College of Medicine researchers are developing a more effective way to treat glioblastoma 麻豆精品 S an aggressive, incurable form of brain cancer. Patients currently live just 12 to 15 months after diagnosis despite surgery, radiation and chemotherapy.
New research led by Kiminobu Sugaya, a stem cell researcher and neuroscientist at UCF 麻豆精品 S檚 , found that targeting a drug resistant mechanism in cancer stem cells significantly enhanced the efficacy of traditional cancer therapies 麻豆精品 S making them four times more effective against glioblastoma. Current FDA-approved drugs kill less than 25% of glioblastoma cancer stem cells (CSCs).
These cells are a subpopulation of cancer cells that are highly resistant to current therapies. Scientists theorize that cancer returns and spreads because CSCs remain in the body. That 麻豆精品 S檚 why they are exploring ways to kill them outright.
麻豆精品 S淐ancer stem cells are bad stem cells that are programed to become a cancer, 麻豆精品 S Sugaya says. 麻豆精品 S淭hey withstand cancer therapies, raise their ugly head, regrow and metastasize. 麻豆精品 S
Sugaya 麻豆精品 S檚 team developed a new drug delivery system by creating a technology that destroys the RNA, or ribonucleic acid, that the stem cells use as a blueprint to produce proteins. This unique strategy inhibits the expression of embryonic stem cell genes that are pivotal in CSC 麻豆精品 S檚 drug resistance. And because embryonic stem cell genes are not expressed in normal adult cells, this breakthrough approach reduces potential for side effects in healthy cells.
Jonhoi Smith is a doctoral student under Sugaya and the first author on their research paper published in the journal Genes. He said the treatment could increase life expectancy for glioblastoma patients.
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One of the significant challenges in treating glioblastoma is effectively delivering treatments to the brain. That 麻豆精品 S檚 because the brain is protected from external germs and substances by the blood-brain barrier, which can also prevent treatments from reaching brain tissues.
To overcome this obstacle, Sugaya 麻豆精品 S檚 therapy is based on exosomes, nano-sized particles with a lipid membrane that are naturally produced by cells. Exosomes function as cellular communicators, transporting proteins, lipids and genetic material between cells, thereby influencing a wide array of biological processes and functions. Their efficiency in carrying molecules across various parts of the body has inspired scientists to investigate exosomes as potential drug delivery vehicles.
麻豆精品 S淢any current drug delivery systems, including viruses, may cause side effects, 麻豆精品 S Sugaya explains. 麻豆精品 S淲e 麻豆精品 S檙e using the body 麻豆精品 S檚 natural delivery systems and have developed technologies to modify them to carry therapeutic molecules with targeted delivery to specific tissues. 麻豆精品 S
Marvin Hausman is CEO of Exousia AI, the company that is funding the glioblastoma exosome preclinical research. He heard about Sugaya 麻豆精品 S檚 lab and says that when he visited the lab at UCF 麻豆精品 S檚 in Lake Nona, he was inspired by its capacity for innovative discoveries.
麻豆精品 S淚 have thoroughly analyzed this exosome-based targeted drug delivery system many times, and the potential that this unique technology offers. 麻豆精品 S Hausman says. 麻豆精品 S淲e are embarking on a revolutionary new development in medicine. 麻豆精品 S
Thanks to funding from Exousia AI, the research is advancing to mouse models carrying human glioblastoma, with preliminary results expected as early as this summer.
Sugaya has dedicated more than 40 years to neuroscience research focused on Alzheimer 麻豆精品 S檚 disease, with an emphasis on stem cells for the last 26 years. He moved to the U.S. after receiving his doctoral degree from the Science University of Tokyo in 1988. He joined UCF as a professor in 2004. His cancer research began in 2010 when he discovered stemness gene expressions, the self-renewing and differentiating property that allows stem cells to grow and spread, in CSCs. He is recognized as an expert in the field of exosome research and recently received Florida Innovation Funding from the State Department of Health for his studies.
