Photoelectric-Responsive Extracellular Matrix for Bone Engineering
Jieni Fu, Xiangmei Liu, Lei Tan, Zhenduo Cui, Yufeng Zheng, Yanqin Liang, Zhaoyang Li, Shengli Zhu, Kelvin Wai Kwok Yeung, Xiaobo Feng, Xianbao Wang, Shuilin Wu
Journal:ACS Nano
IF:13.9
DOI:10.1021/acsnano.9b08115
PMID:31697055
Published:2019-11-07
research field:细胞生物学生物医学工程组织工程光遗传学
Abstract
Using noninvasive stimulation of cells to control cell fate and improve bone regeneration by optical stimulation can achieve the aim of precisely orchestrating biological activities. In this study, we create a fast and repeatable photoelectric-responsive microenvironment around an implant using a bismuth sulfide/hydroxyapatite (BS/HAp) film. The unexpected increase of photocurrent on the BS/HAp film under near-infrared (NIR) light is mainly due to the depletion of holes through PO43– from HAp and interfacial charge transfer by HAp compared with BS. The electrons activate the Na+ channel of mesenchymal stem cells (MSCs) and change the cell adhesion in the intermediate environment. The behavior of MSCs is tuned by changing the photoelectronic microenvironment. RNA sequencing reveals that when photoelectrons transfer to the cell membrane, sodium ions flux and the membrane potential depolarizes to change the cell shape. Meanwhile, calcium ions fluxed and FDE1 was upregulated. Furthermore, the TCF/LEF in the cell nucleus began transcription to regulate the downstream genes involved in osteogenic differentiation, which is performed through the Wnt/Ca2+ signaling pathway. This research has created a biological therapeutic strategy, which can achieve in vitro remotely, precisely, and noninvasively controlling cell differentiation behaviors by tuning the in vivo photoelectric microenvironment using NIR light.
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