Congratulations, Mick, starting his MD program at Cooper Medical School
Sunghee Lee, Ph.D. • September 2, 2020
Michael McGlone (’17 BS Physics), our former Project Symphony member, started his MD program in Fall 2020 at Cooper Medical in Camden, NJ. While at Iona, Mick involved in electrophysiology experiment determining membrane capacitance and traveled to Japan for NSF funded research at the University of Tokyo. After Iona, he worked as a research scientist at Regeneron Pharmaceuticals in NY.
We’re pleased to announce our new collaborative publication, “Study of the Interaction Between Graphene Oxide and Cholesterol Using Different Artificial Membrane Models,” conducted in partnership with colleagues in Italy. This work investigates how graphene oxide—an emerging nanomaterial with biomedical promise—interacts with cholesterol within lipid membranes. By employing various artificial membrane systems, we examined how membrane composition and organization influence these interactions, revealing key insights into the physicochemical mechanisms at play. Our results contribute to a deeper understanding of how nanomaterials engage with biological membranes, providing valuable guidance for the safe and effective design of graphene-based biomedical applications. Congratulations to all team members and our Italian collaborators on this exciting achievement! The full article is available here: https://www.sciencedirect.com/science/article/pii/S0021979726002821 .
In this study, we explored how the membrane environment shapes the behavior of serotonin, a key neurotransmitter involved in mood regulation and neural signaling. By systematically varying lipid composition in model membranes, we uncovered how differences in lipid charge, fluidity, and packing influence serotonin’s nonspecific interactions with bilayers. Our findings shed new light on the physical chemistry of neurotransmitter–membrane interactions, with potential implications for understanding serotonin’s diverse physiological functions and its role in receptor signaling. Congratulations to all co-authors for their outstanding work and collaboration! The article can be accessed here: https://pubs.acs.org/doi/full/10.1021/acsptsci.5c00767
Our research team has uncovered new details about how small oil-like molecules influence the thickness and flexibility of cell membranes. These membranes, built from layers of lipids, contain tiny pockets of free space that help control how soft, dense, or permeable the membrane is. Our research team found that some smaller molecules can fit into these layers, making the membrane thicker, while larger or crystallizing ones get pushed out, leading to thinning. These changes help explain how different molecules inside a membrane affect its overall structure and function. This study not only expands our understanding of how biological membranes work but also points to new possibilities for creating custom-designed synthetic membranes for research and technology. Read more details here: https://pubs.acs.org/doi/10.1021/acs.jpcb.5c06296 Congratulations to the Project Symphpony team for their exciting findings and continued dedication to advancing membrane science!
