For patients who receive a heart transplant in the near future, the old adage, “Good things come in small packages,” may become words to live by. In a recent study, researchers at Johns Hopkins Medicine and the National Cancer Institute (NCI) demonstrated in mice that they can easily deliver a promising anti-rejection drug directly to the area surrounding a grafted heart by packaging it within a tiny three-dimensional, protein gel cocoon known as a hydrogel. Best of all, the researchers say that the release of the drug is spread out over time, making it highly regulatable and eliminating the need for daily medication to keep rejection in check.
The findings are presented in the Aug. 18, 2020, issue of the journal Small.
Preventing the rejection of a transplanted heart has often been a Catch-22 situation. If you give an organ recipient large amounts of immune suppression drugs, there may be serious side effects, including kidney damage, hypertension, blood sugar imbalances and even lymphomas. Lowering the dose may be safer for general health but increases the risk that rejection will not be properly controlled and the grafted heart will be lost.
“What was needed was a drug delivery method that would get the anti-rejection medication only where needed; protect the drug from premature degradation; and maintain a high concentration for the period of time needed to retrain the immune system,” says study co-author Giorgio Raimondi, M.Sc., Ph.D., assistant professor of plastic and reconstructive surgery at the Johns Hopkins University School of Medicine.
“Two earlier studies used the hydrogel method to successfully deliver conventional immunosuppressive drugs to other sites, and this prompted us to try it out for transplanted hearts,” Raimondi explains. “Additionally, work by a team at the NCI Frederick National Laboratory for Cancer Research under Joel Schneider [Ph.D., a study co-author] showed that hydrogel-drug packages can be administered by syringe.”
The drug these researchers wanted to supply to transplanted hearts is tofacitinib, an inhibitor of the process by which cells alert their receptiveness to binding with inflammation-inducing proteins called cytokines. In normal immune responses to foreign invaders within the body, cytokines play a critical role in alerting specialized white blood cells — T lymphocytes — to attack and remove the threatening bacteria or viruses. However, cytokines in the presence of a transplanted heart can direct the immune system to destroy the graft.
To see if a hydrogel courier could be used to deliver tofacitinib, the researchers first grafted mouse hearts into the necks of recipient mice to create an animal model of a human transplant. Next, they mixed tofacitinib with a solution of small protein fragments that assembled themselves around the drug during a 24-hour incubation process that Raimondi likens to the “make your own crystal” kits popular with children.
“We found that making tofacitinib into a crystal best controlled how the drug spreads out from the hydrogel,” says study lead author Poulami Majumder, Ph.D., former NCI at Frederick postdoctoral fellow. “The resulting ‘microcrystalline tofacitinib hydrogel,’ or MTH, was extremely stable, preserved the encapsulated drug in pristine condition and could be injected at the transplantation site simply by using a syringe.”
The researchers tested the MTH delivery system in their mouse model in tandem with a second immunosuppressant drug, CTLA4-Ig, which was injected separately. This was the first time that this specific combination therapy had been tried.