Human Fat: A Trojan Horse To Fight Brain Cancer? Johns Hopkins University Reveals
5/1/2014 6:39:09 AM
Human fat: A Trojan Horse To Fight Brain Cancer?
Johns Hopkins researchers use stem cells derived from human body fat to deliver treatment for deadly glioblastoma in mice
MARYLAND -- Johns Hopkins researchers say they have successfully used stem cells derived from human body fat to deliver biological treatments directly to the brains of mice with the most common and aggressive form of brain tumor, significantly extending their lives.
The experiments advance the possibility, the researchers say, that the technique could work in people after surgical removal of brain cancers called glioblastomas to find and destroy any remaining cancer cells in difficult-to-reach areas of the brain. Glioblastoma cells are particularly nimble; they are able to migrate across the entire brain, hide out and establish new tumors. Cure rates for the tumor are notoriously low as a result.
In the mouse experiments, the Johns Hopkins investigators used mesenchymal stem cells (MSCs) — which have an unexplained ability to seek out cancer and other damaged cells — that they harvested from human fat tissue. They modified the MSCs to secrete bone morphogenetic protein 4 (BMP4), a small protein involved in regulating embryonic development and known to have some tumor suppression function. The researchers, who had already given a group of mice glioblastoma cells several weeks earlier, injected stem cells armed with BMP4 into their brains.
In a report published in the May 1 issue of Clinical Cancer Research, the investigators say the mice treated this way had less tumor growth and spread, and their cancers were overall less aggressive and had fewer migratory cancer cells compared to mice that didn't get the treatment. Meanwhile, the mice that received stem cells with BMP4 survived significantly longer, living an average of 76 days, as compared to 52 days in the untreated mice.
"These modified mesenchymal stem cells are like a Trojan horse, in that they successfully make it to the tumor without being detected and then release their therapeutic contents to attack the cancer cells," says study leader Alfredo Quinones-Hinojosa, M.D., a professor of neurosurgery, oncology and neuroscience at the Johns Hopkins University School of Medicine.
Standard treatments for glioblastoma include chemotherapy, radiation and surgery, but even a combination of all three rarely leads to more than 18 months of survival after diagnosis. Finding a way to get biologic therapy to mop up what other treatments can't get is a long-sought goal, says Quinones-Hinojosa, who cautions that years of additional studies are needed before human trials of fat-derived MSC therapies could begin.
Quinones-Hinojosa, who treats brain cancer patients at Johns Hopkins Kimmel Cancer Center, says his team was heartened by the fact that the stem cells let loose into the brain in his experiments did not transform themselves into new tumors.
The latest findings build on research published in March 2013 by Quinones-Hinojosa and his team in the journal PLOS ONE, which showed that harvesting MSCs from fat was much less invasive and less expensive than getting them from bone marrow, a more commonly studied method.
Ideally, he says, if MSCs work, a patient with a glioblastoma would have some adipose tissue (fat) removed from any number of locations in the body a short time before surgery. The MSCs in the fat would be drawn out and manipulated in the lab to secrete BMP4. Then, after surgeons removed the brain tumor, they could deposit these treatment-armed cells into the brain in the hopes that they would seek out and destroy the cancer cells.
This research was supported by the National Institutes of Health's National Institute of Neurological Disorders and Stroke (RO1NS070024) and the Maryland Stem Cell Research Fund.
Other Johns Hopkins researchers involved in the study include Qian Li, Ph.D.; Olindi Wijesekera; Joanna Y. Wang; Mingxin Zhu, M.D.; Colette ap Rhys, Ph.D.; Kaisorn L. Chaichana, M.D.; David A. Chesler, M.D., Ph.D.; Hao Zhang, M.D.; Christopher L. Smith, Ph.D.; and Hugo Guerrero-Cazares, M.D., Ph.D. Researchers from Yale University also contributed to this work.
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Johns Hopkins Medicine (JHM), headquartered in Baltimore, Maryland, is a $6.7 billion integrated global health enterprise and one of the leading health care systems in the United States. JHM unites physicians and scientists of the Johns Hopkins University School of Medicine with the organizations, health professionals and facilities of The Johns Hopkins Hospital and Health System. JHM's vision, "Together, we will deliver the promise of medicine," is supported by its mission to improve the health of the community and the world by setting the standard of excellence in medical education, research and clinical care. Diverse and inclusive, JHM educates medical students, scientists, health care professionals and the public; conducts biomedical research; and provides patient-centered medicine to prevent, diagnose and treat human illness. JHM operates six academic and community hospitals, four suburban health care and surgery centers, and more than 30 primary health care outpatient sites. The Johns Hopkins Hospital, opened in 1889, was ranked number one in the nation for 21 years in a row by U.S. News & World Report.
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