‘First-in-class’ tool for potential treatment of brain disorders

Hong Chen, medical school faculty to collaborate on NIH-funded work Read More

From the McKelvey School of Engineering

New methods to treat human brain disorders is one of the top priorities of the National Institutes of Health’s ambitious BRAIN Initiative. To find noninvasive tools that are equally or more effective is a kind of Holy Grail for neuroscience, and a biomedical engineer at Washington University in St. Louis has it in her sights.

Hong Chen, PhD, associate professor of biomedical engineering in the McKelvey School of Engineering and of radiation oncology in the School of Medicine, plans to develop and validate an incisionless treatment delivery method —named iSonogenetics — in animals with a three-year, $2.1 million grant from the National Institutes of Health’s National Institute of Mental Health. The uniquely structured UG3/UH3 grant provides initial support for three years to develop the tool in the UG3 phase with two additional years of funding in the UH3 phase to validate its performance.

Chen will collaborate with Ilya Monosov, PhD, associate professor of neuroscience and co-principal investigator, and three other faculty members from the School of Medicine: Joel Perlmutter, MD, professor of neurology; Buck Rogers, PhD, professor of radiation oncology; and Larry Snyder, MD, PhD, professor of neuroscience.

Chen’s iSonogenetics method uses focused ultrasound to deliver a viral construct containing ultrasound-sensitive ion channels to genetically selected neurons in the brain through the nose. Then, they use low-intensity focused ultrasound to deliver a small burst of warmth, which opens the ion channels and activates the neurons.

“This research is significant because it directly addresses the central goal of this aspect of the BRAIN Initiative by providing the neuroscience community with a first-of-its-kind tool that has the potential to change the way we approach these process and to uncover new ways to understand and treat these neurological disorders,” Chen said.

The work’s foundation is in optogenetics, the combination of the targeted expression of light-sensitive ion channels and the precise delivery of light to stimulate neurons deep in the brain. While optogenetics has increased the discovery of new neural circuits, it is limited in penetration depth due to light scattering and requires surgical implantation of optical fibers. The iSonogenetics method requires no surgery.

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Posted on September 7, 2021
Posted in: HPAN, Neurogenetics & Transcriptomics, NeuroRestorative Therapy, Neurovascular Injury & Repair, News Authors: ,