“Our study shows for the first time how CAR T cell technology could be used to treat the underlying cause of the most common form of heart disease, which is the leading cause of death worldwide,” said senior author Avery Posey, PhD, an assistant professor of Pharmacology. “This preclinical finding represents an important step forward for continuing to expand the impact of CAR T cell therapy to common diseases beyond cancer.”
Building on anti-inflammatory research for heart disease Atherosclerosis underlies ischemic heart disease and stroke, which together kill tens of millions globally each year. Available treatments include medications to reduce low-density lipoprotein (LDL) cholesterol, which causes the build-up of plaque, and lifestyle modifications to reduce the risk of disease. Although atherosclerosis is largely driven by inflammation, there are no approved treatments that specifically target atherosclerotic inflammation, and previous clinical trials of anti-inflammatory drugs have not panned out.
“The idea that therapy targeted to inflammation within the arterial wall can reduce the risk of atherosclerotic cardiovascular disease is compelling” said co-author Daniel J. Rader, MD, an expert on lipids and atherosclerosis and chair of the Department of Genetics. “The use of a CAR T approach to target the proinflammatory molecule oxLDL could provide an important complementary treatment approach to reducing the high residual risk of atherosclerotic cardiovascular disease in patients on effective cholesterol-lowering therapy.”
Researchers do not anticipate that CAR T cell therapy, should the approach prove successful in clinical trials, would replace existing treatments when they’re working well for patients. Rather, it could become another tool for patients who need additional or alternative treatment options.
A CAR T to suppress, rather than ignite, the immune system CAR T cell therapy has revolutionized treatment for blood cancers. It works by engineering a patient’s own T cells in the lab and training them to recognize a marker found on cancer cells, creating an immune response that destroys the cancer.
Scientists have been exploring the potential of this powerful technology to treat other diseases, including autoimmune diseases and cardiac fibrosis, another form of heart disease. In this study, the researchers used a different type of T cell called regulatory T cells (Tregs), the subject of the 2025 Nobel Prize in Physiology or Medicine. Tregs dampen—rather than incite—the activity of other immune cells nearby.
The team engineered a CAR Treg that targets oxidized LDL (OxLDL), the main inflammation-stoking form of LDL cholesterol that drives plaque buildup in atherosclerosis.
“OxLDL is a pro-inflammatory molecule, and that inflammation is what starts atherosclerosis,” explained lead author Robert Schwab, MD, an instructor of Hematology-Oncology. “The idea was, if we can get the immune system to see OxLDL and provoke an anti-inflammatory response, it would reduce inflammation and essentially stop the pathogenesis in its tracks.”
70 percent less arterial plaque Initial lab-dish tests with human cells confirmed that the anti-OxLDL CAR Tregs suppress inflammation in response to OxLDL, greatly reducing the buildup of the cells that are a central feature of atherosclerotic plaques. The team then engineered a mouse version of the anti-OxLDL CAR-Treg and tested it in mice that were genetically predisposed to high cholesterol and atherosclerosis.
After about twelve weeks of treatment, the treated mice’s hearts and aortas showed a roughly 70 percent lower atherosclerotic plaque burden compared to control mice—indicating a clear preventive effect of the CAR-Tregs. Despite this effect, there was no disruption of general immune function in the treated mice.
The researchers and Penn have founded a spinout company, Cartio Therapeutics, to continue developing the OxLDL CAR Tregs to test the therapy in human clinical trials.
The cardio-oncology connection Both Posey and Schwab trained under CAR T cell therapy pioneer Carl June, MD, the Richard W. Vague Professor in Immunotherapy, who led the development of the first CAR T cell therapy, approved by the FDA in 2017. Posey has continued his independent CAR T research career in Penn’s Center for Cellular Immunotherapies, which is directed by June, and Schwab continued his medical training as an oncologist, completing a fellowship in the division of Hematology-Oncology at Penn earlier this year.
“Cancer, inflammation, and heart disease go hand-in-hand,” Schwab said. “It’s a real shame to see a patient cured of cancer die from a heart attack a year or two later.”
For many patients who survive cancer, heart disease becomes their biggest health risk, in part due to known side effects of cancer treatments and in part due to the cancer itself creating an inflammatory environment where diseases like atherosclerosis can thrive.
“We’re inspired by the potential that this technology developed for cancer could have to help so many people, cancer survivors included,” Posey said.
The study was funded in part by the Hematology Research Training Program (T32HL007439), the American Society of Hematology Research Training Award for Fellows, and the Department of Veteran’s Affairs (IK2BX004183, I01BX006247).
Editor’s note: Posey and Schwab are inventors on a patent filed by the Trustees of the University of Pennsylvania, which covers technology described in this manuscript. They are also founders of, and equity holders in, Cartio Therapeutics, which has been formed to further develop and commercialize the technology. Penn holds equity in Cartio Therapeutics, and Penn may receive future research funding and financial consideration based on development and commercialization of certain products by Cartio Therapeutics.
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