Fabrication Methods and Chronic In Vivo Validation of Mechanically Adaptive Microfluidic Intracortical Devices

Authors

Youjoung Kim, Case Western Reserve UniversityFollow
Natalie N. Mueller, Case Western Reserve UniversityFollow
William E. Schwartzman, Case Western Reserve UniversityFollow
Danielle Sarno, Case Western Reserve University
Reagan Wynder, Case Western Reserve University
George F. Hoeferlin, Case Western Reserve UniversityFollow
Kaela Gisser, Case Western Reserve University
Jeffrey R. Capadona, Case Western Reserve UniversityFollow
Allison E. Hess-Dunning, Case Western Reserve UniversityFollow

Author ORCID Identifier

Youjoung Kim

Natalie N. Mueller

William E. Schwartzman

Reagan Wynder

George F. Hoeferlin

Kaela Gisser

Jeffrey R. Capadona

Allison Hess-Dunning

Document Type

Article

Publication Date

5-9-2023

Abstract

Intracortical neural probes are both a powerful tool in basic neuroscience studies of brain function and a critical component of brain computer interfaces (BCIs) designed to restore function to paralyzed patients. Intracortical neural probes can be used both to detect neural activity at single unit resolution and to stimulate small populations of neurons with high resolution. Unfortunately, intracortical neural probes tend to fail at chronic timepoints in large part due to the neuroinflammatory response that follows implantation and persistent dwelling in the cortex. Many promising approaches are under development to circumvent the inflammatory response, including the development of less inflammatory materials/device designs and the delivery of antioxidant or anti-inflammatory therapies. Here, we report on our recent efforts to integrate the neuroprotective effects of both a dynamically softening polymer substrate designed to minimize tissue strain and localized drug delivery at the intracortical neural probe/tissue interface through the incorporation of microfluidic channels within the probe. The fabrication process and device design were both optimized with respect to the resulting device mechanical properties, stability, and microfluidic functionality. The optimized devices were successfully able to deliver an antioxidant solution throughout a six-week in vivo rat study. Histological data indicated that a multi-outlet design was most effective at reducing markers of inflammation. The ability to reduce inflammation through a combined approach of drug delivery and soft materials as a platform technology allows future studies to explore additional therapeutics to further enhance intracortical neural probes performance and longevity for clinical applications.

Keywords

drug delivery, mechanically adaptive, microfabrication, microfluidic, neural interface, polymer

Publication Title

Micromachines

Rights

© 2023 by the authors.

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Recommended Citation

Kim, Y.; Mueller, N.N.; Schwartzman, W.E.; Sarno, D.; Wynder, R.; Hoeferlin, G.F.; Gisser, K.; Capadona, J.R.; Hess-Dunning, A. Fabrication Methods and Chronic In Vivo Validation of Mechanically Adaptive Microfluidic Intracortical Devices. Micromachines 2023, 14, 1015. https://doi.org/10.3390/mi14051015