Exploring polymeric biomaterials in developing neural prostheses

Abstract: Neuroprosthetics, with a range of applications such as cognitive, auditory, pain relief, recording, motor, and visual prosthetics have emerged as a promising field in recent years. However, poor electrical conductivity, a high disparity between tissue and interfaces and the onset of reactive gliosis post-implantation remains major challenges in the development of neuroprostheses. The choice of biomaterials in designing the neural interfaces’ in neuroprosthetic applications is of high importance, as the overall… Show more

“…Nowadays, soft electrode materials consisting of polymers such as PEDOT [ 27 ], polypyrrole [ 28 ], and polythiophene [ 29 ] can likewise be considered, as they significantly reduce rejection reactions. However, these materials are not as flexible [ 30 ], have poorer electrical properties, and exhibit reduced long-lasting mechanical behavior [ 31 , 32 ].…”

Laminin Adsorption and Adhesion of Neurons and Glial Cells on Carbon Implanted Titania Nanotube Scaffolds for Neural Implant Applications

“…Nowadays, soft electrode materials consisting of polymers such as PEDOT [ 27 ], polypyrrole [ 28 ], and polythiophene [ 29 ] can likewise be considered, as they significantly reduce rejection reactions. However, these materials are not as flexible [ 30 ], have poorer electrical properties, and exhibit reduced long-lasting mechanical behavior [ 31 , 32 ].…”

Laminin Adsorption and Adhesion of Neurons and Glial Cells on Carbon Implanted Titania Nanotube Scaffolds for Neural Implant Applications