EMEMI: An interference‐free mini‐incubator with integrated electric and magnetic field exposure for real‐time microscopic imaging of field effects

Abstract

AbstractUninterrupted microscopic observation and real‐time imaging of cell behavior during exposure to the stimulus, for example, electric and/or magnetic fields, especially for periods of several days, has been a challenge in experimental bioelectromagnetics due to a lack of proper gas/temperature conditions outside the incubator. Conventional mini‐incubators might suffer from stray fields produced by heating elements. We report an in vitro electric and magnetic fields (EMF) exposure system embedded inside a novel under‐the‐microscope mini‐CO2‐incubator with a unique design to avoid electromagnetic interference from the heating and circulation functions while ensuring the requisite temperature. A unique, reconfigurable array of electrodes and/or coils excited by calculated current distributions among array elements is designed to provide excellent field uniformity and controllable linear or circular polarization (even at very low frequencies) of the EMF within the cell culture. Using standard biochemical assays, long‐term cell viability has been verified and compared with a conventional incubator. Cell orientation/migration in three‐dimensional culture made of collagen‐hydrogels has been successfully observed in vitro, in long‐term, and in real‐time under the influence of DC electric fields with the device.