Torque action of two-joint muscles in the swing period of stiff-legged gait: a forward dynamic model analysis
Stiff-legged gait, characterized by limited knee flexion during the swing period, is a common consequence of upper motor neuron injury. The purpose of this investigation was to determine whether the rectus femoris and hamstrings muscles (which act at both the hip and knee) contribute to stiff-legged...
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| Published in | Journal of biomechanics Vol. 31; no. 9; pp. 835 - 840 |
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| Main Authors | , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Elsevier Ltd
01.09.1998
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| Subjects | |
| Online Access | Get full text |
| ISSN | 0021-9290 1873-2380 |
| DOI | 10.1016/S0021-9290(98)00107-9 |
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| Abstract | Stiff-legged gait, characterized by limited knee flexion during the swing period, is a common consequence of upper motor neuron injury. The purpose of this investigation was to determine whether the rectus femoris and hamstrings muscles (which act at both the hip and knee) contribute to stiff-legged gait if active during the swing period of the gait cycle. Ten subjects with unilateral stiff-legged gait due to stroke were evaluated. Swing period free gait data were obtained. A biomechanical model of the affected limb was developed for each subject. Muscle and tendon lengths were scaled to individual subjects while constant nominal values for maximum muscle forces were used for all subjects. Torque driven forward dynamic simulations were employed to determine the sensitivity of swing period maximum knee flexion angle to changes in hip and knee torques. Combined torque and muscle driven simulations were used to access the action of specific two-joint muscles. Both hip flexion torque and knee extension torque were found to influence knee angle, but knee angle was more sensitive to changes in torque at the knee joint. The actions of the rectus femoris and long hamstrings are most marked at the knee, although their action at the hip opposes their action at the knee. Rectus femoris activity during early swing acts to limit knee flexion and contributes to stiff-legged gait. Long hamstring activity in early swing contributes to knee flexion. |
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| AbstractList | Stiff-legged gait, characterized by limited knee flexion during the swing period, is a common consequence of upper motor neuron injury. The purpose of this investigation was to determine whether the rectus femoris and hamstrings muscles (which act at both the hip and knee) contribute to stiff-legged gait if active during the swing period of the gait cycle. Ten subjects with unilateral stiff-legged gait due to stroke were evaluated. Swing period free gait data were obtained. A biomechanical model of the affected limb was developed for each subject. Muscle and tendon lengths were scaled to individual subjects while constant nominal values for maximum muscle forces were used for all subjects. Torque driven forward dynamic simulations were employed to determine the sensitivity of swing period maximum knee flexion angle to changes in hip and knee torques. Combined torque and muscle driven simulations were used to access the action of specific two-joint muscles. Both hip flexion torque and knee extension torque were found to influence knee angle, but knee angle was more sensitive to changes in torque at the knee joint. The actions of the rectus femoris and long hamstrings are most marked at the knee, although their action at the hip opposes their action at the knee. Rectus femoris activity during early swing acts to limit knee flexion and contributes to stiff-legged gait. Long hamstring activity in early swing contributes to knee flexion. Stiff-legged gait, characterized by limited knee flexion during the swing period, is a common consequence of upper motor neuron injury. The purpose of this investigation was to determine whether the rectus femoris and hamstrings muscles (which act at both the hip and knee) contribute to stiff-legged gait if active during the swing period of the gait cycle. Ten subjects with unilateral stiff-legged gait due to stroke were evaluated. Swing period free gait data were obtained. A biomechanical model of the affected limb was developed for each subject. Muscle and tendon lengths were scaled to individual subjects while constant nominal values for maximum muscle forces were used for all subjects. Torque driven forward dynamic simulations were employed to determine the sensitivity of swing period maximum knee flexion angle to changes in hip and knee torques. Combined torque and muscle driven simulations were used to access the action of specific two-joint muscles. Both hip flexion torque and knee extension torque were found to influence knee angle, but knee angle was more sensitive to changes in torque at the knee joint. The actions of the rectus femoris and long hamstrings are most marked at the knee, although their action at the hip opposes their action at the knee. Rectus femoris activity during early swing acts to limit knee flexion and contributes to stiff-legged gait. Long hamstring activity in early swing contributes to knee flexion.Stiff-legged gait, characterized by limited knee flexion during the swing period, is a common consequence of upper motor neuron injury. The purpose of this investigation was to determine whether the rectus femoris and hamstrings muscles (which act at both the hip and knee) contribute to stiff-legged gait if active during the swing period of the gait cycle. Ten subjects with unilateral stiff-legged gait due to stroke were evaluated. Swing period free gait data were obtained. A biomechanical model of the affected limb was developed for each subject. Muscle and tendon lengths were scaled to individual subjects while constant nominal values for maximum muscle forces were used for all subjects. Torque driven forward dynamic simulations were employed to determine the sensitivity of swing period maximum knee flexion angle to changes in hip and knee torques. Combined torque and muscle driven simulations were used to access the action of specific two-joint muscles. Both hip flexion torque and knee extension torque were found to influence knee angle, but knee angle was more sensitive to changes in torque at the knee joint. The actions of the rectus femoris and long hamstrings are most marked at the knee, although their action at the hip opposes their action at the knee. Rectus femoris activity during early swing acts to limit knee flexion and contributes to stiff-legged gait. Long hamstring activity in early swing contributes to knee flexion. |
| Author | Kerrigan, D.Casey Riley, Patrick O. |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/9802784$$D View this record in MEDLINE/PubMed |
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| References | Delp, Loan, Hoy, Zajac, Topp, Rosen (BIB1) 1990; 37 Ferrigno, Pedotti (BIB4) 1985; 37 Sutherland, Santi, Abel (BIB13) 1990; 10 Delp, S.L., Zajac, F.E., 1992. Force and moment-generating capacity of lower-extremity muscles before and after tendon lengthening. Clinical Orthopaedics (284), 247–259. Saunders, Inman, Eberhart (BIB12) 1953; 35 Noth (BIB9) 1991; 238 Piazza, Delp (BIB11) 1996; 29 Kerrigan, Deming, Holden (BIB5) 1996; 77 Yamaguchi, Moran, Si (BIB16) 1995; 28 Treanor (BIB14) 1969; 63 Waters, Garland, Perry, Habig, Slabaugh (BIB15) 1979; 61 Kerrigan, Gronley, Perry (BIB7) 1991; 70 Engardt, Knutsson, Jonsson, Sternhag (BIB3) 1995; 76 Kerrigan, Glenn (BIB6) 1994; 73 Perry, J., 1992. Gait Analysis: normal and pathological function. Thorofare: SLACK, Inc. Knutsson (BIB8) 1980; 7 |
| References_xml | – volume: 29 start-page: 723 year: 1996 end-page: 733 ident: BIB11 article-title: The influence of muscles on knee flexion during the swing phase of gait publication-title: Journal of Biomechanics – volume: 70 start-page: 294 year: 1991 end-page: 300 ident: BIB7 article-title: Stiff-legged gait in spastic paresis publication-title: American Journal of Physical Medicine and Rehabilitation – reference: Delp, S.L., Zajac, F.E., 1992. Force and moment-generating capacity of lower-extremity muscles before and after tendon lengthening. Clinical Orthopaedics (284), 247–259. – volume: 61 start-page: 927 year: 1979 end-page: 933 ident: BIB15 article-title: Stiff-legged gait in hemiplegia publication-title: American Journal of Bone and Joint Surgery – volume: 63 start-page: 14 year: 1969 end-page: 22 ident: BIB14 article-title: The role of physical medicine treatment in stroke rehabilitation publication-title: Clinical Orthopaedics and Related Research – volume: 7 start-page: 47 year: 1980 end-page: 52 ident: BIB8 article-title: Muscle activation patterns of gait in spastic hemiparesis, paraparesis and cerebral palsy publication-title: Scandinavian Journal of Rehabilitation Medicine – volume: 37 start-page: 943 year: 1985 end-page: 950 ident: BIB4 article-title: ELITE publication-title: IEEE Transactions of Biomedical Engineering – volume: 73 start-page: 421 year: 1994 end-page: 427 ident: BIB6 article-title: An illustration of clinical gait laboratory use to improve rehabilitation management publication-title: American Journal of Physical Medicine and Rehabilitation – volume: 28 start-page: 999 year: 1995 end-page: 1005 ident: BIB16 article-title: A computationally efficient method for solving the redundant problem in biomechanics publication-title: Journal of Biomechanics – volume: 76 start-page: 419 year: 1995 end-page: 425 ident: BIB3 article-title: Dynamic muscle strength training in stroke patients publication-title: Archieves of Physical Medicine and Rehabilitation – volume: 77 start-page: 645 year: 1996 end-page: 650 ident: BIB5 article-title: Knee recurvatum in gait publication-title: Archieves of Physical Medicine and Rehabilitation – volume: 238 start-page: 131 year: 1991 end-page: 139 ident: BIB9 article-title: Trends in the pathophysiology and pharmacotherapy of spasticity publication-title: Journal of Neurology – volume: 10 start-page: 433 year: 1990 end-page: 441 ident: BIB13 article-title: Treatment of stiff-knee gait in cerebral palsy publication-title: Journal of Pediatric Orthopaedics – volume: 37 start-page: 757 year: 1990 end-page: 767 ident: BIB1 article-title: An interactive graphics-based model of the lower extremity to study orthopaedic surgical procedures publication-title: Transactions on Biomechanical Engineering – reference: Perry, J., 1992. Gait Analysis: normal and pathological function. Thorofare: SLACK, Inc. – volume: 35 start-page: 543 year: 1953 end-page: 558 ident: BIB12 article-title: The major determinants in normal and pathological gait publication-title: American Journal of Bone and Joint Surgery |
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| SubjectTerms | Adult Aged Biomechanical Phenomena Cerebrovascular Disorders - physiopathology Computer Simulation Female Gait Hip - physiopathology Humans Joints (anatomy) Knee - physiopathology Knee Joint - physiopathology Leg - physiopathology Male Mathematical models Middle Aged Models, Biological Muscle Muscle, Skeletal - physiopathology Range of Motion, Articular Tendons Torque |
| Title | Torque action of two-joint muscles in the swing period of stiff-legged gait: a forward dynamic model analysis |
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