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Entry of microparticles into giant lipid vesicles by optical tweezers
Summary
Using optical tweezers to apply precise forces, this study showed that microparticles can be pushed through lipid membrane vesicles — a model for cell membranes — when external mechanical force is applied and membrane tension is low. The findings provide mechanistic insight into how microplastics might physically cross cell membranes and enter cells, a key step in understanding potential cellular toxicity.
Entry of micro- or nanosized objects into cells or vesicles made of lipid membranes occurs in many processes such as entry of viruses into host cells, microplastics pollution, drug delivery, or biomedical imaging. Here we investigate the microparticle crossing of lipid membranes in giant unilamellar vesicles in the absence of strong binding interactions (e.g., streptavidin-biotin binding). In these conditions, we observe that organic and inorganic particles can always penetrate inside the vesicles provided an external piconewton force is applied and for relatively low membrane tensions. In the limit of vanishing adhesion, we identify the role of the membrane area reservoir and show that a force minimum exists when the particle size is comparable to the bendocapillary length.
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