Integration of reconfigurable microchannels into aligned three-dimensional neural networks for spatially controllable neuromodulation.
Sohyeon JeongHyun Wook KangSo Hyun KimGyu-Sang HongMin-Ho NamJihye SeongEui-Sung YoonIl-Joo ChoSeok ChungSeokyoung BangHong Nam KimNakwon ChoiPublished in: Science advances (2023)
Anisotropically organized neural networks are indispensable routes for functional connectivity in the brain, which remains largely unknown. While prevailing animal models require additional preparation and stimulation-applying devices and have exhibited limited capabilities regarding localized stimulation, no in vitro platform exists that permits spatiotemporal control of chemo-stimulation in anisotropic three-dimensional (3D) neural networks. We present the integration of microchannels seamlessly into a fibril-aligned 3D scaffold by adapting a single fabrication principle. We investigated the underlying physics of elastic microchannels' ridges and interfacial sol-gel transition of collagen under compression to determine a critical window of geometry and strain. We demonstrated the spatiotemporally resolved neuromodulation in an aligned 3D neural network by local deliveries of KCl and Ca 2+ signal inhibitors, such as tetrodotoxin, nifedipine, and mibefradil, and also visualized Ca 2+ signal propagation with a speed of ~3.7 μ m/s. We anticipate that our technology will pave the way to elucidate functional connectivity and neurological diseases associated with transsynaptic propagation.
Keyphrases
- neural network
- functional connectivity
- resting state
- tissue engineering
- ionic liquid
- photodynamic therapy
- squamous cell carcinoma
- high throughput
- protein kinase
- radiation therapy
- molecular dynamics simulations
- drug delivery
- white matter
- locally advanced
- high resolution
- mass spectrometry
- atomic force microscopy
- simultaneous determination