Repelling disorder: What makes cholesterol-containing surfaces so repulsive?

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The Collembola Tetrodontophora bielanensis in its natural habitat | Quelle: Stephan Floss | Copyright: Leibniz-Institut für Polymerforschung Dresden/NATURE | Download

Living organisms use powerful physical principles to control interactions at their surfaces. Researchers at the Leibniz Institute of Polymer Research Dresden, Leipzig University and TU Dresden have now discovered why cholesterol-containing surfaces can exhibit greatly reduced attachment of proteins and bacteria.

The interdisciplinary team led by Carsten Werner had previously identified cholesterol as a component of the skin of widespread invertebrates (collembolae), which breathe through their skin and therefore need to protect it from contamination. In their paper published in Nature on June 22, 2023, the scientists have now elucidated a repulsive mechanism of cholesterol-containing surfaces. Using experiments, simulations and thermodynamic analyses, they were able to show how the spontaneous change in the orientation of interfacial cholesterol molecules creates an "entropic barrier" that makes cholesterol-containing surfaces repellent.

The development of synthetic materials using the discovered principle is promising, as it is important for many products and technologies to effectively minimize the attachment of biomolecules and bacteria. However, such "translation" of the effect to scalable, robust surface functionalization requires further research.

At the Leibniz Institute of Polymer Research Dresden (IPF), basic principles for new materials and their application in future technologies are being developed, with biology-inspired material concepts becoming increasingly important. The Chair of Biophysical Chemistry at Leipzig University works closely with the IPF on biomimetic materials. At the Cluster of Excellence Physics of Life of the TU Dresden, basic principles of the functionality of living matter are being explored.

Wissenschaftlicher Ansprechpartner:
Prof. Dr. Carsten Werner, werner@ipfdd.de

Originalpublikation:
Jens Friedrichs, Ralf Helbig, Julia Hilsenbeck, Prithvi Raj Pandey, Jens-Uwe Sommer, Lars David Renner, Tilo Pompe und Carsten Werner
Entropic repulsion of cholesterol-containing layers counteracts bioadhesion.
Nature https://doi.org/10.1038/s41586-023-06033-4 (2023)