Excitability of skeletal muscle during development, denervation, and tissue culture.

Robert G Dennis, Douglas E Dow
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引用次数: 36

Abstract

A quantitative understanding of the bulk excitability of skeletal muscle tissues is important for the design of muscle tissue bioreactor systems, implantable muscle stimulators, and other systems where electrical pulses are employed to elicit contractions in muscle tissue both in vitro and in vivo. The purpose of the present study is to systematically compare the excitability of mammalian (rat) skeletal muscle under a range of conditions (including neonatal development, denervation, and chronic in vivo stimulation of denervated muscle) and of self-organized muscle tissue constructs engineered in vitro from both primary cells and cell lines. Excitability is represented by rheobase (R(50), units = V/mm) and chronaxie (C(50), units = microseconds) values, with lower values for each indicating greater excitability. Adult skeletal muscle is the most excitable (R(50) ~ 0.29, C(50) ~ 100); chronically denervated whole muscles (R(50) ~ 2.54, C(50) ~ 690) and muscle engineered in vitro from cell lines (C2C12 + 10T1/2) (R(50) ~ 1.93, C(50) ~ 416) have exceptionally low excitability; muscle engineered in vitro from primary myocytes (R(50) ~ 0.99, C(50) ~ 496) has excitability similar to that of day 14 neonatal rat muscle (R(50) ~ 0.65, C(50) ~ 435); stimulated-denervated muscles retain excellent excitability when chronically electrically stimulated (R(50) ~ 0.40, C(50) ~ 100); and neonatal rat muscle excitability improves during the first 6 weeks of development, steadily approaching that of adult muscle.

骨骼肌在发育、去神经支配和组织培养过程中的兴奋性。
定量了解骨骼肌组织的整体兴奋性对于肌肉组织生物反应器系统、植入式肌肉刺激器和其他利用电脉冲在体外和体内引起肌肉组织收缩的系统的设计非常重要。本研究的目的是系统地比较哺乳动物(大鼠)骨骼肌在一系列条件下的兴奋性(包括新生儿发育、去神经支配和去神经支配肌肉的慢性体内刺激),以及在体外由原代细胞和细胞系设计的自组织肌肉组织结构。兴奋性由流变基(R(50),单位= V/mm)和时轴(C(50),单位=微秒)值表示,值越低,兴奋性越强。成人骨骼肌最易兴奋(R(50) ~ 0.29, C(50) ~ 100);慢性失神经全肌(R(50) ~ 2.54, C(50) ~ 690)和体外细胞工程肌肉(C2C12 + 10T1/2) (R(50) ~ 1.93, C(50) ~ 416)的兴奋性异常低;原代肌细胞体外工程肌肉(R(50) ~ 0.99, C(50) ~ 496)具有与第14天新生大鼠肌肉(R(50) ~ 0.65, C(50) ~ 435)相似的兴奋性;在长期电刺激下,受刺激的去神经肌肉保持良好的兴奋性(R(50) ~ 0.40, C(50) ~ 100);新生大鼠肌肉兴奋性在发育的前6周有所改善,逐渐接近成年大鼠肌肉兴奋性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Tissue engineering
Tissue engineering CELL & TISSUE ENGINEERING-BIOTECHNOLOGY & APPLIED MICROBIOLOGY
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