Parker Kevin K, Ingber Donald E
School of Engineering and Applied Sciences, Harvard University, Cambridge, MA 02138, USA.
Philos Trans R Soc Lond B Biol Sci. 2007 Aug 29;362(1484):1267-79. doi: 10.1098/rstb.2007.2114.
The spatial and temporal scales of cardiac organogenesis and pathogenesis make engineering of artificial heart tissue a daunting challenge. The temporal scales range from nanosecond conformational changes responsible for ion channel opening to fibrillation which occurs over seconds and can lead to death. Spatial scales range from nanometre pore sizes in membrane channels and gap junctions to the metre length scale of the whole cardiovascular system in a living patient. Synchrony over these scales requires a hierarchy of control mechanisms that are governed by a single common principle: integration of structure and function. To ensure that the function of ion channels and contraction of muscle cells lead to changes in heart chamber volume, an elegant choreography of metabolic, electrical and mechanical events are executed by protein networks composed of extracellular matrix, transmembrane integrin receptors and cytoskeleton which are functionally connected across all size scales. These structural control networks are mechanoresponsive, and they process mechanical and chemical signals in a massively parallel fashion, while also serving as a bidirectional circuit for information flow. This review explores how these hierarchical structural networks regulate the form and function of living cells and tissues, as well as how microfabrication techniques can be used to probe this structural control mechanism that maintains metabolic supply, electrical activation and mechanical pumping of heart muscle. Through this process, we delineate various design principles that may be useful for engineering artificial heart tissue in the future.
心脏器官发生和发病机制的时空尺度使得人工心脏组织工程成为一项艰巨的挑战。时间尺度从负责离子通道开放的纳秒级构象变化到数秒内发生且可能导致死亡的颤动。空间尺度从膜通道和缝隙连接中的纳米级孔径到活体患者整个心血管系统的米级长度尺度。这些尺度上的同步需要一系列由单一共同原则支配的控制机制:结构与功能的整合。为确保离子通道的功能和肌肉细胞的收缩导致心腔容积的变化,由细胞外基质、跨膜整合素受体和细胞骨架组成的蛋白质网络执行了代谢、电和机械事件的精妙编排,这些网络在所有大小尺度上功能相连。这些结构控制网络对机械刺激有反应,它们以大规模并行的方式处理机械和化学信号,同时还充当信息流的双向电路。本综述探讨了这些层次结构网络如何调节活细胞和组织的形态与功能,以及微制造技术如何用于探究维持心肌代谢供应、电激活和机械泵血的这种结构控制机制。通过这个过程,我们阐述了未来可能对人工心脏组织工程有用的各种设计原则。