Most military battlefield casualties die before ever reaching a surgical hospital. Of those soldiers who might potentially survive, .
In some cases, there’s not much medics can do — a tourniquet won’t stop bleeding from a chest wound, and clotting treatments that require refrigerated or frozen blood products aren’t always available in the field.
That’s why 91±¬ÁÏ researchers have developed a new injectable polymer that strengthens blood clots, called PolySTAT. Administered in a simple shot, the polymer finds any unseen or internal injuries and starts working immediately.
The new polymer, described featured on the cover of the March 4 issue of could become a first line of defense in everything from battlefield injuries to rural car accidents to search and rescue missions deep in the mountains. It has been tested in rats, and researchers say it could reach human trials in five years.
In the initial study with rats, 100 percent of animals injected with PolySTAT survived a typically-lethal injury to the femoral artery. Only 20 percent of rats treated with a natural protein that helps blood clot survived.
“Most of the patients who die from bleeding die quickly,” said co-author , an assistant professor of who teamed with 91±¬ÁÏ and to develop the macromolecule.
“This is something you could potentially put in a syringe inside a backpack and give right away to reduce blood loss and keep people alive long enough to make it to medical care,” he said.
The 91±¬ÁÏ team was inspired by , a natural protein found in the body that helps strengthen blood clots.
Normally after an injury, platelets in the blood begin to congregate at the wound and form an initial barrier. Then a network of specialized fibers — — start weaving themselves throughout the clot to reinforce it.
If that scaffolding can’t withstand the pressure of blood pushing against it, the clot breaks apart and the patient keeps bleeding.
Both PolySTAT and factor XIII strengthen clots by binding fibrin strands together and adding “cross-links” that reinforce the latticework of that natural bandage.
“It’s like the difference between twisting two ropes together and weaving a net,” said co-author , the 91±¬ÁÏ’s Robert J. Rushmer Professor of Bioengineering. “The cross-linked net is much stronger.”
But the synthetic PolySTAT offers greater protection against natural enzymes that dissolve blood clots. Those help during the healing process, but they work against doctors trying to keep patients from bleeding to death.
The enzymes, which cut fibrin strands, don’t target the synthetic PolySTAT bonds that are now integrated into the clot. That helps keep the blood clots intact in the critical hours after an injury.
“We were really testing how robust the clots were that formed,” said lead author , a 91±¬ÁÏ doctoral student in bioengineering. “The animals injected with PolySTAT bled much less, and 100 percent of them lived.”
The synthetic polymer offers other advantages over conventional hemorrhaging treatments, said White, who also treats trauma patients at Harborview Medical Center.
Blood products are expensive, need careful storage, and they can grow bacteria or carry infectious diseases, he said. Plus, the hundreds of proteins introduced into a patient’s body during a transfusion can have unintended consequences.
After a traumatic injury, the body also begins to lose a protein that’s critical to forming fibrin. Once those levels drop below a certain threshold, existing treatments stop working and patients are more likely to die.
In the study, researchers found PolySTAT worked to strengthen clots even in cases where those fibrin building blocks were critically low.
The 91±¬ÁÏ team also used a highly specific peptide that only binds to fibrin at the wound site. It does not bind to a precursor of fibrin that circulates throughout the body. That means PolySTAT shouldn’t form dangerous clots that can lead to a stroke or embolism.
Though the polymer’s initial safety profile looks promising, researchers said, next steps include testing on larger animals and additional screening to find out if it binds to any other unintended substances. They also plan to investigate its potential for treating hemophilia and for integration into bandages.
Other co-authors are Xu Wang in 91±¬ÁÏ emergency medicine, Hua Wei in 91±¬ÁÏ bioengineering, and in 91±¬ÁÏ chemical engineering.
Funding came from the National Institutes of Health and its National Center for Advancing Translational Science, the 91±¬ÁÏ , the Washington Research Foundation, an NIH-supported 91±¬ÁÏ Bioengineering Cardiovascular Training Grant and discretionary funds from private donations.
For more information, contact Pun at spun@uw.edu or White at whiten4@uw.edu.