Lim Han L, Chuang Jessica C, Tran Tuan, Aung Aereas, Arya Gaurav, Varghese Shyni
Department of Bioengineering University of California San Diego, 9500 Gilman Drive, MC-0442, La Jolla, CA 92093, USA.
Adv Funct Mater. 2011 Jan 7;21(1). doi: 10.1002/adfm.201001519.
Hydrogels have numerous biomedical applications including synthetic matrices for cell culture and tissue engineering. Here we report the development of hydrogel based multifunctional matrices that not only provide three-dimensional structural support to the embedded cells but also can simultaneously provide potentially beneficial dynamic mechanical and electrical cues to the cells. A unique aspect of these matrices is that they undergo reversible, anisotropic bending dynamics in an electric field. The direction and magnitude of this bending can be tuned through the hydrogel crosslink density while maintaining the same electric potential gradient, allowing control over the mechanical strain imparted to the cells in a three-dimensional environment. The conceptual design of these hydrogels was motivated through theoretical modeling of the osmotic pressure changes occurring at the gel-solution interfaces in an electric field. These electro-mechanical matrices support survival, proliferation, and differentiation of stem cells. Thus, these new three-dimensional in vitro synthetic matrices, which mimic multiple aspects of the native cellular environment, take us one step closer to in vivo systems.
水凝胶有众多生物医学应用,包括用于细胞培养和组织工程的合成基质。在此,我们报告了基于水凝胶的多功能基质的开发,这些基质不仅为包埋的细胞提供三维结构支持,还能同时为细胞提供潜在有益的动态机械和电学信号。这些基质的一个独特之处在于它们在电场中会经历可逆的各向异性弯曲动力学。在保持相同电势梯度的情况下,这种弯曲的方向和幅度可通过水凝胶交联密度进行调节,从而能够控制在三维环境中施加给细胞的机械应变。这些水凝胶的概念设计是通过对电场中凝胶 - 溶液界面处渗透压变化的理论建模激发而来的。这些机电基质支持干细胞的存活、增殖和分化。因此,这些模拟天然细胞环境多个方面的新型三维体外合成基质使我们离体内系统又近了一步。