During the first two years of the project, the main effort has been made on the development and characterization of the bypass parts materials. In addition, biocompatibility tests are already being carried out, as well as initial tests of the excitation ability of the nanostructured electrodes.
Regarding the magnetic sensors, first prototypes have been developed in GREYC/CNRS (France) by depositing thin films of La0.7Sr0.3MnO3 (LSMO) using the technique of Pulsed Laser Deposition. The on-bench performance of these sensors has been characterized both in GREYC/CNRS and IMDEA-Nanociencia (Spain), including their sensitivity, detectivity or bridge imbalance. Sub-nT/Hz-1/2 detectivity values have been obtained in the range 10-100 Hz, even before complete optimization of the system.
In parallel, nanostructured electrodes have been fabricated at IMDEA Nanociencia (Spain) using two approaches:
(1) Coating of vertical free-standing metallic nanowires grown by template assisted electrochemical deposition. We have successfully prepared coatings of nanowires of various metals, using two kinds of template.
(2) Coating of conductive polymeric nanopillars fabricated by nanoimprinting. Different compositions of polymer have been tested in order to optimize the conductivity of the pillars.
The teams of SISSA (Italy), SESCAM and CSIC (Spain) initiated the evaluation of the biocompatibility of the bypass parts and prototypes. Research efforts have focused on two main objectives:
(1) To evaluate the biocompatibility in vitro of the materials and nanostructured devices fabricated;
(2) To functionalize the bypass elements/prototype to enhance biocompatibility and reduce tissue disturbance.
An exhaustive screening of the interaction of the different materials and nanostructured devices fabricated with embryonic neural progenitor cells (CSIC+SESCAM), postnatal hippocampal cells (SISSA) and organotypic cultures (SISSA) were performed. Studies focused on neural cell adhesion, viability, morphology, differentiation, and simultaneous imaging of the intracellular calcium activity of living neurons. Material samples analyzed included:
(1) Electrodeposited nanowires in either a random or vertical position on the substrate;
(2) Vertical metallic nanowires up to 2 microns long of single metal samples and combinations of metals;
(3) Polymeric nanopillars of different electrical conductance;
(4) Reduced graphene oxide nanofibers.
With respect to the functionalization of the substrates aimed to improve their biocompatibility, various treatments are under study. Initial stimulation tests on dissociated hippocampal cultures using some of the nanostructured electrodes have been performed in SISSA (Italy), using live calcium imaging to monitor the activity response.