Variability of femoral muscle attachments

Duda, Georg N.; Brand, Doris; Freitag, Sabine; Lierse, Werner; Schneider, Erich

Affiliations

¹Biomechanics Section, Technical University Hamburg-Harburg

²Hafenkrankenhaus Hamburg

³Neuro-Anatomical Institute, University Hospital Eppendorf, Hamburg, Germany

Abstract

Analytical and experimental models of the musculoskeletal system often assume single values rather than ranges for anatomical input parameters. The hypothesis of the present study was that anatomical variability significantly influences the results of biomechanical analyses, specifically regarding the moment arms of the various thigh muscles.

Insertions and origins of muscles crossing or attaching to the femur were digitized in six specimens. Muscle volumes were measured; muscle attachment area and centroid location were computed. To demonstrate the influence of inter-individual anatomic variability on a mechanical modeling parameter, the corresponding range of muscle moment arms were calculated.

Standard deviations, as a percentage of the mean, were about 70% for attachment area and 80% for muscle volume and attachment centroid location. The resulting moment arms of the m. gluteus maximus and m. rectus femoris were especially sensitive to anatomical variations (SD 65%).

The results indicate that sensitivity to anatomical variations should be analyzed in any investigation simulating musculoskeletal interactions. To avoid misinterpretations, investigators should consider using several anatomical configurations rather than relying on a mean data set.

Links

DOI: 10.1016/0021-9290(96)00025-5

PubMed: 8872275

WoS: A1996VD99800008

History

Revised: 1996-01-09

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Cited By (12)

Year	Entry
1998	Duda GN, Heller M, Albinger J, Schulz O, Schneider E, Claes L. Influence of muscle forces on femoral strain distribution. J Biomech. September 1998;31(9):841-846.
2001	Heller MO, Bergmann G, Deuretzbacher G, Dürselen L, Pohl M, Claes L, Haas NP, Duda GN. Musculo-skeletal loading conditions at the hip during walking and stair climbing. J Biomech. July 2001;34(7):883-893.
2011	Correa TA, Baker R, Kerr Graham H, Pandy MG. Accuracy of generic musculoskeletal models in predicting the functional roles of muscles in human gait. J Biomech. July 28, 2011;44(11):2096-2105.
2013	Gerus P, Sartori M, Besier TF, Fregly BJ, Delp SL, Banks SA, Pandy MG, D'Lima DD, Lloyd DG. Subject-specific knee joint geometry improves predictions of medial tibiofemoral contact forces. J Biomech. November 15, 2013;46(16):2778-2786.
2014	Handsfield GG, Meyer CH, Hart JM, Abel MF, Blemker SS. Relationships of 35 lower limb muscles to height and body mass quantified using MRI. J Biomech. February 7, 2014;47(3):631-638.
2015	Carbone V, Fluit R, Pellikaan P, van der Krogt MM, Janssen D, Damsgaard M, Vigneron L, Feilkas T, Koopman HFJM, Verdonschot N. TLEM 2.0: a comprehensive musculoskeletal geometry dataset for subject-specific modeling of lower extremity. J Biomech. March 18, 2015;48(5):734-741.
2015	Hicks JL, Uchida TK, Seth A, Rajagopal A, Delp SL. Is my model good enough? best practices for verification and validation of musculoskeletal models and simulations of movement. J Biomech Eng. February 2015;137(2):020905.
2013	Moore SR. Bridging Mechanics & Biology to Understand the Periosteum's Role in Bone Regeneration: Towards a Parametric Approach to Engineering Replacement Periosteum [PhD thesis]. Cleveland, OH: Case Western Reserve University; August 2013.
2016	Navacchia A. Multiscale Musculoskeletal Modeling of the Lower Limb to Perform Personalized Simulations of Movement [PhD thesis]. University of Denver; November 2016.
1999	Arnold AS. Quantitative Descriptions of Musculoskeletal Geometry in Persons With Cerebral Palsy: Guidelines for the Evaluation and Treatment of Crouch Gait [PhD thesis]. Evanston, IL: Northwestern University; December 1999.
2014	Handsfield GG. MRI and Computational Modeling of in Vivo Muscle-Tendon Architecture and Function [PhD thesis]. Charlottesville, VA: University of Virginia; December 2014.
2010	Anderson DE. An Examination of Age-Related Differences in Lower Extremity Joint Torques and Strains in the Proximal Femur During Gait [PhD thesis]. Virginia Polytechnic Institute and State University; March 26, 2010.