Cuchiara Michael P, Gould Daniel J, McHale Melissa K, Dickinson Mary E, West Jennifer L
Department of Bioengineering-MS 142 6100 Main St., Houston, TX 77005 USA.
Adv Funct Mater. 2012 Nov 7;22(21):4511-4518. doi: 10.1002/adfm.201200976.
Despite tremendous efforts, tissue engineered constructs are restricted to thin, simple tissues sustained only by diffusion. The most significant barrier in tissue engineering is insufficient vascularization to deliver nutrients and metabolites during development in vitro and to facilitate rapid vascular integration in vivo. Tissue engineered constructs can be greatly improved by developing perfusable microvascular networks in vitro in order to provide transport that mimics native vascular organization and function. Here a microfluidic hydrogel is integrated with a self-assembling pro-vasculogenic co-culture in a strategy to perfuse microvascular networks in vitro. This approach allows for control over microvascular network self-assembly and employs an anastomotic interface for integration of self-assembled micro-vascular networks with fabricated microchannels. As a result, transport within the system shifts from simple diffusion to vessel supported convective transport and extra-vessel diffusion, thus improving overall mass transport properties. This work impacts the development of perfusable prevascularized tissues in vitro and ultimately tissue engineering applications in vivo.
尽管付出了巨大努力,但组织工程构建体仍局限于仅通过扩散维持的薄而简单的组织。组织工程中最显著的障碍是血管化不足,无法在体外发育过程中输送营养物质和代谢产物,也无法促进体内快速的血管整合。通过在体外构建可灌注的微血管网络,以提供模拟天然血管组织和功能的运输方式,可以极大地改善组织工程构建体。在此,一种微流体水凝胶与一种自组装的促血管生成共培养体系相结合,旨在体外灌注微血管网络。这种方法能够控制微血管网络的自组装,并采用吻合接口将自组装的微血管网络与制造的微通道整合。结果,系统内的运输方式从简单扩散转变为血管支持的对流运输和血管外扩散,从而改善了整体传质特性。这项工作影响了体外可灌注预血管化组织的发展,并最终影响了体内组织工程应用。