Ricotti Leonardo, Trimmer Barry, Feinberg Adam W, Raman Ritu, Parker Kevin K, Bashir Rashid, Sitti Metin, Martel Sylvain, Dario Paolo, Menciassi Arianna
The BioRobotics Institute, Scuola Superiore Sant'Anna, Pontedera, Pisa, Italy.
Department of Biology, Tufts University, Medford, MA 02153, USA.
Sci Robot. 2017 Nov 29;2(12). doi: 10.1126/scirobotics.aaq0495.
Actuation is essential for artificial machines to interact with their surrounding environment and to accomplish the functions for which they are designed. Over the past few decades, there has been considerable progress in developing new actuation technologies. However, controlled motion still represents a considerable bottleneck for many applications and hampers the development of advanced robots, especially at small length scales. Nature has solved this problem using molecular motors that, through living cells, are assembled into multiscale ensembles with integrated control systems. These systems can scale force production from piconewtons up to kilonewtons. By leveraging the performance of living cells and tissues and directly interfacing them with artificial components, it should be possible to exploit the intricacy and metabolic efficiency of biological actuation within artificial machines. We provide a survey of important advances in this biohybrid actuation paradigm.
驱动对于人造机器与周围环境进行交互并完成其设计功能至关重要。在过去几十年中,新型驱动技术的开发取得了显著进展。然而,对于许多应用而言,可控运动仍然是一个相当大的瓶颈,阻碍了先进机器人的发展,尤其是在小长度尺度上。自然界利用分子马达解决了这个问题,这些分子马达通过活细胞组装成具有集成控制系统的多尺度集合体。这些系统可以将力的产生从皮牛顿扩展到千牛顿。通过利用活细胞和组织的性能并将它们直接与人造部件连接,应该有可能在人造机器中利用生物驱动的复杂性和代谢效率。我们对这种生物混合驱动范式的重要进展进行了综述。