期刊
出版社
IEEE
DOI: 10.1109/MEMS51782.2021.9375134
关键词
Piezoelectricity; NG; ZnO; NS; microdevice; bioelectronics; cell stimulation; biomaterial
资金
- CSIC [BOE-A2007-14853]
- La Caixa Foundation [LCF/BQ/PR19/11700010]
- Spanish State Research Agency (AEI) [EUR2020-112082]
- European Union [101003407]
- Electronic Components and Systems For European Leadership Joint Undertaking (ECSEL) (EnSO) [692482]
- Grant Agency of the Czech Republic [20-01570S]
Bioelectronic medicine is gaining importance in regenerative medicine by using electrical stimulation to promote cell migration, differentiation, and proliferation for tissue regeneration. Piezoelectric nanogenerators have the potential to wirelessly stimulate cells, expanding the range of materials for biomedical applications. Microdevices integrating piezoelectric zinc oxide nanosheets on silicon microparticles have shown cytocompatibility and the ability to generate electric fields in response to mechanical stress or ultrasonic waves, paving the way for cost-effective and reproducible bioelectronic therapies.
Bioelectronic medicine is acquiring importance within the field of regenerative medicine. Several types of cells migrate, differentiate or proliferate in response to electrical stimuli, promoting tissue regeneration. Piezoelectric nanogenerators (NGs) are capable of electrically stimulate cells in a wireless way through acoustic power; broadening the scope of materials used for biomedical applications. In this work, microdevices consisting of piezoelectric zinc oxide nanosheets (ZnO NSs) integrated on silicon microparticles were synthesized. Finite element modelling (FEM) simulations demonstrate that these microdevices are able to produce electric fields (EF) in response to mechanical stresses or ultrasonic waves. In vitro testing with osteoblast Saos-2 cells proved their cytocompatibility. Soon, the use of these simple, costless and technologically reproducible microdevices may offer new ways to develop bioelectronic therapies.
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