A treatment called extracorporeal shockwave therapy (ESWT) is used in patients both human and equine to speed healing of injured tendons and ligaments. Using high-pressure sonic waves, ESWT is thought to increase blood flow to the treated area, and has been shown to reduce pain over the short term.
In racehorses, however, masking pain can come with a cost: overworked minor injuries could lead to major ones—or even pose a life-threatening risk to both horse and rider.
For that reason, horseracing authorities have banned the use of ESWT for horses within 10 days of a race or sporting event. But the question of how to enforce the ban on this “invisible” therapy remained open. Now a team led by Mary Robinson, director of the School of Veterinary Medicine’s Equine Pharmacology Research Laboratory, and lab member Jinwen Chen has found that the practice does in fact leave a trail. In a paper in Equine Veterinary Journal, they report finding potential biomarkers of ESWT that, with further testing, could one day be used to enforce the ESWT ban.
“Because it's not a drug—it's applied to the surface of the skin—it's just not an easy thing to detect,” says Robinson. “After a lot of trial and error, our study was able to measure changes in levels of five inflammatory factors, some of which we could detect up to three weeks after the shockwave therapy.”
The attempt to find these biomarkers dates back roughly a decade.
“It was Dr. [Lawrence] Soma, my predecessor, who said [the lab] was going to have to look at blood-based or urine-based biomarkers to try to detect shockwave therapy,” Robinson notes.
To find the fingerprints that ESWT might leave behind, the researchers tested the therapy on 11 horses kept as a study herd at Penn Vet’s New Bolton Center. The researchers collected blood samples from the group of horses, composed of Thoroughbreds and Standardbreds, at several timepoints both before and after they each received a single dose of ESWT to a leg.
Over the years, the lab investigated a number of potential biomarkers, molecules that would indicate a horse received ESWT. They zeroed in on 10 pro-inflammatory and anti-inflammatory signaling molecules, called cytokines, which they can measure from the blood using a sensitive test called ELISA.
“We looked a week before giving the shockwave therapy to see if there were any changes in the baseline period, due to changes in time of day or anything else, and didn’t see anything we could define as significant,” Robinson says. “And in the post-shockwave period we went out to three weeks.”
They could not detect changes in five of the cytokines they examined following ESWT. But the other five—TNF-a, IL1b, IL-1RA, IL-6, and sTLR2—did respond. Of those, TNF-a levels were significantly increased through the whole of the post-therapy study period, three weeks.
More study is necessary, Robinson emphasizes, before these biomarkers could be used to assess inappropriate use of ESWT in racehorses. For one, the researchers would like to see if measuring these same molecules in horses that are actively training and racing, or that have an acute injury, might change their results.
For that, she and her colleagues are actively pursuing follow-up studies to look at these biomarkers and other indicators, using a biobank of samples from client-owned animals, including injured and active racehorses, treated at New Bolton Center.
The end goal is to keep the sport safe.
“Shockwave therapy is great as long as people rest the horse after using it,” she says. “We are concerned that it’s being abused in the racehorse industry and that it could potentially result in breakdowns. That’s exactly what we’re trying to avoid.”
Jinwen Chen is a research specialist in the Equine Pharmacology Laboratory at the University of Pennsylvania School of Veterinary Medicine.
Additional coauthors on the study were Penn Vet’s Darko Stefanovski, Joanne Haughan, Zibin Jiang, Raymond Boston, and Lawrence Soma.
The study was supported by the Pennsylvania State Racing Commissions and the Pennsylvania Harness Horsemen Association at Pocono and Chester Downs, Meadows Standardbred Owners Association, Pennsylvania Horsemen’s Benevolent and Protective Association at Penn National and Presque Isle Downs, and The Racing Medication and Testing Consortium.
Future studies to expand on this body of research are largely supported by the Pennsylvania Horse Breeders Association (PHBA), whose generous support established New Bolton Center's state-of-the-art Equine BioBank.
About Penn Vet
Ranked among the top ten veterinary schools worldwide, the University of Pennsylvania School of Veterinary Medicine (Penn Vet) is a global leader in veterinary education, research, and clinical care. Founded in 1884, Penn Vet is the first veterinary school developed in association with a medical school. The school is a proud member of the One Health initiative, linking human, animal, and environmental health.
Penn Vet serves a diverse population of animals at its two campuses, which include extensive diagnostic and research laboratories. Ryan Hospital in Philadelphia provides care for dogs, cats, and other domestic/companion animals, handling nearly 35,300 patient visits a year. New Bolton Center, Penn Vet’s large-animal hospital on nearly 700 acres in rural Kennett Square, PA, cares for horses and livestock/farm animals. The hospital handles nearly 5,300 patient visits a year, while the Field Service treats more than 38,000 patients at local farms. In addition, New Bolton Center’s campus includes a swine center, working dairy, and poultry unit that provide valuable research for the agriculture industry.