Drones can deliver blood products, but hurdles remain

Photo by Cristina Granados

BOSTON—Drone-delivered blood products may be coming soon to a hospital near you, experts said at AABB 2018.

Using a system of completely autonomous delivery drones launched from a central location, U.S.-based Zipline International delivers blood products to treat postpartum hemorrhage, trauma, malaria, and other life-threatening conditions to patients in rural Rwanda, according to company spokesman Chris Kenney.

“In less than 2 years in Rwanda, we’ve made almost 10,000 deliveries,” Kenney said. “That’s almost 20,000 units of blood.”

One-third of all deliveries are needed for urgent, life-saving interventions, he added.

The system, which delivers 30% of all blood products used in Rwanda outside the capital Kigali, has resulted in 100% availability of blood products when needed, a 98% reduction in waste (i.e., when unused blood products are discarded because of age), and a 175% increase in the use of platelets and fresh frozen plasma, according to Kenney.

How it works

Kenney described the case of a 24-year-old Rwandan woman who had uncontrolled bleeding from complications following a cesarean section.

The clinicians treating her opted to give her an immediate red blood cell transfusion, but she continued to bleed, and the hospital ran out of red blood cells in about 15 minutes.

They placed an order for more blood products, which can be done by text message or via WhatsApp, a free messaging and voiceover IP calling service.

After the order was placed, Zipline was able to deliver blood products using multiple drone launches over the course of 90 minutes. The deliveries consisted of 7 units of red blood cells, 4 units of plasma, and 2 units of platelets, all of which were transfused into the patient and allowed her condition to stabilize.

Deliveries that would take a minimum of 3 hours by road can be accomplished in about 15 to 25 minutes by air, Kenney said.

The drones—more formally known as “unmanned aerial vehicles”—fly a loop starting at the distribution center, find their target, descend to a height of about 10 meters, and drop the package, which has a parachute attached.

Packages can be delivered within a drop zone the size of two parking spaces, even in gale-force winds, Kenney said.

“The whole process is 100% autonomous,” he noted. “The aircraft knows where it’s going, it knows what conditions [are], it knows what its payload characteristics are and flies to the delivery point and drops its package.”

As drones return to the distribution center, they are snared from the air with a wire that catches a small tail hook on the fuselage.

Airborne deliveries are significantly cheaper than ground-based services for local delivery, according to Paul Eastvold, MD, chief medical officer at Vitalant, a nonprofit network of community blood banks headquartered in Spokane, Wash.

Dr. Eastvold cited statistics suggesting the cost of ground shipping from a local warehouse by carriers such as UPS or FedEx could be $6 or more. However, drone delivery could be as cheap as 5 cents per mile.

Barriers to drone delivery

Setting up an airborne delivery network in the largely unregulated and uncrowded Rwandan airspace was a relatively simple process, compared with the myriad challenges of establishing a similar system for deliveries to urban medical centers in Boston, Chicago, New York, or Los Angeles, according to Dr. Eastvold.

He described the hurdles that will need to be surmounted before blood-delivery drones are as common a sight as traffic helicopters in the United States.

Dr. Eastvold said the barriers to adoption of drone-based delivery systems include differences in state laws about when, where, and how drones can be used and who can operate them as well as Federal Aviation Administration (FAA) airspace restrictions and regulations.

For example, the FAA currently requires “line-of-sight” operation for most drone operators, meaning the operator must have visual contact with the drone at all times. The FAA will, however, grant waivers to individual operators for specified flying conditions on a case-by-case basis, if compelling need or extenuating circumstances can be satisfactorily explained.

In addition, federal regulations require commercial drone pilots to be 16 or older, be fluent in English, be in a physical and mental condition that would not interfere with safe operation of a drone, pass an aeronautical knowledge exam at an FAA-approved testing center, and undergo a Transportation Safety Administration background security screening.

Despite these challenges, at least one U.S. medical center, Johns Hopkins University, is testing the use of drones for blood delivery.

In 2015, Johns Hopkins researchers reported that transporting blood samples on hobby-sized drones did not affect the results of common and routine blood tests.

In 2016, the researchers showed that large bags of blood products can maintain temperature and cellular integrity when transported by drones.

In 2017, the researchers demonstrated that a drone could deliver blood samples in temperature-controlled conditions across 161 miles of Arizona desert, in a flight lasting 3 hours.

Kenney said his company is developing a second distribution center in Rwanda that will expand coverage to the entire country and is also working with the FAA, federal regulators, and the state of North Carolina to develop a drone-based blood delivery system in the United States.

Photo by Cristina Granados

BOSTON—Drone-delivered blood products may be coming soon to a hospital near you, experts said at AABB 2018.

Using a system of completely autonomous delivery drones launched from a central location, U.S.-based Zipline International delivers blood products to treat postpartum hemorrhage, trauma, malaria, and other life-threatening conditions to patients in rural Rwanda, according to company spokesman Chris Kenney.

“In less than 2 years in Rwanda, we’ve made almost 10,000 deliveries,” Kenney said. “That’s almost 20,000 units of blood.”

One-third of all deliveries are needed for urgent, life-saving interventions, he added.

The system, which delivers 30% of all blood products used in Rwanda outside the capital Kigali, has resulted in 100% availability of blood products when needed, a 98% reduction in waste (i.e., when unused blood products are discarded because of age), and a 175% increase in the use of platelets and fresh frozen plasma, according to Kenney.

How it works

Kenney described the case of a 24-year-old Rwandan woman who had uncontrolled bleeding from complications following a cesarean section.

The clinicians treating her opted to give her an immediate red blood cell transfusion, but she continued to bleed, and the hospital ran out of red blood cells in about 15 minutes.

They placed an order for more blood products, which can be done by text message or via WhatsApp, a free messaging and voiceover IP calling service.

After the order was placed, Zipline was able to deliver blood products using multiple drone launches over the course of 90 minutes. The deliveries consisted of 7 units of red blood cells, 4 units of plasma, and 2 units of platelets, all of which were transfused into the patient and allowed her condition to stabilize.

Deliveries that would take a minimum of 3 hours by road can be accomplished in about 15 to 25 minutes by air, Kenney said.

The drones—more formally known as “unmanned aerial vehicles”—fly a loop starting at the distribution center, find their target, descend to a height of about 10 meters, and drop the package, which has a parachute attached.

Packages can be delivered within a drop zone the size of two parking spaces, even in gale-force winds, Kenney said.

“The whole process is 100% autonomous,” he noted. “The aircraft knows where it’s going, it knows what conditions [are], it knows what its payload characteristics are and flies to the delivery point and drops its package.”

As drones return to the distribution center, they are snared from the air with a wire that catches a small tail hook on the fuselage.

Airborne deliveries are significantly cheaper than ground-based services for local delivery, according to Paul Eastvold, MD, chief medical officer at Vitalant, a nonprofit network of community blood banks headquartered in Spokane, Wash.

Dr. Eastvold cited statistics suggesting the cost of ground shipping from a local warehouse by carriers such as UPS or FedEx could be $6 or more. However, drone delivery could be as cheap as 5 cents per mile.

Barriers to drone delivery

Setting up an airborne delivery network in the largely unregulated and uncrowded Rwandan airspace was a relatively simple process, compared with the myriad challenges of establishing a similar system for deliveries to urban medical centers in Boston, Chicago, New York, or Los Angeles, according to Dr. Eastvold.

He described the hurdles that will need to be surmounted before blood-delivery drones are as common a sight as traffic helicopters in the United States.

Dr. Eastvold said the barriers to adoption of drone-based delivery systems include differences in state laws about when, where, and how drones can be used and who can operate them as well as Federal Aviation Administration (FAA) airspace restrictions and regulations.

For example, the FAA currently requires “line-of-sight” operation for most drone operators, meaning the operator must have visual contact with the drone at all times. The FAA will, however, grant waivers to individual operators for specified flying conditions on a case-by-case basis, if compelling need or extenuating circumstances can be satisfactorily explained.

In addition, federal regulations require commercial drone pilots to be 16 or older, be fluent in English, be in a physical and mental condition that would not interfere with safe operation of a drone, pass an aeronautical knowledge exam at an FAA-approved testing center, and undergo a Transportation Safety Administration background security screening.

Despite these challenges, at least one U.S. medical center, Johns Hopkins University, is testing the use of drones for blood delivery.

In 2015, Johns Hopkins researchers reported that transporting blood samples on hobby-sized drones did not affect the results of common and routine blood tests.

In 2016, the researchers showed that large bags of blood products can maintain temperature and cellular integrity when transported by drones.

In 2017, the researchers demonstrated that a drone could deliver blood samples in temperature-controlled conditions across 161 miles of Arizona desert, in a flight lasting 3 hours.

Kenney said his company is developing a second distribution center in Rwanda that will expand coverage to the entire country and is also working with the FAA, federal regulators, and the state of North Carolina to develop a drone-based blood delivery system in the United States.

Photo by Cristina Granados

BOSTON—Drone-delivered blood products may be coming soon to a hospital near you, experts said at AABB 2018.

Using a system of completely autonomous delivery drones launched from a central location, U.S.-based Zipline International delivers blood products to treat postpartum hemorrhage, trauma, malaria, and other life-threatening conditions to patients in rural Rwanda, according to company spokesman Chris Kenney.

“In less than 2 years in Rwanda, we’ve made almost 10,000 deliveries,” Kenney said. “That’s almost 20,000 units of blood.”

One-third of all deliveries are needed for urgent, life-saving interventions, he added.

The system, which delivers 30% of all blood products used in Rwanda outside the capital Kigali, has resulted in 100% availability of blood products when needed, a 98% reduction in waste (i.e., when unused blood products are discarded because of age), and a 175% increase in the use of platelets and fresh frozen plasma, according to Kenney.

How it works

Kenney described the case of a 24-year-old Rwandan woman who had uncontrolled bleeding from complications following a cesarean section.

The clinicians treating her opted to give her an immediate red blood cell transfusion, but she continued to bleed, and the hospital ran out of red blood cells in about 15 minutes.

They placed an order for more blood products, which can be done by text message or via WhatsApp, a free messaging and voiceover IP calling service.

After the order was placed, Zipline was able to deliver blood products using multiple drone launches over the course of 90 minutes. The deliveries consisted of 7 units of red blood cells, 4 units of plasma, and 2 units of platelets, all of which were transfused into the patient and allowed her condition to stabilize.

Deliveries that would take a minimum of 3 hours by road can be accomplished in about 15 to 25 minutes by air, Kenney said.

The drones—more formally known as “unmanned aerial vehicles”—fly a loop starting at the distribution center, find their target, descend to a height of about 10 meters, and drop the package, which has a parachute attached.

Packages can be delivered within a drop zone the size of two parking spaces, even in gale-force winds, Kenney said.

“The whole process is 100% autonomous,” he noted. “The aircraft knows where it’s going, it knows what conditions [are], it knows what its payload characteristics are and flies to the delivery point and drops its package.”

As drones return to the distribution center, they are snared from the air with a wire that catches a small tail hook on the fuselage.

Airborne deliveries are significantly cheaper than ground-based services for local delivery, according to Paul Eastvold, MD, chief medical officer at Vitalant, a nonprofit network of community blood banks headquartered in Spokane, Wash.

Dr. Eastvold cited statistics suggesting the cost of ground shipping from a local warehouse by carriers such as UPS or FedEx could be $6 or more. However, drone delivery could be as cheap as 5 cents per mile.

Barriers to drone delivery

Setting up an airborne delivery network in the largely unregulated and uncrowded Rwandan airspace was a relatively simple process, compared with the myriad challenges of establishing a similar system for deliveries to urban medical centers in Boston, Chicago, New York, or Los Angeles, according to Dr. Eastvold.

He described the hurdles that will need to be surmounted before blood-delivery drones are as common a sight as traffic helicopters in the United States.

Dr. Eastvold said the barriers to adoption of drone-based delivery systems include differences in state laws about when, where, and how drones can be used and who can operate them as well as Federal Aviation Administration (FAA) airspace restrictions and regulations.

For example, the FAA currently requires “line-of-sight” operation for most drone operators, meaning the operator must have visual contact with the drone at all times. The FAA will, however, grant waivers to individual operators for specified flying conditions on a case-by-case basis, if compelling need or extenuating circumstances can be satisfactorily explained.

In addition, federal regulations require commercial drone pilots to be 16 or older, be fluent in English, be in a physical and mental condition that would not interfere with safe operation of a drone, pass an aeronautical knowledge exam at an FAA-approved testing center, and undergo a Transportation Safety Administration background security screening.

Despite these challenges, at least one U.S. medical center, Johns Hopkins University, is testing the use of drones for blood delivery.

In 2015, Johns Hopkins researchers reported that transporting blood samples on hobby-sized drones did not affect the results of common and routine blood tests.

In 2016, the researchers showed that large bags of blood products can maintain temperature and cellular integrity when transported by drones.

In 2017, the researchers demonstrated that a drone could deliver blood samples in temperature-controlled conditions across 161 miles of Arizona desert, in a flight lasting 3 hours.

Kenney said his company is developing a second distribution center in Rwanda that will expand coverage to the entire country and is also working with the FAA, federal regulators, and the state of North Carolina to develop a drone-based blood delivery system in the United States.