Development of Microfluidic Stretch System for Studying Recovery of Damaged Skeletal Muscle Cells.

Wanho Kim,Hyung-Soon Park,Jessie Jeon,Jaesang Kim

doi:10.3390/mi9120671

Wanho Kim, Hyung-Soon Park + Show 2 more

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https://doi.org/10.3390/mi9120671

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Abstract

The skeletal muscle occupies about 40% mass of the human body and plays a significant role in the skeletal movement control. Skeletal muscle injury also occurs often and causes pain, discomfort, and functional impairment in daily living. Clinically, most studies observed the recovery phenomenon of muscle by massage or electrical stimulation, but there are limitations on quantitatively analyzing the effects on recovery. Although additional efforts have been made within in vitro biochemical research, some questions still remain for effects of the different cell microenvironment for recovery. To overcome these limitations, we have developed a microfluidic system to investigate appropriate conditions for repairing skeletal muscle injury. First, the muscle cells were cultured in the microfluidic chip and differentiated to muscle fibers. After differentiation, we treated hydrogen peroxide and 18% axial stretch to cause chemical and physical damage to the muscle fibers. Then the damaged muscle fibers were placed under the cyclic stretch condition to allow recovery. Finally, we analyzed the damage and recovery by quantifying morphological change as well as the intensity change of intracellular fluorescent signals and showed the skeletal muscle fibers recovered better in the cyclic stretched condition. In total, our in situ generation of muscle damage and induction recovery platform may be a key system for investigating muscle recovery and rehabilitation.

Highlights

Skeletal muscle occupies most of the human body and plays a significant role in movement and maintaining the shape of the body
We have developed a stretchable microfluidic system that allows in situ generation of damage and recovery models of skeletal muscle cells
Our experiment focuses on revealing the recovery relationship between mechanical stretch and damaged muscle cells, and we make an effort to establish the platform for analyzing the stretching treatment of muscle recovery quantitatively

Summary

Introduction

Skeletal muscle occupies most of the human body and plays a significant role in movement and maintaining the shape of the body From these characteristics, skeletal muscle is frequently exposed to injury during activity, and muscle injuries are one of the most common traumas in sports [1,2]. The quiescent satellite cells in the injured area are activated and developed into proliferative myoblasts. These myoblasts are compacted in cellular space, fuse themselves and enter into the differentiation process. The repair process usually takes three weeks but may require several months for severe functional loss and structural damage This injury has a high probability to leave aftereffects. The development of effective therapy for muscle recovery is consistently demanded

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