TY - JOUR
T1 - Micelle-enabled self-assembly of porous and monolithic carbon membranes for bioelectronic interfaces
AU - Fang, Yin
AU - Prominski, Aleksander
AU - Rotenberg, Menahem Y.
AU - Meng, Lingyuan
AU - Acarón Ledesma, Héctor
AU - Lv, Yingying
AU - Yue, Jiping
AU - Schaumann, Erik
AU - Jeong, Junyoung
AU - Yamamoto, Naomi
AU - Jiang, Yuanwen
AU - Elbaz, Benayahu
AU - Wei, Wei
AU - Tian, Bozhi
N1 - Publisher Copyright:
© 2020, The Author(s), under exclusive licence to Springer Nature Limited.
PY - 2021/2/1
Y1 - 2021/2/1
N2 - Real-world bioelectronics applications, including drug delivery systems, biosensing and electrical modulation of tissues and organs, largely require biointerfaces at the macroscopic level. However, traditional macroscale bioelectronic electrodes usually exhibit invasive or power-inefficient architectures, inability to form uniform and subcellular interfaces, or faradaic reactions at electrode surfaces. Here, we develop a micelle-enabled self-assembly approach for a binder-free and carbon-based monolithic device, aimed at large-scale bioelectronic interfaces. The device incorporates a multi-scale porous material architecture, an interdigitated microelectrode layout and a supercapacitor-like performance. In cell training processes, we use the device to modulate the contraction rate of primary cardiomyocytes at the subcellular level to target frequency in vitro. We also achieve capacitive control of the electrophysiology in isolated hearts, retinal tissues and sciatic nerves, as well as bioelectronic cardiac sensing. Our results support the exploration of device platforms already used in energy research to identify new opportunities in bioelectronics.
AB - Real-world bioelectronics applications, including drug delivery systems, biosensing and electrical modulation of tissues and organs, largely require biointerfaces at the macroscopic level. However, traditional macroscale bioelectronic electrodes usually exhibit invasive or power-inefficient architectures, inability to form uniform and subcellular interfaces, or faradaic reactions at electrode surfaces. Here, we develop a micelle-enabled self-assembly approach for a binder-free and carbon-based monolithic device, aimed at large-scale bioelectronic interfaces. The device incorporates a multi-scale porous material architecture, an interdigitated microelectrode layout and a supercapacitor-like performance. In cell training processes, we use the device to modulate the contraction rate of primary cardiomyocytes at the subcellular level to target frequency in vitro. We also achieve capacitive control of the electrophysiology in isolated hearts, retinal tissues and sciatic nerves, as well as bioelectronic cardiac sensing. Our results support the exploration of device platforms already used in energy research to identify new opportunities in bioelectronics.
UR - http://www.scopus.com/inward/record.url?scp=85097235804&partnerID=8YFLogxK
U2 - 10.1038/s41565-020-00805-z
DO - 10.1038/s41565-020-00805-z
M3 - Article
C2 - 33288948
AN - SCOPUS:85097235804
SN - 1748-3387
VL - 16
SP - 206
EP - 213
JO - Nature Nanotechnology
JF - Nature Nanotechnology
IS - 2
ER -