Abstract-Optoelectronic tweezers (OET) provide a powerful tool for the manipulation of micro-and nanoparticles. The OET device produces an optically controlled dielectrophoretic force, allowing complex dynamic manipulation patterns using light intensities up to 100 000 times lower than that of optical tweezers. Using OET, we demonstrate the separation of live and dead human B cells, and the separation of HeLa and Jurkat cells. We also present, for the first time, a modified single-sided OET device that promises to facilitate the integration of OET and microfluidics. Unlike standard OET, this single-sided OET device produces electric fields that are oriented parallel to the plane of the device. We demonstrate the manipulation of polystyrene beads using this new single-sided OET device, and discuss its capabilities.
Index Terms-Dielectrophoresis (DEP), optical tweezers, optically induced dielectrophoresis, optoelectronic tweezers (OET).
Optoelectronic tweezers enables parallel manipulation of individual single cells using optical addressing and optically induced dielectrophoretic force. This provides a useful platform for performing a variety of biological functions, such as cell manipulation, cell sorting, and cell electroporation. However, in order to obtain more reliable cellular manipulation, especially of adherent mammalian cells, antifouling coatings need to be used to avoid non-specific cell adherence. Two antifouling coatings are discussed here, which can reduce the amount of non-specific adherence by as much as a factor of 30.
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