Carbon nanotubes (CNTs) are nanometer-scale cylindrical graphitic struc-
tures that exhibit extraordinary physical properties as determined by their
structure [6]. Developing neural implants and the process of neuron regener-
ation are extremely difcult. Nerve cells require the right environment and
the right growth factors at the right time to grow and proliferate. The elec-
trical conductive properties of these nanotubes o®er the possibility of using
it as a replacement to transmit and receive signals. The resulting 'hair like'
conductive wires that incorporate the properties of electrodes, permeable mi-
cro°uidic conduits and the porosity of the CNTs was found to promote cell
growth, migration and proliferation. The bridging consists either of an axon
or bundles of axons and dendrites. In some cases the bridge is covered with
clusters of cells [7]. These bridges form very e±ciently over quartz surfaces
which are apparently very poor surfaces for cell attachment.
tures that exhibit extraordinary physical properties as determined by their
structure [6]. Developing neural implants and the process of neuron regener-
ation are extremely difcult. Nerve cells require the right environment and
the right growth factors at the right time to grow and proliferate. The elec-
trical conductive properties of these nanotubes o®er the possibility of using
it as a replacement to transmit and receive signals. The resulting 'hair like'
conductive wires that incorporate the properties of electrodes, permeable mi-
cro°uidic conduits and the porosity of the CNTs was found to promote cell
growth, migration and proliferation. The bridging consists either of an axon
or bundles of axons and dendrites. In some cases the bridge is covered with
clusters of cells [7]. These bridges form very e±ciently over quartz surfaces
which are apparently very poor surfaces for cell attachment.