Microelectrodes made from structured diamond for neural interfacing applications

1 . A microelectrode for neural interfacing applications comprising a stack of a first layer of substrate in a first biocompatible material, a second adhesion layer in a second material for initiating the growth of synthetic diamond crystals, and a third layer in a third electrically conductive material, including poly-crystalline diamond doped with atoms comprised in the set formed by boron atoms, nitrogen atoms and phosphorus atoms, the first, second, third layers ( 1 , 6 , 8 ) having mutually parallel extension planes, characterized in that the third material is a textured material which comprises a compact set, as a brush, of hollow or solid tubes, each consisting of at least one peripheral layer, radially external, of doped poly-crystalline diamond, radially deposited by growth at high temperature, the tubes each having a first end attached to the second layer and a second free end, intended to be the active portion of the electrode, the tubes being separated from each other by an empty space at their first ends and projecting their second ends in a direction away from the first and second layers substantially normal with respect to the extension plane of the second layer. 2 . The microelectrode according to claim 1 , characterized in that the tubes form a carpet in which, either all the tubes are substantially normal with respect to the extension plane of the second layer and separated from each other regularly, or the tubes are grouped in bundles, separated from each other regularly and wherein the second ends of the tubes of a same bundle are brought closer to each other, or even touch each other. 3 . The microelectrode according to claim 1 , wherein each tube has a length comprised between 500 nm and 50 μm, and each tube has a section having a substantially constant diameter over the whole length or each tube has a variable section which decreases from its first end as far as its second end. 4 . The microelectrode according to claim 1 , wherein the second material is an adhesion material for diamond suitable for being used as a diffusion barrier to a molten metal comprised in the set formed by nickel, cobalt, iron and nickel, iron, cobalt alloys, and the first material is a biocompatible material which may resist to the growth conditions of the diamond, either electrically insulating comprised for example in the set formed by SiO 2 , Si 3 N 4 , quartz, glass, GaN, or electrically conductive for example comprised in the set formed by Pt, PtIr, Ti, TiN, TiPt alloys, diamond doped with boron. 5 . The microelectrode according to claim 4 , wherein the second material is comprised in the set formed by titanium nitride TiN, non-doped poly-crystalline diamond, poly-crystalline diamond doped with atoms comprised in the set formed by boron atoms, nitrogen atoms and phosphorus atoms, preferably poly-crystalline diamond doped with boron. 6 . The microelectrode according to claim 1 , comprising a fourth layer in a fourth material consisting of doped polycrystalline diamond, the fourth layer covering the totality of the third layer at the base of the tubes forming the second material. 7 . The microelectrode according to claim 1 , comprising a fifth layer and a sixth layer, the fifth layer being in a fifth metal material, forming an electric current outlet of the third layer through the second layer when the latter is electrically conductive and/or of the fourth layer, the fifth layer being positioned on or above the first layer, either underneath the second layer when the latter is conductive, or in contact and at the periphery of the second and fourth layers independently of the electric conductivity of the second layer, the fifth layer having a contact area, forming an electric output terminal of the microelectrode and shifted from the third layer along the extension plane of the second layer, the sixth layer being a biocompatible layer for passivation of the fifth layer covering la totality of the fifth layer except for its contact area forming the electric output terminal of the microelectrode. 8 . A network of a multitude of microelectrodes for neural interfacing applications comprising a plurality of at least two microelectrodes defined according to claim 1 , developed and etched on a stack of layers common according to a distribution pattern on a planar surface. 9 . A flexible implant for neural interfacing applications comprising: a network of a multitude of microelectrodes defined according to claim 8 wherein, and a matrix in a flexible polymeric material of small thickness with a two-dimensional main extension including a monolayer sheet, and for each microelectrode, a single and different sheet with two layers covering the microelectrode while leaving exposed the second ends of its tubes and of its contact area, the whole of the sheets being join together in a single part by the monolayer sheet, with or without any through-hole. 10 . A method for manufacturing a microelectrode for neural interfacing applications comprising the steps consisting of providing in a first step a first dielectric substrate layer in a first biocompatible material, and then in a second step depositing a second adhesion layer in a second material for initiating growth of synthetic diamond crystals, in a third step manufacturing a third layer in a third electrically conductive material, including crystalline poly-crystalline diamond doped with atoms comprised in the set formed by boron atoms, nitrogen atoms and phosphorus atoms, the first, second, third layers having parallel extensions planes, characterized in that the third material is a textured material which comprises a compact set as a brush, of hollow or solid tubes, each consisting of at least one peripheral layer, radially external, of doped poly-crystalline diamond, deposited radially by growth at high temperature, the tubes each having a first end attached to the second layer and a second free end, intended to be the active portion of the electrode, the tubes being separated from each other by an empty space at their first ends and projecting their second ends in a direction away from the first and second layers substantially normal with respect to the extension plane of the second layer. 11 . The manufacturing method according to claim 10 , wherein the third step comprises the steps consisting of in a fourth step, growing carbon nanotubes (CNT) on and from the second layer, and then in a fifth step, depositing one or several first layers of non-doped diamond nanoparticles on each of the carbon nanotubes, and then in a sixth step, depositing on the first non-doped diamond layer(s) by chemical vapor deposition assisted by plasma of the doped diamond by glowing the doped diamond crystal until complete cover of the carbon nanotubes and partial or complete etching with radical hydrogen contained in the plasma. 12 . The manufacturing method according to claim 10 , wherein during the sixth step a fourth layer in doped polycrystalline diamond is also formed so as to cover the totality of the third layer at the base of the tubes forming the second material. 13 . The manufacturing method according to claim 11 , wherein the fourth step comprises: a seventh step for depositing as a thin layer a metal comprised in the set formed by nickel, iron, cobalt, and their alloys notably FeNi, FeCoNi, preferably nickel on the second layer, and then an eighth step for de-wetting by annealing of the metal deposited as a thin layer in the seventh step in order to obtain metal drops regularly distributed over the second layer, and then a ninth step in which carbon nanotubes are grown on and from metal dr