There’s a famous line attributed to Ernest Rutherford, the father of nuclear physics: “All science is either physics or stamp collecting.” It’s still provocative. But it’s unfair to biology. Long before today’s omics era, biologists were uncovering causality everywhere from evolution and natural selection to Mendelian inheritance. They have never merely catalogued life. They have explained it. But modern biology has also generated extraordinary inventories of genes, proteins, and pathways, and those inventories now invite a deeper systems-level question: how do the parts behave together in living cells? Could new precise physical measurements aid biology and medicine?
Todays’ guest, Erdinc Sezgin, is an Associate Professor at Karolinska Institute and recipient of the Biophysical Society Early Independent Career Award. His lab is bringing physics to biology. For example, Sezgin studies the cell membrane not as a passive wrapper, but as an active, dynamic system whose physical properties of fluidity, viscosity, charge, and organization help determine how cells signal and survive. His hope is to improve ways to measure these biophysical properties.
Sezgin discusses his recent collaboration with Pixelgen Technologies, where Molecular Pixelation was used to study how changing membrane charge reshapes the cell surface. By knocking out a lipid-regulating complex, Sezgin and his colleagues showed that living cells can adopt surface features that alter immune recognition and may help explain how cancer cells evade destruction. It’s a reminder that major biological insights often arrive hand-in-hand with new tools that make previously hidden phenomena measurable.
The conversation closes on a broader point about scientific boundaries. Biology is not separate from physics or chemistry, but an expression of them in living systems.
“Cells don’t have physics, chemistry, biology. . . It is life,” he says.
