AI Article Synopsis
- Biological cells are surrounded by a lipid bilayer (plasma membrane) that can stretch significantly, but isolated lipids often rupture under small strains, limiting synthetic cell construction.
- Research shows that by keeping the plasma membrane structure intact during cell isolation, vesicles can mimic cell-like elasticity and include nanotubes that serve as lipid reservoirs.
- This study reveals a "superelastic" response in these membranes, paving the way for creating synthetic biomaterials that are softer and more deformable than traditional lipid vesicles, suggesting potential for engineering synthetic cells with biological properties.
Article Abstract
Biological cells are contained by a fluid lipid bilayer (plasma membrane, PM) that allows for large deformations, often exceeding 50% of the apparent initial PM area. Isolated lipids self-organize into membranes, but are prone to rupture at small (<2-4%) area strains, which limits progress for synthetic reconstitution of cellular features. Here, it is shown that by preserving PM structure and composition during isolation from cells, vesicles with cell-like elasticity can be obtained. It is found that these plasma membrane vesicles store significant area in the form of nanotubes in their lumen. These act as lipid reservoirs and are recruited by mechanical tension applied to the outer vesicle membrane. Both in experiment and theory, it is shown that a "superelastic" response emerges from the interplay of lipid domains and membrane curvature. This finding allows for bottom-up engineering of synthetic biomaterials that appear one magnitude softer and with threefold larger deformability than conventional lipid vesicles. These results open a path toward designing superelastic synthetic cells possessing the inherent mechanics of biological cells.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8564416 | PMC |
| http://dx.doi.org/10.1002/advs.202102109 | DOI Listing |
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