Ultrasoft electronics to monitor dynamically pulsing cardiomyocytes

纳米网 数码产品 材料科学 纳米技术 弹性体 生物电子学 诱导多能干细胞 光电子学 电气工程 化学 石墨烯 复合材料 生物传感器 基因 工程类 胚胎干细胞 生物化学
作者
Sunghoon Lee,Daisuke Sasaki,Dongmin Kim,Mami Mori,Tomoyuki Yokota,Hyunjae Lee,Sungjun Park,Kenjiro Fukuda,Masaki Sekino,Katsuhisa Matsuura,Tatsuya Shimizu,Takao Someya
出处
期刊:Nature Nanotechnology [Nature Portfolio]
卷期号:14 (2): 156-160 被引量:267
标识
DOI:10.1038/s41565-018-0331-8
摘要

In biointegrated electronics, the facile control of mechanical properties such as softness and stretchability in electronic devices is necessary to minimize the perturbation of motions inherent in biological systems1–5. For in vitro studies, multielectrode-embedded dishes6–8 and other rigid devices9–12 have been widely used. Soft or flexible electronics on plastic or elastomeric substrates13–15 offer promising new advantages such as decreasing physical stress16–18 and/or applying mechanical stimuli19,20. Recently, owing to the introduction of macroporous plastic substrates with nanofibre scaffolds21,22, three-dimensional electrophysiological mapping of cardiomyocytes has been demonstrated. However, quantitatively monitoring cells that exhibit significant dynamical motions via electric probes over a long period without affecting their natural motion remains a challenge. Here, we present ultrasoft electronics with nanomeshes that monitor the field potential of human induced pluripotent stem cell-derived cardiomyocytes on a hydrogel, while enabling them to move dynamically without interference. Owing to the extraordinary softness of the nanomeshes, nanomesh-attached cardiomyocytes exhibit contraction and relaxation motions comparable to that of cardiomyocytes without attached nanomeshes. Our multilayered nanomesh devices maintain reliable operations in a liquid environment, enabling the recording of field potentials of the cardiomyocytes over a period of 96 h without significant degradation of the nanomesh devices or damage of the cardiomyocytes. Ultrasoft nanomesh electronics enable monitoring of the field potential of cardiomyocytes without interference with their natural motion.
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