Basic NeuroscienceInsect-machine interface: A carbon nanotube-enhanced flexible neural probe

We developed microfabricated flexible neural probes (FNPs) to provide a bi-directional electrical link to the moth Manduca sexta. These FNPs can deliver electrical stimuli to, and capture neural activity from, the insect's central nervous system. They are comprised of two layers of polyimide with gold sandwiched in between in a split-ring geometry that incorporates the bi-cylindrical anatomical structure of the insect's ventral nerve cord. The FNPs provide consistent left and right abdominal stimulation both across animals and within an individual animal. The features of the stimulation (direction, threshold charge) are aligned with anatomical features of the moth. We also have used these FNPs to record neuronal activity in the ventral nerve cord of the moth. Finally, by integrating carbon nanotube (CNT)-Au nanocomposites into the FNPs we have reduced the interfacial impedance between the probe and the neural tissue, thus reducing the magnitude of stimulation voltage. This in turn allows use of the FNPs with a wireless stimulator, enabling stimulation and flight biasing of freely flying moths. Together, these FNPs present a potent new platform for manipulating and measuring the neural circuitry of insects, and for other nerves in humans and other animals with similar dimensions as the ventral nerve cord of the moth.

► Developed a microfabricated multisite probe for stimulating and recording from moth nerve cord. ► We based the geometry of the probe on the anatomy of insect's ventral nerve cord. ► Integrating CNT-Au nanocomposite onto the probe improved interfacial properties. ► The probe had abdominal stimulation within and across animals, consistent with it's geometry. ► We demonstrated remote flight biasing of moth using neural stimulation via microfabricated probe.