Systems and methods for instrumented neurovascular unit device

What is claimed is: 1 . A neurovascular cell culture system comprising: an electrical/electronic interface board; a cell culture well secured to the interface board; a 3D microelectrode array disposed within an interior volume of the cell culture well and in electrical communication with the interface board, the 3D microelectrode array having at least one probe with at least one electrode thereon; and the cell culture well having at least one fluidic port for enabling fluidic access to the interior volume of the cell culture well. 2 . The system of claim 1 , wherein the at least one probe comprises a plurality of spaced apart, independent probes, with each one of the plurality of spaced apart, independent probes including a plurality of electrodes formed thereon. 3 . The system of claim 1 , wherein the at least one fluidic port is formed by a tube communicating with a region within the cell culture well adjacent to the 3D microelectrode. 4 . The system of claim 1 , wherein the at least one fluidic port comprises two independent tubes extending through openings in the cell culture well, with each said tube being in communication with a region adjacent to the 3D microelectrode within the volume of the cell culture well. 5 . The system of claim 1 , further comprising a cap for covering an upper area of the cell culture well. 6 . The system of claim 1 , wherein the cap includes at least one opening for enabling communication with the interior area of the well. 7 . The system of claim 1 , wherein the well includes: a lower region within which the 3D microelectrode is disposed; an intermediate region elevationally above the lower region forming a headspace, and which is substantially larger in volume than the lower region; and a region elevationally above the intermediate for receiving an O-ring. 8 . The system of claim 1 , wherein the well includes a polymerized hydrogel encasing the 3D microelectrode. 9 . The system of claim 8 , wherein: the well comprises: a lower region within which the 3D microelectrode is disposed; an intermediate region elevationally above the lower region which is substantially larger in volume than the lower region and which forms a headspace; and an O-ring groove above the intermediate region; and a polymerized hydrogel encasing the 3D microelectrode. 10 . The system of claim 1 , wherein the probe is configured to extend substantially perpendicularly to the interface board. 11 . A neurovascular cell culture assembly, comprising: a neurovascular cell culture system including: an electrical/electronic interface board; a cell culture well secured to the interface board; a 3D microelectrode array disposed within an interior volume of the cell culture well and in electrical communication with the interface board, the 3D microelectrode array having at least one probe with at least one electrode thereon; and the cell culture well having at least one fluidic port for enabling fluidic access to the interior volume of the cell culture well; and an enclosure assembly for containing the neurovascular cell culture system in a temperature controlled environment. 12 . The assembly of claim 11 , further comprising an amplifier in electrical communication with the neurovascular cell culture system. 13 . The assembly of claim 11 , wherein the cell culture well comprises a plurality of independent cell culture wells secured to the interface board. 14 . The assembly of claim 11 , further comprising at least one tube extending through an opening in the cell culture well into an area adjacent to the 3D microelectrode, to provide fluidic access to the interior volume of the cell culture well. 15 . The assembly of claim 14 , wherein the at least one tube comprises two independent tubes extending through a pair of openings in the cell culture wall into the interior volume of the cell culture well, and each said tube including a distal end being disposed adjacent to the 3D microelectrode. 16 . The assembly of claim 11 , wherein the assembly includes a cap for covering an uppermost area of the cell culture well. 17 . The assembly of claim 16 , wherein the cap is removably coupled to the cell culture well and includes at least one opening for permitting access to the interior volume of the cell culture well when the cap is secured to the cell culture well. 18 . The assembly of claim 11 , wherein the at least one probe comprises a plurality of independent, spaced apart probes each having a plurality of electrodes formed thereon. 19 . The assembly of claim 18 , wherein the plurality of independent, spaced apart probes are configured to extend generally perpendicularly relative to the electrical/electronics interface board within the cell culture well. 20 . A method for forming a monitoring neurovascular cell formation, comprising: using an electrical/electronic interface board to support a cell culture well thereon; arranging a 3D microelectrode array within an interior volume of the cell culture well, and such that the 3D microelectrode is in electrical communication with the interface board, wherein the 3D microelectrode array has at least one probe with at least one electrode thereon; at least partially filling an interior volume of the cell culture well with a substance which encases the 3D microelectrode array; providing fluidic access to the 3D microelectrode array; and using an electronic subsystem to communicate with the 3D microelectrode array to at least one of: obtain electrical signals collected by the 3D microelectrode array, or provide electrical signals to the 3D microelectrode array.