光遗传学
葡萄糖稳态
能量稳态
平衡
胰岛素
神经科学
生物
细胞生物学
医学
胰岛素抵抗
内科学
受体
作者
Zhuo Liu,Yang Zhou,Xuecheng Qu,Lingling Xu,Yang Zou,Yizhu Shan,Jiawei Shao,Chan Wang,Ying Liu,Jiangtao Xue,Dongjie Jiang,Yubo Fan,Zhou Li,Haifeng Ye
出处
期刊:Research
[AAAS00]
日期:2022-01-01
卷期号:2022
被引量:13
标识
DOI:10.34133/2022/9864734
摘要
Diabetes treatment and rehabilitation are usually a lifetime process. Optogenetic engineered designer cell-therapy holds great promise in regulating blood glucose homeostasis. However, portable, sustainable, and long-term energy supplementation has previously presented a challenge for the use of optogenetic stimulation in vivo. Herein, we purpose a self-powered optogenetic system (SOS) for implantable blood glucose control. The SOS consists of a biocompatible far-red light (FRL) source, FRL-triggered transgene-expressing cells, a power management unit, and a flexible implantable piezoelectric nanogenerator (i-PENG) to supply long-term energy by converting biomechanical energy into electricity. Our results show that this system can harvest energy from body movement and power the FRL source, which then significantly enhanced production of a short variant of human glucagon-like peptide 1 (shGLP-1) in vitro and in vivo. Indeed, diabetic mice equipped with the SOS showed rapid restoration of blood glucose homeostasis, improved glucose, and insulin tolerance. Our results suggest that the SOS is sufficiently effective in self-powering the modulation of therapeutic outputs to control glucose homeostasis and, furthermore, present a new strategy for providing energy in optogenetic-based cell therapy.
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