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Control of polymers' amorphous-crystalline transition enables miniaturization and multifunctional integration for hydrogel bioelectronics.

Sizhe HuangXinyue LiuShaoting LinChristopher GlynnKayla FelixAtharva SahasrabudheCollin MaleyJingyi XuWeixuan ChenEunji HongAlfred J CrosbyQianbin WangSiyuan Rao
Published in: Nature communications (2024)
Soft bioelectronic devices exhibit motion-adaptive properties for neural interfaces to investigate complex neural circuits. Here, we develop a fabrication approach through the control of metamorphic polymers' amorphous-crystalline transition to miniaturize and integrate multiple components into hydrogel bioelectronics. We attain an about 80% diameter reduction in chemically cross-linked polyvinyl alcohol hydrogel fibers in a fully hydrated state. This strategy allows regulation of hydrogel properties, including refractive index (1.37-1.40 at 480 nm), light transmission (>96%), stretchability (139-169%), bending stiffness (4.6 ± 1.4 N/m), and elastic modulus (2.8-9.3 MPa). To exploit the applications, we apply step-index hydrogel optical probes in the mouse ventral tegmental area, coupled with fiber photometry recordings and social behavioral assays. Additionally, we fabricate carbon nanotubes-PVA hydrogel microelectrodes by incorporating conductive nanomaterials in hydrogel for spontaneous neural activities recording. We enable simultaneous optogenetic stimulation and electrophysiological recordings of light-triggered neural activities in Channelrhodopsin-2 transgenic mice.
Keyphrases
  • drug delivery
  • tissue engineering
  • hyaluronic acid
  • wound healing
  • carbon nanotubes
  • room temperature
  • healthcare
  • spinal cord
  • high throughput
  • photodynamic therapy
  • high speed
  • spinal cord injury
  • single cell
  • living cells