Biohybrid robot with skeletal muscle tissue covered with a collagen structure for moving in air

Biohybrid robots composed of biological and synthetic components have been introduced to reconstruct biological functions in mechanical systems and obtain better understanding of biological designs. For example, biohybrid robots powered by skeletal muscle tissue have already succeeded in performing various movements. However, it has been difficult for the conventional biohybrid robots to actuate in air, as the skeletal muscle tissue often dries out in air and is damaged. To overcome this limitation, we propose a biohybrid robot in which the skeletal muscle tissue is encapsulated in a collagen structure to maintain the required humidity conditions when operated in air. As the skeletal muscle tissue maintains high cell viability and contractility, even after encapsulation within the collagen structure, the biohybrid robot can move in air through contractions of the skeletal muscle tissue. To demonstrate the applicability of the developed biohybrid robot, we demonstrate its use in object manipulation. In addition, to prove its capability of functionality enhancement, we show that the biohybrid robot can actuate for a long term when perfusable tubes are set inside the collagen structure; it can actuate even while culturing cells on its surface. The developed biohybrid robot composed of skeletal muscle tissue and collagen structure can be employed within platforms used to replicate various motions of land animals.

[1]  Ritu Raman,et al.  Three-dimensionally printed biological machines powered by skeletal muscle , 2014, Proceedings of the National Academy of Sciences.

[2]  Jeong-Woo Choi,et al.  Phototactic guidance of a tissue-engineered soft-robotic ray , 2016, Science.

[3]  Sung-Jin Park,et al.  Instrumented cardiac microphysiological devices via multi-material 3D printing , 2016, Nature materials.

[4]  Shoji Takeuchi,et al.  Three-dimensional neuron-muscle constructs with neuromuscular junctions. , 2013, Biomaterials.

[5]  Megan L. McCain,et al.  A tissue-engineered jellyfish with biomimetic propulsion , 2012, Nature Biotechnology.

[6]  G. Whitesides,et al.  Muscular Thin Films for Building Actuators and Powering Devices , 2007, Science.

[7]  Lieven Thorrez,et al.  Drug‐screening platform based on the contractility of tissue‐engineered muscle , 2008, Muscle & nerve.

[8]  J. Paul Robinson,et al.  A novel and simple cell-based detection system with a collagen-encapsulated B-lymphocyte cell line as a biosensor for rapid detection of pathogens and toxins , 2008, Laboratory Investigation.

[9]  Adam W Feinberg,et al.  Biological Soft Robotics. , 2015, Annual review of biomedical engineering.

[10]  Takehiko Kitamori,et al.  An actuated pump on-chip powered by cultured cardiomyocytes. , 2006, Lab on a chip.

[11]  L. Kaufman,et al.  Pore size variable type I collagen gels and their interaction with glioma cells. , 2010, Biomaterials.

[12]  R. Duffy,et al.  Optimizing the structure and contractility of engineered skeletal muscle thin films. , 2013, Acta biomaterialia.

[13]  Takayuki Hoshino,et al.  Muscle-powered Cantilever for Microtweezers with an Artificial Micro Skeleton and Rat Primary Myotubes , 2010 .

[14]  Paolo Dario,et al.  Biohybrid actuators for robotics: A review of devices actuated by living cells , 2017, Science Robotics.

[15]  H. Asada,et al.  Utilization and control of bioactuators across multiple length scales. , 2014, Lab on a chip.

[16]  Sukho Park,et al.  Micro pumping with cardiomyocyte-polymer hybrid. , 2007, Lab on a chip.

[17]  Lorenzo Moroni,et al.  Biofabrication strategies for 3D in vitro models and regenerative medicine , 2018, Nature Reviews Materials.

[18]  Ritu Raman,et al.  Optogenetic skeletal muscle-powered adaptive biological machines , 2016, Proceedings of the National Academy of Sciences.

[19]  P. Zorlutuna,et al.  Development and characterization of muscle-based actuators for self-stabilizing swimming biorobots. , 2016, Lab on a chip.

[20]  Arianna Menciassi,et al.  Bio-hybrid muscle cell-based actuators , 2012, Biomedical Microdevices.

[21]  Shoji Takeuchi,et al.  Biohybrid device with antagonistic skeletal muscle tissue for measurement of contractile force , 2019, Adv. Robotics.

[22]  Shoji Takeuchi,et al.  Biohybrid robot powered by an antagonistic pair of skeletal muscle tissues , 2018, Science Robotics.

[23]  Yasunori Yamamoto,et al.  Functional evaluation of artificial skeletal muscle tissue constructs fabricated by a magnetic force-based tissue engineering technique. , 2011, Tissue engineering. Part A.

[24]  B. Williams,et al.  A self-propelled biohybrid swimmer at low Reynolds number , 2014, Nature Communications.

[25]  S. Takeuchi,et al.  Human induced pluripotent stem cell-derived fiber-shaped cardiac tissue on a chip. , 2016, Lab on a chip.

[26]  Takayuki Hoshino,et al.  Atmospheric-operable bioactuator powered by insect muscle packaged with medium. , 2013, Lab on a chip.