Neuroelectronic interfacing with cultured multielectrode arrays toward a cultured probe

Efficient and selective electrical stimulation and recording of neural activity in peripheral, spinal, or central pathways requires multielectrode arrays at micrometer scale. ¿Cultured probe¿ devices are being developed, i.e., cell-cultured planar multielectrode arrays (MEAs). They may enhance efficiency and selectivity because neural cells have been grown over and around each electrode site as electrode-specific local networks. If, after implantation, collateral sprouts branch from a motor fiber (ventral horn area) and if they can be guided and contacted to each ¿host¿ network, a very selective and efficient interface will result. Four basic aspects of the design and development of a cultured probe, coated with rat cortical or dorsal root ganglion neurons, are described. First, the importance of optimization of the cell-electrode contact is presented. It turns out that impedance spectroscopy, and detailed modeling of the electrode-cell interface, is a very helpful technique, which shows whether a cell is covering an electrode and how strong the sealing is. Second, the dielectrophoretic trapping method directs cells efficiently to desired spots on the substrate, and cells remain viable after the treatment. The number of cells trapped is dependent on the electric field parameters and the occurrence of a secondary force, a fluid flow (as a result of field-induced heating). It was found that the viability of trapped cortical cells was not influenced by the electric field. Third, cells must adhere to the surface of the substrate and form networks, which are locally confined, to one electrode site. For that, chemical modification of the substrate and electrode areas with various coatings, such as polyethyleneimine (PEI) and fluorocarbon monolayers promotes or inhibits adhesion of cells. Finally, it is shown how PEI patterning, by a stamping technique, successfully guides outgrowth of collaterals from a neonatal rat lumbar spinal cord explant, after six days in cultur

Intrinsic properties of the developing motor cortex in the rat: in vitro axons from the medial somatomotor cortex grow faster than axons from the lateral somatomotor cortex

The axons that originate in the medial somatomotor cortex of the rat depart, during development, after those from the lateral somatomotor cortex, yet they arrive in the cervical spinal cord first. Either the medially originating axons elongate faster, or the laterally originating ones pause along the descent pathway. To investigate the presence of an intrinsic difference of the axonal elongation velocity between the lateral and medial somatomotor cortical areas, we cultured explants taken from these areas for 2 days, and measured the length of the outgrowth. After 2 days the explants were surrounded by a radiate corona of axons of which the longest measured 1.95 mm. A significant difference was detected between the medial and lateral somatomotor cortical areas in vitro. Axons originating from explants taken from the medial somatomotor cortical area are, after 2 days in culture, on average 0.16 mm longer than those from the lateral somatomotor cortical area. Though the observed difference is not large enough to allow for the overtaking observed in vivo, it does indicate that intrinsic differences exist within the developing rat somatomotor cortex. This in turn indicates that intrinsic cortical traits not only influence regionalization and targeting behavior of cortical projection neurons, but also their axonal elongation speed