Michael Levin is an American developmental and synthetic biologist at Tufts University. His research interests include: bioelectrical signals by which cells communicate to serve the dynamic anatomical needs of the organism during development, regeneration, and cancer suppression; basal cognition and intelligence in diverse unconventional substrates; and top-down control of form and function across scales in biology.

Join us as we discuss.
- Bioelectricity.
- Regeneration.
- The future in medicine.
- The act of free will and more.

EPISODE LINKS:
Michael’s Twitter: https://twitter.com/drmichaellevin.
Michael’s Website: https://drmichaellevin.org.
Michael’s Publications: https://facultyprofiles.tufts.edu/michael-levin-1/publications.

PODCAST INFO:
Podcast website: https://www.rekindi.com/podcasts.
Apple Podcasts: https://podcasts.apple.com/gb/podcast/rekindi-podcast/id1550253946
Spotify: https://open.spotify.com/show/1Gn2DZjxvLnZ88bh2fgLWn?si=c714c46c9d09449a

Our ability to learn, move, and sense our world comes from the neurons in our brain. This information moves through our brain between neurons that are linked together by tens of trillions of tiny structures called synapses. Although tiny, synapses are not simple and must be precisely organized to function properly. Indeed, diseases like autism and Alzheimer’s are increasingly linked to defects in the organization and number of these tiny structures. Now researchers at Thomas Jefferson University have found a new way in which synapses organization is controlled, which could eventually lead to better treatments for neurological diseases.

Researchers who study how synapses grow and are lost have long focused on a molecule called PSD-95, which helps create and maintain the scaffolding around which a synapse is built. A new paper, publishing in Nature Neuroscience October 19th, reveals that a second protein interacts with PSD-95 and enables adaptive changes, such as changes in sensation, to be translated into changes in the synaptic scaffold, changing the amount of PSD-95 at the synapse.

“We can’t see or learn or talk without synapses working properly,” says senior author Matthew Dalva, Ph.D., Associate Professor of Neuroscience at the Sidney Kimmel Medical College at Thomas Jefferson University and the Farber Institute of Neuroscience at Jefferson and leader of the Theme Team for Synapse Biology. “We need a better understanding of how the brain works normally in order to develop a better sense of where to intervene to stop or cure diseases of the brain. It’s important to understand how these molecules interact.”

It’s a hidden, lifelong process that’s tied to cancer, heart disease and dementia, but there’s plenty you can do to fix the damage In the past few years, a new buzzword has entered conversations about illness and disease. Doctors are increasingly talking about “inflammation” – a term which describes the automatic response – or flaring up – of the body when it tries to fight infections, toxins and trauma.