The next step in organ transplants: New startup takes aim at reperfusion injury
While advancing technology and techniques has improved transplant outcomes dramatically, obstacles remain. One of the worst is the ischemia, or lack of blood supply, that the transplanted organ experiences as it goes from donor to recipient. Without a constant supply of blood, the cells of the organ are cut off from fresh oxygen and nutrients that they need to survive. However, sudden reintroduction of blood to the transplanted organ, known as reperfusion, floods cells with oxygen, setting off a chain reaction that leads to the production of free radicals that can trigger inflammation and cause organ damage. Ischemia-reperfusion injury also promotes organ rejection after transplant.
The startup, Lydex Pharmaceuticals, has received almost $300,000 in small business technology transfer grant funding from the National Institutes of Health to develop a novel approach to preventing reperfusion-related organ damage after liver transplant. MUSC researchers C. James Chou, Ph.D., a medicinal chemist; Sherine Chan, Ph.D., a mitochondrial biologist; and College of Charleston chemist Richard Himes, Ph.D., founded Lydex, which will partner with Zhi Zhong, M.D., Ph.D., a professor in the MUSC College of Pharmacy, on the project.
Lydex Pharmaceuticals is developing compounds known as histone deacetylase (HDAC) inhibitors to help prevent ischemia-reperfusion injury. Normally investigated for their potency as anti-cancer drugs, these inhibitors affect the level of gene expression within a cell. Lydex and MUSC researchers have shown that targeting specific HDAC enzymes within the liver markedly reduces both inflammation and tissue damage after reperfusion.
Normally, HDAC inhibitors are potent but have potential toxic effects as they hit unintended enzymes within the cell. The lead compound in development by Lydex promises high potency while also doing a better job of targeting only the enzymes involved in ischemia-reperfusion injury, which greatly minimizes the risk of toxic effects.
"What we see is that there are specific HDACs that promote oxidative stress and inflammation," said Chan. "Our drug is a fast way of turning off these damaging processes before they lead to injury."
This specificity makes the compounds an attractive and novel approach for helping prevent ischemia- reperfusion injury, and this breakthrough couldn't have come at a better time.
A new epidemic of fatty liver disease looms on the horizon, according to Zhong. Fatty liver-induced liver fibrosis is becoming one of the most common indications for liver transplant.
"Up to 30% of the general population currently has fatty liver disease, which is expected to further increase," said Zhong. "Because severe fatty livers are especially vulnerable to the damage caused by ischemia reperfusion, they are not currently used for liver transplant, exacerbating the shortage of donor organs. New drugs that minimize ischemia-reperfusion injury may increase the availability of transplantable livers and improve outcomes for these patients after transplant or major liver surgery."
Even with an urgent need for a new treatment, more research is needed before HDAC inhibitors, currently in use as anti-cancer drugs, can be employed to help to prevent reperfusion injury after transplant and other major liver surgery. The team of Lydex and MUSC researchers is making strides toward this goal. Having verified the efficacy of the lead compound in biochemical assays, the team will next address the compounds' therapeutic potential in mouse models of ischemia-reperfusion injury. In the long term, the team hopes to explore further whether they can use HDAC inhibitors to treat other diseases.
"This new therapeutic intervention, with its novel mechanism of action, could potentially broaden the therapeutic areas of HDAC inhibitors to include immune and inflammatory diseases," said Chou.
Provided by Medical University of South Carolina