¹ Studies have shown this to be 90% effective.² Few studies have evaluated shorter courses of therapy for pyelonephritis. The purpose of this study was to compare the effectiveness of 7 days of ciprofloxacin with 14 days of trimethoprim-sulfamethoxazole (TMP-SMZ) for treatment of acute uncomplicated pyelonephritis in an outpatient setting.

POPULATION STUDIED: The study participants were premenopausal women aged 18 years or older with a clinical diagnosis of pyelonephritis, defined as flank pain or costovertebral angle tenderness, fever, and pyuria. Patients were excluded if they had abnormal renal function (creatinine >2.7), severe sepsis, urologic abnormalities, persistent vomiting, or if they were immunocompromised, had diabetes, were admitted to the hospital, or were pregnant or lactating.

STUDY DESIGN AND VALIDITY: A total of 378 patients were randomized to receive either 7 days of ciprofloxacin 500 mg twice daily or 14 days of TMP-SMZ 800/160 mg twice daily. In both groups, managing physicians had the option to treat patients with an initial dose of intravenous antibiotic, if clinically indicated (400 mg of ciprofloxacin in the ciprofloxacin group or 1 gram of ceftriaxone in the TMP-SMZ group). Blood cultures and a urine culture were obtained by either clean catch or catheterization before therapy was initiated. Urine cultures were repeated on days 3 to 5 of treatment. Patients were evaluated at 4 to 11 days and 22 to 48 days following treatment to assess for clinical cure and to repeat urine cultures.

OUTCOMES MEASURED: Primary study outcomes were bacteriologic and clinical cures at a visit 4 to 11 days post-therapy, as determined by urine culture and signs and symptoms, respectively. Secondary outcomes included bacteriologic and clinical responses at the visit 22 to 48 days post-therapy, adverse drug events, and a health resource analysis.

RESULTS: At 4 to 11 days post-therapy, the efficacy analysis showed that patients treated with ciprofloxacin had a better bacteriologic cure rate than the patients treated with TMP-SMZ (99% vs 89%, P=.004; number needed to treat [NNT]=10) and a better clinical cure rate (96% vs 83%, P=.002; NNT=7.6). Escherichia coli represented 90% of cultured organisms, of which 18% were resistant to TMP-SMZ, and <1% were resistant to ciprofloxacin. When the analysis was done using only organisms sensitive to TMP-SMZ, the efficacy rates were similar. An initial IV dose was associated with a greater cure rate in the TMP-SMZ group, but not in the ciprofloxacin group. In the intention-to-treat analysis, clinical cure rates for ciprofloxacin were better than TMP-SMZ at 22 to 48 days post-therapy (82% vs 72%; 95% confidence interval [CI], 0.01-0.19; NNT=10). Benefits were also seen when comparing ciprofloxacin with TMP-SMZ for bacteriologic cure (84% vs 74%; 95% CI, 0.01-0.19; NNT=10). Adverse events occurred in 24% of the ciprofloxacin and 33% of the TMP-SMZ group; 6% of patients taking ciprofloxacin and 11% taking TMP-SMZ discontinued the drug. The cost per cure was $615 for ciprofloxacin compared with $770 for TMP-SMZ; however, this study did not have enough power to detect a statistically significant difference.