在解释等长膝关节伸展扭矩随髋关节角度变化时，原动肌和拮抗肌的作用。

The role of agonist and antagonist muscles in explaining isometric knee extension torque variation with hip joint angle.

机构信息

Department of Medical and Sport Sciences, University of Cumbria, Bowerham road, Lancaster, LA1 3JD, UK.

School of Healthcare Science, Manchester Metropolitan University, Manchester, UK.

出版信息

Eur J Appl Physiol. 2017 Oct;117(10):2039-2045. doi: 10.1007/s00421-017-3693-y. Epub 2017 Aug 12.

DOI:10.1007/s00421-017-3693-y

PMID:28803367

Abstract

PURPOSE

The biarticular rectus femoris (RF), operating on the ascending limb of the force-length curve, produces more force at longer lengths. However, experimental studies consistently report higher knee extension torque when supine (longer RF length) compared to seated (shorter RF length). Incomplete activation in the supine position has been proposed as the reason for this discrepancy, but differences in antagonistic co-activation could also be responsible due to altered hamstrings length. We examined the role of agonist and antagonist muscles in explaining the isometric knee extension torque variation with changes in hip joint angle.

METHOD

Maximum voluntary isometric knee extension torque (joint MVC) was recorded in seated and supine positions from nine healthy males (30.2 ± 7.7 years). Antagonistic torque was estimated using EMG and added to the respective joint MVC (corrected MVC). Submaximal tetanic stimulation quadriceps torque was also recorded.

RESULT

Joint MVC was not different between supine (245 ± 71.8 Nm) and seated (241 ± 69.8 Nm) positions and neither was corrected MVC (257 ± 77.7 and 267 ± 87.0 Nm, respectively). Antagonistic torque was higher when seated (26 ± 20.4 Nm) than when supine (12 ± 7.4 Nm). Tetanic torque was higher when supine (111 ± 31.9 Nm) than when seated (99 ± 27.5 Nm).

CONCLUSION

Antagonistic co-activation differences between hip positions do not account for the reduced MVC in the supine position. Rather, reduced voluntary knee extensor muscle activation in that position is the major reason for the lower MVC torque when RF is lengthened (hip extended). These findings can assist standardising muscle function assessment and improving musculoskeletal modelling applications.

摘要

目的

双关节股直肌（RF）在力-长度曲线的上升支上运作，在较长的长度下产生更大的力。然而，实验研究一致报告仰卧位（RF 长度较长）时膝关节伸展扭矩较高，而坐位（RF 长度较短）时则较低。由于仰卧位时不完全激活，提出了这种差异的原因，但由于腘绳肌长度的改变，拮抗肌共同激活的差异也可能是原因。我们研究了在髋关节角度变化时，解释等长膝关节伸展扭矩变化的主动肌和拮抗肌的作用。

方法

从 9 名健康男性（30.2±7.7 岁）中记录了坐位和仰卧位时的最大自愿等长膝关节伸展扭矩（关节 MVC）。使用肌电图估计拮抗肌扭矩，并将其添加到各自的关节 MVC（校正 MVC）中。还记录了亚最大强直刺激股四头肌扭矩。

结果

仰卧位（245±71.8 Nm）和坐位（241±69.8 Nm）的关节 MVC 没有差异，校正 MVC 也没有差异（分别为 257±77.7 和 267±87.0 Nm）。坐位时拮抗肌扭矩较高（26±20.4 Nm），而仰卧位时较低（12±7.4 Nm）。强直扭矩在仰卧位时较高（111±31.9 Nm），而在坐位时较低（99±27.5 Nm）。

结论

髋关节位置的拮抗肌共同激活差异不能解释仰卧位时 MVC 的降低。相反，在 RF 延长（髋关节伸展）时，该位置的膝关节伸肌主动肌激活减少是 MVC 扭矩降低的主要原因。这些发现可以帮助标准化肌肉功能评估和改善肌肉骨骼建模应用。

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在解释等长膝关节伸展扭矩随髋关节角度变化时，原动肌和拮抗肌的作用。

The role of agonist and antagonist muscles in explaining isometric knee extension torque variation with hip joint angle.

机构信息

出版信息

PURPOSE

METHOD

RESULT

CONCLUSION

目的

方法

结果

结论

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