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Photo–cross-linkable, insulating silk fibroin for bioelectronics with enhanced cell affinity

Jie Ju, Ning Hu, Dana M. Cairns, Haitao Liu, Brian P. Timko

2020Proceedings of the National Academy of Sciences41 citationsDOIOpen Access PDF

Abstract

Bioelectronic scaffolds that support devices while promoting tissue integration could enable tissue hybrids with augmented electronic capabilities. Here, we demonstrate a photo-cross-linkable silk fibroin (PSF) derivative and investigate its structural, electrical, and chemical properties. Lithographically defined PSF films offered tunable thickness and <1-µm spatial resolution and could be released from a relief layer yielding freestanding scaffolds with centimeter-scale uniformity. These constructs were electrically insulating; multielectrode arrays with PSF-passivated interconnects provided stable electrophysiological readouts from HL-1 cardiac model cells, brain slices, and hearts. Compared to SU8, a ubiquitous biomaterial, PSF exhibited superior affinity toward neurons which we attribute to its favorable surface charge and enhanced attachment of poly-d-lysine adhesion factors. This finding is of significant importance in bioelectronics, where tight junctions between devices and cell membranes are necessary for electronic communication. Collectively, our findings are generalizable to a variety of geometries, devices, and tissues, establishing PSF as a promising bioelectronic platform.

Topics & Concepts

BioelectronicsFibroinPassivationNanotechnologyMaterials sciencePhotolithographySILKBiocompatible materialBiosensorBiomedical engineeringEngineeringLayer (electronics)Composite materialSilk-based biomaterials and applicationsNeuroscience and Neural EngineeringAdvanced Sensor and Energy Harvesting Materials
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