AI Article Synopsis
- Understanding how cells interact with 3D nanostructures is crucial for integrating electronic devices with electrically active cells.
- Recent advances have introduced various nanoscale structures designed to stimulate and measure electrical signals from cells, but the underlying mechanisms of how cells engage with these structures are still unclear.
- This study combines electron microscopy and theoretical models to analyze cell interactions with cylindrical nanostructures, ultimately aiming to design more effective shapes and sizes for better cell-device integration.*
Article Abstract
An in-depth understanding of the interface between cells and nanostructures is one of the key challenges for coupling electrically excitable cells and electronic devices. Recently, various 3D nanostructures have been introduced to stimulate and record electrical signals emanating from inside of the cell. Even though such approaches are highly sensitive and scalable, it remains an open question how cells couple to 3D structures, in particular how the engulfment-like processes of nanostructures work. Here, we present a profound study of the cell interface with two widely used nanostructure types, cylindrical pillars with and without a cap. While basic functionality was shown for these approaches before, a systematic investigation linking experimental data with membrane properties was not presented so far. The combination of electron microscopy investigations with a theoretical membrane deformation model allows us to predict the optimal shape and dimensions of 3D nanostructures for cell-chip coupling.
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| http://dx.doi.org/10.1021/nn500393p | DOI Listing |
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