We propose to develop novel biodegradable probe materials for enhancing recording and stimulation capabilities of microelectrodes used in neural prostheses and neuroscience. Neural prostheses and functional electrical stimulation systems employing microelectrodes continue to improve and expand their applications in treating neural-degenerative diseases as well as providing tools for basic neuroscience. Their present and future applications include brain-machine interfaces, visual and auditory prostheses, cognitive prosthesis (hippocampus), peripheral nerve prostheses, and deep-brain stimulation. The majority of structural materials used in the recording and/or stimulating microelectrode systems, such as silicon, metals, and ceramics, have been rigid. A main hurdle in the development of the microelectrode system for clinical applications has been their proneness to failure during long-term use. Studies have suggested that loss or deterioration of recording and stimulation capabilities may be due to chronic inflammatory tissue responses around the microelectrode sites, and that local shear forces and strain in the tissue due to micromotion between the probes and the tissue contribute to this. Although soft and flexible polymers have been investigated, their flexibility makes insertion into brain targets difficult. We propose to develop probes with transient mechanical properties that will provide high mechanical stiffness during insertion and gradually degrades over time, leaving the non-degrading flexible polymer probe for long-term use. Our main goal is to develop a novel biodegradable neural probe made of polymer-ceramic composites which allow for control of degradation rate as well as provides mechanical reinforcement. Composition and thickness of the composites will be optimized through acute insertion experiment into animals'brains and by soak-test, and their biocompatibility will be evaluated in-vivo. An underlying hypothesis in this design- or technology-driven project is that these biodegradable probes will result in less chronic inflammatory responses than will rigid probes, which in turn, will result in improved long-term functionality.
Significant health benefits will accrue from increased use of neural prostheses with improved long-term functionality. Their clinical applications include rehabilitation following spinal cord injury or stroke, and sensory deficits such as profound hearing loss, as well as treatments of neurodegenerative diseases, such as Parkinson's disease, epilepsy, and depression. The devices described in this application will also advance knowledge in basic and applied neuroscience.
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Han, Martin; Manoonkitiwongsa, Panya S; Wang, Cindy X et al. (2012) In vivo validation of custom-designed silicon-based microelectrode arrays for long-term neural recording and stimulation. IEEE Trans Biomed Eng 59:346-54 |