An Electrical Stimulation Culture System for Daily Maintenance-Free Muscle Tissue Production

IF 10.5 Q1 ENGINEERING, BIOMEDICAL Cyborg and bionic systems (Washington, D.C.) Pub Date : 2021-04-08 DOI:10.34133/2021/9820505
Y. Akiyama, Akemi Nakayama, S. Nakano, Ryuichiro Amiya, Jun Hirose
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引用次数: 11

Abstract

Low-labor production of tissue-engineered muscles (TEMs) is one of the key technologies to realize the practical use of muscle-actuated devices. This study developed and then demonstrated the daily maintenance-free culture system equipped with both electrical stimulation and medium replacement functions. To avoid ethical issues, immortal myoblast cells C2C12 were used. The system consisting of gel culture molds, a medium replacement unit, and an electrical stimulation unit could produce 12 TEMs at one time. The contractile forces of the TEMs were measured with a newly developed microforce measurement system. Even the TEMs cultured without electrical stimulation generated forces of almost 2 mN and were shortened by 10% in tetanic contractions. Regarding the contractile forces, electrical stimulation by a single pulse at 1 Hz was most effective, and the contractile forces in tetanus were over 2.5 mN. On the other hand, continuous pulses decreased the contractile forces of TEMs. HE-stained cross-sections showed that myoblast cells proliferated and fused into myotubes mainly in the peripheral regions, and fewer cells existed in the internal region. This must be due to insufficient supplies of oxygen and nutrients inside the TEMs. By increasing the supplies, one TEM might be able to generate a force up to around 10 mN. The tetanic forces of the TEMs produced by the system were strong enough to actuate microstructures like previously reported crawling robots. This daily maintenance-free culture system which could stably produce TEMs strong enough to be utilized for microrobots should contribute to the advancement of biohybrid devices.
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用于日常无维护肌肉组织生产的电刺激培养系统
组织工程肌肉的低劳动生产率是实现肌肉驱动装置实用化的关键技术之一。本研究开发并演示了具有电刺激和培养基更换功能的日常免维护培养系统。为了避免伦理问题,使用了永生成肌细胞C2C12。由凝胶培养模具、培养基更换单元和电刺激单元组成的系统可以一次产生12个TEM。TEM的收缩力是用新开发的微力测量系统测量的。即使在没有电刺激的情况下培养的TEMs也会产生几乎2 mN,在强直性收缩时缩短10%。关于收缩力,在1 Hz是最有效的,破伤风的收缩力超过2.5 mN。另一方面,连续脉冲降低了TEM的收缩力。HE染色截面显示,成肌细胞主要在外周区域增殖并融合成肌管,而在内部区域存在较少的细胞。这一定是由于TEM内氧气和营养物质供应不足。通过增加供应,一个TEM可能能够产生高达10左右的力 mN。由该系统产生的TEM的强直力足够强,可以像以前报道的爬行机器人一样驱动微观结构。这种日常免维护的培养系统可以稳定地产生足以用于微型机器人的TEM,这将有助于生物混合装置的发展。
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CiteScore
7.70
自引率
0.00%
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0
审稿时长
21 weeks
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