AI Article Synopsis
- * A new method using electric fields and hydraulic pressure helps regulate the fusion of lipid bilayers, allowing researchers to adjust their shape and size in physiological conditions.
- * This approach shows promise for various biological applications, demonstrated by stable in-vitro experiments lasting 38 days and mimicking natural transport processes.
Article Abstract
Membrane fusion, merging two lipid bilayers, is crucial for fabricating artificial membrane structures. Over the past 40 years, in contrast to precise and controllable membrane fusion in-vivo through specific molecules such as SNAREs, controlling the fusion in-vitro while fabricating artificial membrane structures in physiological ionic solutions without fusion proteins has been a challenge, becoming a significant obstacle to practical applications. We present an approach consisting of an electric field and a few kPa hydraulic pressure as an additional variable to physically control the fusion, enabling tuning of the shape and size of the 3D freestanding lipid bilayers in physiological ionic solutions. Mechanical model analysis reveals that pressure-induced parallel/normal tensions enhance fusion among membranes in the microwell. In-vitro peptide-membrane assay, mimicking vesicular transport via pressure-assisted fusion, and stability of 38 days with in-chip pressure control via pore size-regulated hydrogel highlight the potential for diverse biological applications.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11133453 | PMC |
| http://dx.doi.org/10.1038/s41467-024-48875-0 | DOI Listing |
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