Download PDFOpen PDF in browserDesign and Optimization of Implantable Microelectronic Devices for Neural ProstheticsEasyChair Preprint no. 140489 pages•Date: July 19, 2024AbstractThis research investigates the design and optimization of implantable microelectronic devices aimed at enhancing the functionality and performance of neural prosthetics. By integrating advanced materials, miniaturized electronics, and biocompatible interfaces, the study aims to develop devices that can seamlessly interface with neural tissues to restore or augment sensory and motor functions. Key areas of focus include the development of low-power, high-efficiency circuits, wireless communication systems for data transmission and power transfer, and robust encapsulation techniques to ensure long-term stability and biocompatibility. Computational models and simulation tools are utilized to optimize device parameters and predict in vivo performance. The research also explores novel electrode designs to improve signal resolution and reduce tissue damage. The ultimate goal is to create reliable, high-performance neural prosthetic devices that can significantly improve the quality of life for individuals with neurological impairments. Keyphrases: biocompatibility, data transmission, electrode design, implantable microelectronic devices, low-power circuits, neural interfaces, Neural prosthetics, neurological impairments, power transfer, signal resolution, wireless communication
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