Abstract

Piezoelectric materials implanted in vivo will be affected by physiological stress, leading to the generation of dynamic piezoelectrical signals. The cells identify both piezoelectrical and mechanical stimuli, and the way they behave is regulated through an electromechanical coupling process. Understanding the specific functions of individual stimulation on the osteogenic differentiation of mesenchymal stem cells (MSCs) would aid the development of ideal biomaterials for bone tissue engineering. In this work, by utilizing the controllable piezoelectric properties of polylactic acid materials, we prepared biomimetic piezoelectric poly (L-lactic acid) nanofibers and its non-piezoelectric isomer poly (D, l-lactide) nanofibers using the electrospinning technology. The dynamic piezoelectric and mechanical stimuli on the nanofibers were theoretically and experimentally investigated. A home-made in-situ mechanical loading platform was used to apply predetermined tensile loading on the nanofibers under cell culture conditions. The results indicated that piezo-potential ranging from 11 to 103 μV could be produced by cell adhesion forces varied between 1 and 15 nN, while mechanical loading ranging from 1 % to 15 % strain resulted in piezoelectrical signals in the magnitude of several volts. These piezoelectric signals could influence cell adhesion through enhancing cell aspect ratio and cell area. During the process of cell contraction and re-spreading caused by the mechanical loading, the piezoelectric signals were capable of accelerating the recovery of spreading and adhesion. Furthermore, individual piezoelectric and mechanical signals could modulate intracellular calcium signals, and significantly promote osteogenic differentiation of MSCs. Specifically, the mechanical stimulation could activate PIEZO signaling pathway, resulting in a greater upregulation of early osteogenic differentiation markers of Collagen type I and Bone morphogenetic protein-2 compared to the piezoelectric signal. However, the combination of the two stimuli could obviously and effectively enhance osteogenic differentiation of MSCs in a synergistic manner. These findings offer fresh understandings regarding the electromechanical influences in the process of bone tissue regeneration, which afford additional possibilities for optimizing piezoelectric biomaterials for biomedical applications in a more reasonable manner.

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