Abstract: Disclosed herein are novel 3D microelectrode arrays (3D MEA) that include a substrate body (e.g. chip), microneedles, traces, and a well, wherein the 3D MEA provides for transfer of electrical signals on one side of the substrate body to the other side of the substrate body. Methods for using 3D MEAs to grow electrogenic cells and obtain electrophysiological signals are disclosed as well. Fabrication techniques for producing the 3D MEAs are also disclosed.

Abstract: The present invention is directed to a microelectrode array for use in microengineered physiological systems and methods of using the same.

Abstract: The present disclosure generally relates to a cell culturing system, and specifically to a three-dimensional cell culturing system for neuronal cells that promotes both structural and functional characteristics that mimic those of in vivo peripheral fibers, including cell myelination. Using a dual hydrogel construct and spheroids comprising neuronal cells, the present disclosure provides methods, devices, and systems for in vitro spatially-controlled, three-dimensional models that permit intra- and extra-cellular electro-physiological measurements and recordings. The three-dimensional hydrogel constructs allow for flexibility in incorporated cell types, geometric fabrication, and electrical manipulation, providing viable systems for culture, perturbation, and testing of biomimetic neural growth with physiologically-relevant results.

Abstract: The present disclosure generally relates to a cell culturing system, and specifically to a three-dimensional cell culturing system for neuronal cells that promotes both structural and functional characteristics that mimic those of in vivo peripheral fibers, including cell myelination. Using a dual hydrogel construct and explants from neuronal cells, the present disclosure provides methods, devices, and systems for in vitro spatially-controlled, three-dimensional models that permit intra- and extra-cellular electrophysiological measurements and recordings. The three-dimensional hydrogel constructs allow for flexibility in incorporated cell types, geometric fabrication, and electrical manipulation, providing viable systems for culture, perturbation, and testing of biomimetic neural growth with physiologically-relevant results.