A 3D biomimetic optoelectronic scaffold repairs cranial defects.
Huachun WangJingjing TianYuxi JiangShuang LiuJingchuan ZhengNingyu LiGuiyan WangFan DongJunyu ChenYang XieYunxiang HuangXue CaiXiu-Mei WangWei XiongHui QiLan YinYuguang WangXing ShengPublished in: Science advances (2023)
Bone fractures and defects pose serious health-related issues on patients. For clinical therapeutics, synthetic scaffolds have been actively explored to promote critical-sized bone regeneration, and electrical stimulations are recognized as an effective auxiliary to facilitate the process. Here, we develop a three-dimensional (3D) biomimetic scaffold integrated with thin-film silicon (Si)-based microstructures. This Si-based hybrid scaffold not only provides a 3D hierarchical structure for guiding cell growth but also regulates cell behaviors via photo-induced electrical signals. Remotely controlled by infrared illumination, these Si structures electrically modulate membrane potentials and intracellular calcium dynamics of stem cells and potentiate cell proliferation and differentiation. In a rodent model, the Si-integrated scaffold demonstrates improved osteogenesis under optical stimulations. Such a wirelessly powered optoelectronic scaffold eliminates tethered electrical implants and fully degrades in a biological environment. The Si-based 3D scaffold combines topographical and optoelectronic stimuli for effective biological modulations, offering broad potential for biomedicine.
Keyphrases
- tissue engineering
- bone regeneration
- stem cells
- room temperature
- cell proliferation
- end stage renal disease
- high resolution
- chronic kidney disease
- mass spectrometry
- cell therapy
- prognostic factors
- ejection fraction
- bone mineral density
- cell cycle
- bone marrow
- mesenchymal stem cells
- drug induced
- reactive oxygen species
- human health
- patient reported outcomes
- pi k akt
- peritoneal dialysis
- patient reported