Developments in materials science and engineering have significantly enhanced the recording and stimulation capabilities of electrophysiological neural interface devices. Enhanced biocompatibility has increased the viability and longevity of such systems, with particularly interesting advances resulting from the utilization of organic and mixed-conductive conjugated polymers. These materials tend to improve biocompatibility and signal quality by overcoming material limitations of conventional metallic electrodes. Simultaneously, advanced microfabrication methods have increased the spatiotemporal resolution and signal quality of recorded data without added invasiveness.
The research work presented in this dissertation touches upon three aspects of relevance for improved neural interface use: i) improving the accuracy of histological verification procedures in research using naturally abundant organic materials; ii) introducing unconventional electrodes for neural recordings and localized drug delivery by utilizing conductive organic polymers and clinical supply items; iii) applying a high-density electrocorticography (ECoG) array to study differential neural oscillation patterns underlying memory processing in vivo.
First, we showcase a chitosan (CS) based, solution-processable film for localizing neural implants by leveraging CSs intrinsic fluorescence, without impeding data quality or cell viability.
Second, we develop a mixed-conductive suture by using standard silk sutures and the mixed-conductive polymer PEDOT:PSS. The resulting device (E-Suture) is shown to safely interface with live tissue and possess high-fidelity recording and stimulation capabilities as well as applicability for localized drug delivery thanks to the mixed-conductivity of PEDOT:PSS.
Finally, we leverage high spatiotemporal resolution ECoG arrays to show that distinctive oscillatory memory biomarkers in the neocortex and hippocampus show significant but differential temporal coupling patterns in response to consolidation of new information and reconsolidation of that information at a later time in rats.
This dissertation demonstrates the utility of different organic materials for the enhancement of neural interface functions at multiple phases of the device life cycle as well as a concrete demonstration of improved electrophysiological recording devices in answering key questions of foundational neuroscience.
| Identifer | oai:union.ndltd.org:columbia.edu/oai:academiccommons.columbia.edu:10.7916/x7ra-h324 |
| Date | January 2024 |
| Creators | Rauhala, Onni |
| Source Sets | Columbia University |
| Language | English |
| Detected Language | English |
| Type | Theses |
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