Fabrication and Characterization of PDMS Waveguides for Flexible Optrodes.

With the growth of optogenetic research, the demand for optical probes tailored to specific applications is ever rising. Specifically, for applications like the coiled cochlea of the inner ear, where planar, stiff, and nonconformable probes can hardly be used, transitioning from commonly used stiff glass fibers to flexible probes is required, especially for long-term use. Following this demand, polydimethylsiloxane (PDMS) with its lower Young's modulus compared to glass fibers can serve as material of choice. Hence, the long-term usability of PDMS as a waveguide material with respect to variations in transmission and refractive index over time is investigated. Different manufacturing methods for PDMS-based flexible waveguides are established and compared with the aim to minimize optical losses and thus maximize optical output power. Finally, the waveguides with lowest optical losses (-4.8 dB cm-1 ± 1.3 dB cm-1 at 472 nm) are successfully inserted into the optogenetically modified cochlea of a Mongolian gerbil (Meriones unguiculatus), where optical stimuli delivered by the waveguides evoked robust neuronal responses in the auditory pathway.

An optoelectronic neural interface approach for precise superposition of optical and electrical stimulation in flexible array structures.

Optical stimulation of genetically modified nerve cells has become one of the state-of-the-art methods in neuroscience. This so-called optogenetic approach allows cell-type specific activation in comparison to more generalized electrical stimulation. Combinations of both stimulation modalities would be desirable to investigate effects in detail and specify differences. This work presents the design of a miniaturized optoelectronic device that allows optical and electrical activation at the same spot. Indium tin oxide (ITO), which is transparent to visible light, has been chosen as electrode material. Light emitting diodes were assembled on a polyimide substrate with integrated interconnection lines, directly behind the electrodes to compare optical with electrical stimulation. The optical transparency of the ITO-polyimide layer stack was investigated and showed sufficient transmission in the required wavelength range. ITO electrodes with diameters up to 1000 µm were electrochemically characterized using electrical impedance spectroscopy (EIS). Several diameters did show comparable results to platinum, a commonly used electrode material. Fully assembled devices were used in combination an ex vivo setting with genetically modified retina to demonstrate the functionality of this approach. Retinal ganglion cells were excited by both, optical and electrical stimulation at the same spot and signals were recorded via standard microelectrode arrays (MEA) as reference. The simultaneous stimulation and recording of directly evoked action potentials indicates a similar mode of action of the two stimulation modalities. Further engineering work is needed to transfer the presented and proven concept into devices for chronic implantation, might it be in animal or first-in-human studies.