Hybrid models of the neuromusculoskeletal system improve subject-specificity

Abstract

Muscle-actuated simulations of pathological gait have the capacity to identify muscle impairments and compensatory strategies, but the lack of subject-specific solutions prevents the prescription of personalized therapies. Conversely, electromyographic-driven models are limited to muscles for which data are available but can capture the true neural drive initiated by an individual subject. In order to improve subject-specificity and enforce physiological constraints on muscle activity, we propose a hybrid strategy for the optimization of subject-specific muscle patterns that involves forward dynamic simulation of whole body movement coupled with electromyographic-driven models of muscle subsets. In this paper we apply the hybrid approach to an example of post-stroke gait and demonstrate its unique ability to account for the unusual muscle activation patterns and muscle properties in patients with neuromuscular impairments.

Keywords

Neuromuscular musculoskeletal model gait optimization

Get full access to this article

View all access options for this article.

References

Piazza

. Muscle-driven forward dynamic simulations for the study of normal and pathological gait. J NeuroEng Rehab 2006; 3: 5.

Neptune

Kautz

Zajac

. Contributions of the individual ankle plantar flexors to support, forward progression and swing initiation during walking. J Biomech 2001; 34: 1387–1398.

Neptune

Zajac

Kautz

. Muscle force redistributes segmental power for body progression during walking. Gait & Posture 2001; 19: 194–205.

Pandy

. Computer modeling and simulation of human movement. Annu Rev Biomed Eng 2001; 3: 245–273.

Jonkers

Stewart

Spaepen

. The complementary role of the plantarflexors, hamstrings and gluteus maximus in the control of stance limb stability during gait. Gait & Posture 2003; 17: 264–272.

Richards

Higginson

. Knee contact force in subjects with symmetrical OA grades: differences between OA severities. J Biomech 2010; 43: 2595–2600.

Fregly

. Computational assessment of combinations of gait modifications for knee osteoarthritis rehabilitation. IEEE Trans Biomed Eng 2008; 55: 2104–2106.

Fregly

Reinbolt

Rooney

. Design of patient-specific gait modifications for knee osteoarthritis rehabilitation. IEEE Trans Biomed Eng 2007; 54: 1687–1695.

Higginson

Zajac

Neptune

. Muscle contributions to support during gait in an individual with post-stroke hemiparesis. J Biomech 2006; 39: 1769–1777.

10.

Shao

Buchanan

. A biomechanical model to estimate corrective changes in muscle activation patterns for stroke patients. J Biomech 2008; 41: 3097–3100.

11.

Fregly

B J

D’Lima

Colwell

. Effective gait patterns for offloading the medial compartment of the knee. J Ortho Res 2009; 27: 1016–1021.

12.

Erdemir

McLean

Herzog

Van den Bogert

. Model-based estimation of muscle forces exerted during movements. Clin Biomech 2007; 22: 131–154.

13.

Lieber

. Skeletal muscle structure and function: Implications for rehabilitation and sports medicine. Maryland: Williams & Wilkins, 1992.

14.

Buchanan

Lloyd

Manal

Besier

. Neuromusculoskeletal modeling: estimation of muscle forces and joint moments and movements from measurements of neural command. J Applied Biomech 2004; 20: 367–395.

15.

Buchanan

Lloyd

Manal

Besier

. Estimation of muscle forces and joint moments using a forward-inverse dynamics model. Med Sci Sports Excer 2005; 37(11): 1911–1916.

16.

Delp

Anderson

Arnold

. OpenSim: Open-source software to create and analyze dynamic simulations of movement. IEEE Trans Biomed Eng 2007; 54: 1940–1950.

17.

Lloyd

Besier

. An EMG-driven musculoskeletal model to estimate muscle forces and knee joint moments in vivo. J Biomech 2003; 36: 765–776.

18.

Manal

Buchanan

. A one-parameter neural activation to muscle activation model: estimating isometric joint moments from electromyograms. J Biomech 2003; 36: 1197–1202.

19.

Goffe

Ferrier

Rogers

. Global optimization of statistical functions with simulated annealing. J Econometrics 1994; 60: 65–100.

20.

Thelen

Anderson

Delp

. Generating dynamic simulations of movement using computed muscle control. J Biomech 2003; 36: 321–328.

21.

Thelen

Anderson

. Using computed muscle control to generate forward dynamic simulations of human walking from experimental data. J Biomech 2006; 39: 1107–1115.