Modular Integration of Hydrogel Neural Interfaces

Abstract

Thermal drawing has been recently leveraged to yield multi-functional, fiber-based neural probes at near kilometer length scales. Despite its promise, the widespread adoption of this approach has been impeded by (1) material compatibility requirements and (2) labor-intensive interfacing of functional features to external hardware. Furthermore, in multifunctional fibers, significant volume is occupied by passive polymer cladding that so far has only served structural or electrical insulation purposes. In this letter, we report a rapid, robust, and modular approach to creating multi-functional fiber-based neural interfaces using a solvent evaporation or entrapment driven (SEED) integration process. This process brings together electrical, optical, and microfluidic modalities all encased within a co-polymer comprised of water-soluble poly(ethylene glycol) tethered to water-insoluble poly(urethane) (PU-PEG). We employ these devices for simultaneous optogenetics and electrophysiology, and demonstrate that multi-functional neural probes can be used to deliver cellular cargo with high viability. Upon exposure to water, PU-PEG cladding spontaneously forms a hydrogel, which in addition to enabling integration of modalities, can harbor small molecules and nanomaterials that can be released into local tissue following implantation. We also synthesized a custom nanodroplet forming block polymer and demonstrated that embedding such materials within the hydrogel cladding of our probes enables delivery of hydrophobic small molecules in vitro and in vivo. Our approach widens the chemical toolbox and expands the capabilities of multi-functional neural interfaces.

Publication
chemRxiv
Atharva Sahasrabudhe
Atharva Sahasrabudhe
Graduate Student

Graduate student

Jimin Park
Assistant Professor at KAIST
Dekel Rosenfeld
Zuckerman Faculty Scholar, Tel Aviv University
Polina Anikeeva
Polina Anikeeva
Matoula S. Salapatas Professor and Head, Department of Materials Science and Engineering
Professor, Brain and Cognitive Sciences
Director, K. Lisa Yang Brain-Body Center
Associate Investigator, McGovern Institute for Brain Research
Associate Director, Research Laboratory of Electronics

My goal is to combine the current knowledge of biology and nanoelectronics to develop materials and devices for minimally invasive treatments for neurological and neuromuscular diseases.

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