Effect of pre-activation force on active force generation in skeletal muscle

IF 2.4 3区医学 Q3 BIOPHYSICS

Journal of biomechanics Pub Date : 2025-05-06 DOI:10.1016/j.jbiomech.2025.112744

Eng Kuan Moo , Venus Joumaa , Walter Herzog

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引用次数: 0

Abstract

Cross bridges play a central role in skeletal muscle force generation. The level of force per cross bridge and the number of attached cross bridges are thought to determine muscle performance. Recent studies propose the so-called myosin-activation hypothesis, which suggests that stress exerted on myosin filaments increases the number of attached cross bridges and, hence, active force. This study was aimed at investigating the influence of passive stress magnitude exerted at the onset of activation on active force in a whole muscle preparation. The tibialis anterior (TA) muscle–tendon unit (MTU) of mice (N = 8) was stretched uniaxially in situ to long lengths where substantial viscoelastic passive force relaxation occurs. Muscle stress upon activation was varied by activating the TA either immediately at the end of the passive stretch (high passive force), or following nearly complete passive force relaxation (low passive force). Total forces with and without activation were measured from every MTU. Active forces were calculated by subtracting the passive force relaxation curve from the total force measured over a 1.13-s activation. We found that active force generated by the TA at low passive stress was 5–13 % higher than that at high passive stress. While the results seem contradictory to the myosin-activation hypothesis, we speculate that the results arose either from length adjustments between muscle and tendon during passive force relaxation, from excessive lattice spacing compression, or from unfavourable alterations of myosin conformation by high passive stress. Further research is required to improve our understanding of active force generation under the influence of viscoelasticity of muscle and tendon.

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预激活力对骨骼肌产生主动力的影响

交叉桥在骨骼肌力量生成中起着核心作用。每个十字桥的受力水平和连接的十字桥的数量被认为决定了肌肉的表现。最近的研究提出了所谓的肌球蛋白活化假说，该假说认为施加在肌球蛋白丝上的应力增加了连接的过桥的数量，从而增加了活性。本研究旨在探讨在全肌准备过程中，激活开始时施加的被动应力大小对主动力的影响。将小鼠（N = 8）的胫骨前肌（TA）肌腱单元（MTU）原位单轴拉伸至较长时间，发生大量粘弹性被动力松弛。激活后的肌肉应力通过在被动拉伸结束时立即激活TA（高被动力）或在几乎完全的被动力放松（低被动力）之后激活TA来改变。在激活和未激活的情况下，测量每个MTU的总作用力。通过从1.13-s激活期间测量的总力中减去被动力松弛曲线来计算主动力。研究发现，在低被动应力下，TA产生的主动力比在高被动应力下高5 - 13%。虽然结果似乎与肌球蛋白激活假说相矛盾，但我们推测，结果可能是由于被动力松弛期间肌肉和肌腱之间的长度调整、过度的晶格间距压缩或高被动应力对肌球蛋白构象的不利改变引起的。需要进一步的研究来提高我们对肌肉和肌腱粘弹性影响下的主动力产生的理解。

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

Journal of biomechanics 生物-工程：生物医学

CiteScore

5.10

自引率

4.20%

发文量

345

审稿时长

1 months

期刊介绍： The Journal of Biomechanics publishes reports of original and substantial findings using the principles of mechanics to explore biological problems. Analytical, as well as experimental papers may be submitted, and the journal accepts original articles, surveys and perspective articles (usually by Editorial invitation only), book reviews and letters to the Editor. The criteria for acceptance of manuscripts include excellence, novelty, significance, clarity, conciseness and interest to the readership. Papers published in the journal may cover a wide range of topics in biomechanics, including, but not limited to: -Fundamental Topics - Biomechanics of the musculoskeletal, cardiovascular, and respiratory systems, mechanics of hard and soft tissues, biofluid mechanics, mechanics of prostheses and implant-tissue interfaces, mechanics of cells. -Cardiovascular and Respiratory Biomechanics - Mechanics of blood-flow, air-flow, mechanics of the soft tissues, flow-tissue or flow-prosthesis interactions. -Cell Biomechanics - Biomechanic analyses of cells, membranes and sub-cellular structures; the relationship of the mechanical environment to cell and tissue response. -Dental Biomechanics - Design and analysis of dental tissues and prostheses, mechanics of chewing. -Functional Tissue Engineering - The role of biomechanical factors in engineered tissue replacements and regenerative medicine. -Injury Biomechanics - Mechanics of impact and trauma, dynamics of man-machine interaction. -Molecular Biomechanics - Mechanical analyses of biomolecules. -Orthopedic Biomechanics - Mechanics of fracture and fracture fixation, mechanics of implants and implant fixation, mechanics of bones and joints, wear of natural and artificial joints. -Rehabilitation Biomechanics - Analyses of gait, mechanics of prosthetics and orthotics. -Sports Biomechanics - Mechanical analyses of sports performance.