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相关概念视频

Excitation-Contraction Coupling in Skeletal Muscles01:20

Excitation-Contraction Coupling in Skeletal Muscles

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Excitation-contraction coupling is a series of events that occur between generating an action potential and initiating a muscle contraction. It occurs at the triad, a structure found in skeletal muscle fibers that comprise a T-tubule and terminal cisternae of the sarcoplasmic reticulum on each side. These triads are visible in longitudinally sectioned muscle fibers. They are typically located at the A-I junction — the junction between the A and I bands of the sarcomere.
When an action...
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Muscle Coordination and Action01:24

Muscle Coordination and Action

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Muscle coordination is a complex and finely tuned process essential for smooth and purposeful movements like flexion, extension, adduction, abduction, and rotation. The human body orchestrates the actions of various muscles working in concert, each with a specific role. Four functional types describe how muscles work together: agonist, antagonist, synergist, and fixator.
Agonists
Agonist muscles, often called prime movers, are the primary muscles responsible for producing a specific movement....
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The Muscular System01:18

The Muscular System

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The muscular system is essential to the body's overall structure and function, playing a crucial role in movement, stability, and internal processes. It consists of three distinct types of muscle tissue: the skeletal, the smooth, and the cardiac muscles.
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Actin and Myosin in Muscle Contraction01:16

Actin and Myosin in Muscle Contraction

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Actin and myosin are contractile proteins that form the sarcomere found in skeletal muscle tissues for regulating muscle contraction. Actin, a globular contractile protein, interacts with myosin for muscle contraction. The skeletal tissue appears striped or striated under a microscope due to the repeated arrangement of contractile proteins actin and myosin along the length of myofibrils. Dark A bands and light I bands repeat along myofibrils, and the alignment of myofibrils in the cell causes...
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Cross-bridge Cycle01:26

Cross-bridge Cycle

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As muscle contracts, the overlap between the thin and thick filaments increases, decreasing the length of the sarcomere—the contractile unit of the muscle—using energy in the form of ATP. At the molecular level, this is a cyclic, multistep process that involves binding and hydrolysis of ATP, and movement of actin by myosin.
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Overview of Skeletal Muscle01:15

Overview of Skeletal Muscle

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Skeletal muscles are composed of a bundle of muscle fibers and are attached to bones through tendons. Each skeletal muscle fiber is a single muscle cell. The sarcolemma, the plasma membrane of a skeletal muscle cell, consists of a lipid bilayer and glycocalyx that supports muscle fibers. The sarcolemma extends into the muscle cells to form tubular structures called transverse or T-tubules. Each side of the T-tubules consists of a membrane-bound structure called the sarcoplasmic reticulum,...
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相关实验视频

Updated: Sep 13, 2025

Subject-specific Musculoskeletal Model for Studying Bone Strain During Dynamic Motion
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Subject-specific Musculoskeletal Model for Studying Bone Strain During Dynamic Motion

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骨肌相互作用 骨肌相互作用

Hiroshi Kaji1

  • 1Department of Physiology and Regenerative Medicine, Kindai University Faculty of Medicine, Osaka, Japan.

Osteoporosis and sarcopenia
|July 28, 2025
PubMed
概括
此摘要是机器生成的。

骨和骨肌肉密切相互作用,相互影响.

关键词:
骨头 骨头 骨头 骨头肌肉 肌肉 肌肉 肌肉这就是Myokine.骨质基因 (osteokine) 是一种骨质基因.萨尔科佩尼亚是什么意思 萨尔科佩尼亚

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Author Spotlight: Bridging the Gap Between In Vivo and Ex Vivo Studies with the "Avatar" Technique to Advance Muscle Mechanics Research
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Myo-mechanical Analysis of Isolated Skeletal Muscle
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Myo-mechanical Analysis of Isolated Skeletal Muscle

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相关实验视频

Last Updated: Sep 13, 2025

Subject-specific Musculoskeletal Model for Studying Bone Strain During Dynamic Motion
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Subject-specific Musculoskeletal Model for Studying Bone Strain During Dynamic Motion

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Myo-mechanical Analysis of Isolated Skeletal Muscle
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Myo-mechanical Analysis of Isolated Skeletal Muscle

Published on: February 22, 2011

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科学领域:

  • 生物医学科学 生物医学科学
  • 肌肉骨研究 研究
  • 细胞生物学 细胞生物学

背景情况:

  • 骨和骨肌是通过机械相互作用协调运动功能的解剖学上相邻的器官.
  • 这两种组织都源于共同的中细胞干细胞,突出显示了共同的发育途径.
  • 肌肉组织在骨修复中发挥作用,共同的因素影响着这两个器官,导致诸如肉症和骨质疏松症等疾病.

研究的目的:

  • 审查有关骨和骨肌肉之间的相互作用的科学文献.
  • 探索分子机制,包括骨基因,骨基因和细胞外囊泡,参与骨肌沟通.
  • 讨论了解骨肌相互作用对治疗肉症和骨质疏松症的临床影响.

主要方法:

  • 在过去的15年里,对骨肌相互作用的研究进行文献综述.
  • 分析研究的分析,研究肌,骨和细胞外囊泡的作用.
  • 检查临床证据,将肉类和骨质疏松症联系在一起.

主要成果:

  • 临床证据证实了缩症和骨质疏松症之间存在显著的关系.
  • 肌基因和骨基因是骨肌交叉声的关键调解者.
  • 细胞外囊泡在这种相互作用中涉及作为潜在的信号代理.

结论:

  • 骨和骨肌肉表现出复杂的相互作用,对运动功能和整体健康至关重要.
  • 了解这些相互作用,特别是信号分子和囊泡的作用,对于开发治疗方法至关重要.
  • 对骨肌交叉的进一步研究有望为治疗治疗和骨质疏松症的治疗策略提供希望.