人体小腿三头肌复合体结构的体内测量:对肌肉功能的影响。
In vivo measurements of the triceps surae complex architecture in man: implications for muscle function.
作者信息
Maganaris C N, Baltzopoulos V, Sargeant A J
机构信息
Biomechanics and Neuromuscular Biology Research Groups, Manchester Metropolitan University, Alsager ST7 2HL, UK.
出版信息
J Physiol. 1998 Oct 15;512 ( Pt 2)(Pt 2):603-14. doi: 10.1111/j.1469-7793.1998.603be.x.
Abstract
- The objectives of this study were to (1) quantify experimentally in vivo changes in pennation angle, fibre length and muscle thickness in the triceps surae complex in man in response to changes in ankle position and isometric plantarflexion moment and (2) compare changes in the above muscle architectural characteristics occurring in the transition from rest to a given isometric plantarflexion intensity with the estimations of a planimetric muscle model assuming constant thickness and straight muscle fibres. 2. The gastrocnemius medialis (GM), gastrocnemius lateralis (GL) and soleus (SOL) muscles of six males were scanned with ultrasonography at different sites along and across the muscle belly at rest and during maximum voluntary contraction (MVC) trials at ankle angles of -15 deg (dorsiflexed direction), 0 deg (neutral position), +15 deg (plantarflexed direction) and +30 deg. Additional images were taken at 80, 60, 40 and 20% of MVC at an ankle angle of 0 deg. 3. In all three muscles and all scanned sites, as ankle angle increased from -15 to +30 deg, pennation increased (by 6-12 deg, 39-67%, P < 0.01 at rest and 9-16 deg, 29-43%, P < 0.01 during MVC) and fibre length decreased (by 15-28 mm, 32-34%, P < 0.01 at rest and 8-10 mm, 27-30%, P < 0.05 during MVC). Thickness in GL and SOL increased during MVC compared with rest (by 5-7 mm, 36-47%, P < 0.01 in GL and 6-7 mm, 38-47%, P < 0.01 in SOL) while thickness of GM did not differ (P > 0.05) between rest and MVC. 4. At any given ankle angle the model underestimated changes in GL and SOL occurring in the transition from rest to MVC in pennation angle (by 9-12 deg, 24-38%, P < 0.01 in GL and 9-14 deg, 25-28%, P < 0.01 in SOL) and fibre length (by 6-15 mm, 22-39%, P < 0.01 in GL and 6-8 mm, 23-24%, P < 0.01 in SOL). 5. The findings of the study indicate that the mechanical output of muscle as estimated by the model used may be unrealistic due to errors in estimating the changes in muscle architecture during contraction compared with rest.
摘要
- 本研究的目的是:(1)通过实验定量研究人体小腿三头肌复合体在踝关节位置和等长跖屈力矩变化时,其羽状角、纤维长度和肌肉厚度在体内的变化;(2)比较从静息状态到给定等长跖屈强度过程中上述肌肉结构特征的变化,与假设肌肉厚度恒定且纤维为直线的平面肌肉模型的估计值。2. 对6名男性的内侧腓肠肌(GM)、外侧腓肠肌(GL)和比目鱼肌(SOL)在静息状态以及在踝关节角度为-15度(背屈方向)、0度(中立位)、+15度(跖屈方向)和+30度的最大自主收缩(MVC)试验期间,沿着肌腹并横跨肌腹的不同部位进行超声扫描。在踝关节角度为0度时,还在MVC的80%、60%、40%和20%时拍摄了额外的图像。3. 在所有三块肌肉以及所有扫描部位,随着踝关节角度从-15度增加到+30度,羽状角增大(静息时增大6 - 12度,39 - 67%,P < 0.01;MVC时增大9 - 16度,29 - 43%,P < 0.01),纤维长度减小(静息时减小15 - 28毫米,32 - 34%,P < 0.01;MVC时减小8 - 10毫米,27 - 30%,P < 0.05)。与静息相比,GL和SOL在MVC期间厚度增加(GL增加5 - 7毫米,36 - 47%,P < 0.01;SOL增加6 - 7毫米,38 - 47%,P < 0.01),而GM的厚度在静息和MVC之间无差异(P > 0.05)。4. 在任何给定的踝关节角度,该模型低估了从静息到MVC过程中GL和SOL在羽状角(GL低估9 - 12度,24 - 38%,P < 0.01;SOL低估9 - 14度,25 - 28%,P < 0.01)和纤维长度(GL低估6 - 15毫米,22 - 39%,P < 0.01;SOL低估6 - 8毫米,23 - 24%,P < 0.01)方面的变化。5. 该研究结果表明,与静息相比,由于在估计收缩过程中肌肉结构变化时存在误差,所使用模型估计的肌肉机械输出可能不切实际。
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