Muscle contributions to support and progression during single-limb stance in crouch gait

Steele, Katherine M.; Seth, Ajay; Hicks, Jennifer L.; Schwartz, Michael S.; Delp, Scott L.

Affiliations

¹Departments of Mechanical Engineering, Clark Center, Room S-349, Stanford University, Mail Code 5450, 318 Campus Drive, Stanford, CA 94305-5450, United States

²Bioengineering, Stanford University, United States

³Gage Center for Gait and Movement Analysis, The Gillette Children’s Specialty Healthcare, United States

⁴Orthopaedic Surgery and Biomedical Engineering, University of Minnesota, United States

Abstract and keywords

Pathological movement patterns like crouch gait are characterized by abnormal kinematics and muscle activations that alter how muscles support the body weight during walking. Individual muscles are often the target of interventions to improve crouch gait, yet the roles of individual muscles during crouch gait remain unknown. The goal of this study was to examine how muscles contribute to mass center accelerations and joint angular accelerations during single-limb stance in crouch gait, and compare these contributions to unimpaired gait. Subject-specific dynamic simulations were created for ten children who walked in a mild crouch gait and had no previous surgeries. The simulations were analyzed to determine the acceleration of the mass center and angular accelerations of the hip, knee, and ankle generated by individual muscles. The results of this analysis indicate that children walking in crouch gait have less passive skeletal support of body weight and utilize substantially higher muscle forces to walk than unimpaired individuals. Crouch gait relies on the same muscles as unimpaired gait to accelerate the mass center upward, including the soleus, vasti, gastrocnemius, gluteus medius, rectus femoris, and gluteus maximus. However, during crouch gait, these muscles are active throughout single-limb stance, in contrast to the modulation of muscle forces seen during single-limb stance in an unimpaired gait. Subjects walking in crouch gait rely more on proximal muscles, including the gluteus medius and hamstrings, to accelerate the mass center forward during single-limb stance than subjects with an unimpaired gait.

Keywords: Cerebral palsy; Walking; Dynamic simulation; Crouch gait; Induced acceleration

Links

DOI: 10.1016/j.jbiomech.2010.04.003

PubMed: 20493489

WoS: 000281534000008

History

Accepted: 2010-04-7

Cited Works (14)

Year	Entry
1991	Davis RB III, Õunpuu S, Tyburski D, Gage JR. A gait analysis data collection and reduction technique. Hum Mov Sci. October 1991;10(5):575-587.
2007	Delp SL, Anderson FC, Arnold AS, Loan P, Habib A, John CT, Guendelman E, Thelen DG. OpenSim: open-source software to create and analyze dynamic simulations of movement. IEEE Trans Biomed Eng. November 2007;54(11):1940-1950.
2006	Liu MQ, Anderson FC, Pandy MG, Delp SL. Muscles that support the body also modulate forward progression during walking. J Biomech. 2006;39(14):2623-2630.
2001	Neptune RR, Kautz SA, Zajac FE. Contributions of the individual ankle plantar flexors to support, forward progression and swing initiation during walking. J Biomech. November 2001;34(11):1387-1398.
2008	Hicks JL, Schwartz MH, Arnold AS, Delp SL. Crouched postures reduce the capacity of muscles to extend the hip and knee during the single-limb stance phase of gait. J Biomech. 2008;41(5):960-967.
2005	Arnold AS, Anderson FC, Pandy MG, Delp SL. Muscular contributions to hip and knee extension during the single limb stance phase of normal gait: a framework for investigating the causes of crouch gait. J Biomech. November 2005;38(11):2181-2189.
1999	Waters RL, Mulroy S. The energy expenditure of normal and pathologic gait. Gait Post. July 1999;9(3):207-231.
2008	Liu MQ, Anderson FC, Schwartz MH, Delp SL. Muscle contributions to support and progression over a range of walking speeds. J Biomech. November 14, 2008;41(15):3243-3252.
1990	Delp SL, Loan JP, Hoy MG, Zajac FE, Topp EL, Rosen JM. An interactive graphics-based model of the lower extremity to study orthopaedic surgical procedures. IEEE Trans Biomed Eng. 1990;37(8):757-767.
2003	Anderson FC, Pandy MG. Individual muscle contributions to support in normal walking. Gait Post. April 2003;17(2):159-169.
2004	Goldberg SR, Anderson FC, Pandy MG, Delp SL. Muscles that influence knee flexion velocity in double support: implications for stiff-knee gait. J Biomech. August 2004;37(8):1189-1196.
1999	Anderson FC, Pandy MG. A dynamic optimization solution for vertical jumping in three dimensions. Comput Methods Biomech Biomed Eng. 1999;2(3):201-231.
2006	Thelen DG, Anderson FC. Using computed muscle control to generate forward dynamic simulations of human walking from experimental data. J Biomech. 2006;39(6):1107-1115.
2003	Thelen DG, Anderson FC, Delp SL. Generating dynamic simulations of movement using computed muscle control. J Biomech. March 2003;36(3):321-328.

Cited By (31)

Year	Entry
2012	Steele KM, DeMers MS, Schwartz MH, Delp SL. Compressive tibiofemoral force during crouch gait. Gait Post. April 2012;35(4):556-560.
2013	Thompson JA, Chaudhari AMW, Schmitt LC, Best TM, Siston RA. Gluteus maximus and soleus compensate for simulated quadriceps atrophy and activation failure during walking. J Biomech. September 3, 2013;46(13):2165-2172.
2023	Kim HK, Lu S-H, Lu T-W, Chou L-S. Contribution of lower extremity muscles to center of mass acceleration during walking: effect of body weight. J Biomech. January 2023;146:111398.
2013	Millard M, Uchida T, Seth A, Delp SL. Flexing computational muscle: modeling and simulation of musculotendon dynamics. J Biomech Eng. February 2013;135(2):021005.
2018	Seth A, Hicks JL, Uchida TK, Habib A, Dembia CL, Dunne JJ, Ong CF, DeMers MS, Rajagopal A, Millard M, Hamner SR, Arnold EM, Yong JR, Lakshmikanth SK, Sherman MA, Ku JP, Delp SL. OpenSim: simulating musculoskeletal dynamics and neuromuscular control to study human and animal movement. PLoS Comput Biol. July 2018;14(7):e1006223.
2019	Beaucage-Gauvreau E. Brace for it: Assessing Lumbar Spinal Loads for a Braced Arm-to-Thigh Lifting and Bending Technique Using a Musculoskeletal Modelling Approach [PhD thesis]. University of Adelaide; June 2019.
2015	Hegarty AK. The Effects of Physical Therapy on Individual Muscle Force Production and Function in Children With Cerebral Palsy [Master's thesis]. Colorado School of Mines; 2015.
2016	Pickle NT. Dynamic Balance and Muscle Function in Individuals With and Without Unilateral Transtibial Amputation During Sloped Walking [PhD thesis]. Colorado School of Mines; 2016.
2018	Hegarty AK. Biomechanical Modeling of Gait in Children With Cerebral Palsy [PhD thesis]. Colorado School of Mines; 2018.
2013	Thompson JA. The Effect of Quadriceps Weakness on Lower Extremity Muscle Function During Gait [PhD thesis]. The Ohio State University; 2013.
2017	Caruthers EJ. Investigating Lower Limb Muscle Function During the Sit to Stand Transfer and Stair Climbing [PhD thesis]. The Ohio State University; 2017.
2017	Schloemer SA. Differences in Lower Extremity Muscle Function and Coordination During Gait Between Older and Young Adults [PhD thesis]. The Ohio State University; 2017.
2019	Iturralde PA. Mathematical Characterization of Sensory Inputs and the Adaptation of Motor Outputs in Split-Belt Walking [PhD thesis]. University of Pittsburgh; 2019.
2011	Hast MW. Assessment of Total Knee Replacement Performance Using Muscle-Driven Dynamic Simulations [PhD thesis]. State College, PA: Pennsylvania State University; August 2011.
2010	Hicks JL. Biomechanical Guidelines for the Treatment of Crouch Gait in Children With Cerebral Palsy [PhD thesis]. Stanford University; November 2010.
2012	Arnold EM. Computer Modeling of Human Lower Limb Muscles to Study How Muscle Fiber Lengths and Velocities Affect Muscle Force Generation During Walking and Running [PhD thesis]. Stanford University; July 2012.
2012	Hamner SR. Muscle Contributions to Propulsion and Support Over a Range of Running Speeds [PhD thesis]. Stanford University; August 2012.
2012	John CT. Stabilization of Human Walking by Muscles Revealed Using Three-Dimensional Muscle-Driven Simulations [PhD thesis]. Stanford University; March 2012.
2012	Steele KM. The Dynamics of Crouch Gait in Cerebral Palsy [PhD thesis]. Stanford University; July 2012.
2015	DeMers MS. Computer Modeling of Muscle Coordination Strategies That Decrease Joint Loads [PhD thesis]. Stanford University; December 2015.
2019	Ong CF. Musculoskeletal Simulation and Optimization for Predicting Human Movement [PhD thesis]. Stanford University; June 2019.
2020	Uhlrich SD. Gait Modifications for Knee Osteoarthritis: Design, Evaluation, and Clinical Translation [PhD thesis]. Stanford University; August 2020.
2012	Gopalakrishnan A. Formulating Optimization Based Musculoskeletal Simulation Approaches: Utility in Subject Assessment and Rehabilitation [PhD thesis]. University of Delaware; 2012.
2014	Ramsay JW. Muscle Morphological Changes, Compensatory Strategies and the Use of Predictive Simulations to Direct the Rehabilitation of Individuals Post-Stroke [PhD thesis]. University of Delaware; 2014.
2017	Ries AJ. Evaluating and Improving the Efficacy of Ankle Foot Orthoses for Children With Cerebral Palsy [PhD thesis]. University of Minnesota; January 2017.
2014	Handsfield GG. MRI and Computational Modeling of in Vivo Muscle-Tendon Architecture and Function [PhD thesis]. Charlottesville, VA: University of Virginia; December 2014.
2018	Terrell E. In Vivo Determination of the Physiological and Functional Properties of Muscle Using Multiscale Measurements of Muscle Architecture [Master's thesis]. Charlottesville, VA: University of Virginia; May 2018.
2016	Choi H. Evaluation of Gait and Muscle Function With Ankle Foot Orthoses [PhD thesis]. University of Washington; 2016.
2019	Shuman BR. Evaluation of Muscle Synergies in Individuals With Cerebral Palsy [PhD thesis]. University of Washington; 2019.
2021	Rosenberg MC. Modeling and Predicting Response to Ankle Exoskeletons [PhD thesis]. University of Washington; 2021.
2023	Kuska E. In Silico Techniques to Improve Understanding of Gait in Cerebral Palsy [PhD thesis]. University of Washington; 2023.