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Abstract

One of the most important aspects of the modelling of musculoskeletal systems is the determination of muscle moment arms which are dependent upon the paths of the muscles. These paths are often required to wrap around passive structures that can be modelled as simple geometric shapes. A novel technique for the prediction of the paths of muscles modelled as strings when wrapping around smooth analytical surfaces is presented. The theory of geodesics is used to calculate the shortest path of the string on the surface and a smoothness constraint is used to determine the correct solutions for the string path between insertions. The application of the technique to tapered cylinders and ellipsoids is presented as an extension of previous work on right-circular cylinders and spheres. The technique is assessed with reference to a particular biomechanical scenario; string lengths and moment arms are calculated and compared with alternative approximate methods. This illustrates the potential of the technique to provide more accurate muscle moment arm predictions.

Keywords

biomechanical modelling muscle wrapping geodesics

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References

Kuechle

D. K.

Newman

S. R.

Itoi

Niebur

G. L.

Morrey

B. F.

K.-N.

The relevance of the moment arm of shoulder muscles with respect to axial rotation of the glenohumeral joint in four positions. Clin. Biomechanics, 2000, 15, 322–329.

Liu

Hughes

R. E.

Smutz

W. P.

Niebur

G. L.

K.-N.

Roles of deltoid and rotator cuff muscles in shoulder elevation. Clin. Biomechanics, 1997, 12, 32–38.

de Wilde

Audenaert

Barbaix

Audenaert

Soudan

Consequences of deltoid muscle elongation on deltoid muscle perfomance: A computerised study. Clin. Biomechanics, 2002, 17, 499–505.

van der Helm

F. C. T.

Veenbaas

Modelling the effect of muscles with large attachment sites: Application to the shoulder mechanism. J. Biomechanics, 1991, 24, 1151–1163.

Charlton

I. W.

Johnson

G. R.

A model for the prediciton of the forces at the glenohumeral joint. Proc. IMechE, Part H: J. Engineering in Medicine, 2006, 220, 801–812.

Van der Helm

F. C. T.

Analysis of the kinematic and dynamic behaviour of the shoulder mechanism. J. Biomechanics, 1994, 27, 527–550.

Delp

S. L.

Loan

J. P.

A graphics-based software system to develop and analyze models of musculoskeletal structures. Computers in Biology Medicine, 1995, 25(1), 21–34.

8 Any Body technology, 2006, available from http://www.anybodytech.com and http://www.anybody.auc.dk.

9 Aalborg University Biomechanics, Welcome to the AnyBody Research Project, 2001.

10.

van der Helm

F. C. T.

The shoulder mechanism: a dynamical approach. PhD Thesis, Delft University of Technology, 1991.

11.

Vondrák

Damsgaard

Christensen

S. T.

Rasmussen

Muscle wrapping modelling in biomechanical simulations. In Biomechanics of man 2004 (Ed. Horák

), Šumava Mountains, Czech Republic, 16-19 November 2004 (Czech Society of Biomechanics, Praha).

12.

Feng

Damsgaard

Rasmussen

Christensen

S. T.

Calculating muscle line-of-action for musculo-skeletal modeling. Biol. Cybernetics, 2002, 87(3), 199–210.

13.

Charlton

I. W.

Johnson

G. R.

Application of spherical and cylindrical wrapping algorithms in a musculoskeletal model of the upper limb. J. Biomechanics, 2001, 34(9), 1209–1216.

14.

van der Helm

F. C. T.

Veeger

H. E. J.

Makhsous

van Roy

Anglin

Nagels

Karduna

A. R.

McQuade

Wang

Werner

F. W.

Buchholz

ISB recommendation on definition of joint coordinate systems of various joints for the reporting of human joint motion — Part II: Shoulder, elbow, wrist and hand. J. Biomechanics, 2005, 38(5), 981–992.

15.

Charlton

I. W.

A model for the prediction of forces at the glenohumeral joint. PhD Thesis, Newcastle University, 2006.

16.

Ravi Kumar

G. V. V.

Srinivasan

Devaraja Holla

Shastry

K. G.

Prakash

B. G.

Geodesic curve computations on surfaces. Computer Aided Geometric Des., 2003, 20, 119–133.

17.

O'Neill

Elementary differential geometry, 2nd edition, 1997 (Academic Press, New York).

18.

Pressley

Elementary differential geometry, 2005 (Springer-Verlag, London).

A novel approach to the prediction of musculotendon paths

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