Ambulatory assessment of 3D ground reaction force using plantar pressure distribution

Gait and Posture

Volumn 32, Issue 3, 2010, Pages 311-316

  Rouhani, H ^a   Favre, J ^a   Crevoisier, X ^b   Aminian, K ^a  

^a EPFL   (Switzerland)

^b LAUSANNE UNIVERSITY HOSPITAL   (Switzerland)

Author keywords

Ambulatory pressure insoles; Gait analysis; Ground reaction force; Plantar pressure distribution

Indexed keywords

ANKLE INJURY; ARTICLE; CLINICAL ARTICLE; FOOT SOLE; FORCE; FRICTION; GROUND REACTION FORCE; HUMAN; MOBILIZATION; PRESSURE; PRIORITY JOURNAL; WALKING;

ADULT; AMBULATORY CARE; ANKLE JOINT; BIOMECHANICS; CASE-CONTROL STUDIES; FEMALE; FOOT; FRICTION; GAIT; HUMANS; MALE; ORTHOTIC DEVICES; PRESSURE; REFERENCE VALUES; SENSITIVITY AND SPECIFICITY; SHOES; STRESS, MECHANICAL; TORQUE;

EID: 77956744356     PISSN: 09666362     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.gaitpost.2010.05.014     Document Type: Article

References (21)

1. Forner-Cordero A., Koopman H.J.F.M., van der Helm F.C.T. Use of pressure insoles to calculate the complete ground reaction forces. Journal of Biomechanics 2004, 37:1427-1432.
2. Benedetti M.G., Catani F., Leardini A., Pignotti E., Giannini S. Data management in gait analysis for clinical applications. Clinical Biomechanics 1998, 13:204-215.
3. Beyaert C., Sirveaux F., Paysant J., Mole D., Andre J.M. The effect of tibio-talar arthrodesis on foot kinematics and ground reaction force progression during walking. Gait & Posture 2004, 20:84-91.
4. Kitaoka H.B., Crevoisier X.M., Harbst K., Hansen D., Kotajarvi B., Kaufman K. The effect of custom-made braces for the ankle and hindfoot on ankle and foot kinematics and ground reaction forces. Archives of Physical Medicine and Rehabilitation 2006, 87:130-135.
5. Liedtke C., Fokkenrood S.A.W., Menger J.T., van der Kooij H., Veltink P.H. Evaluation of instrumented shoes for ambulatory assessment of ground reaction forces. Gait & Posture 2007, 26:39-47.
6. Lord M., Hosein R., Williams R.B. Method for in-shoe shear stress measurement. Journal of Biomedical Engineering 1992, 14:181-186.
7. Razian M.A., Pepper M.G. Design, development, and characteristics of an in-shoe triaxial pressure measurement transducer utilizing a single element of piezoelectric copolymer film. IEEE Transactions on Neural Systems and Rehabilitation Engineering 2003, 11:288-293.
8. Ranu H.S. Miniature load cells for the measurement of foot-ground reaction forces and centre of foot pressure during gait. Journal of Biomedical Engineering 1986, 8:175-177.
9. Fong D.T.-P., Chan Y.-Y., Hong Y., Yung P.S.-H., Fung K.-Y., Chan K.-M. Estimating the complete ground reaction forces with pressure insoles in walking. Journal of Biomechanics 2008, 41:2597-2601.
10. Schmiegel A., Rosenbaum D., Schorat A., Hilker A., Gaubitz M. Assessment of foot impairment in rheumatoid arthritis patients by dynamic pedobarography. Gait & Posture 2008, 27:110-114.
11. Rosenbaum D., Becker H.P. Plantar pressure distribution measurements. Technical background and clinical applications. Foot and Ankle Surgery 1997, 3:1-14.
12. Erhart J.C., Mündermann A., Mündermann L., Andriacchi T.P. Predicting changes in knee adduction moment due to load-altering interventions from pressure distribution at the foot in healthy subjects. Journal of Biomechanics 2008, 41:2989-2994.
13. Pataky T.C., Goulermas J.Y. Pedobarographic statistical parametric mapping (pSPM): a pixel-level approach to foot pressure image analysis. Journal of Biomechanics 2008, 41:2136-2143.
14. Zou D., Mueller M.J., Lott D.J. Effect of peak pressure and pressure gradient on subsurface shear stresses in the neuropathic foot. Journal of Biomechanics 2007, 40:883-890.
15. Cenk Güler H., Berme N., Simon S.R. A viscoelastic sphere model for the representation of plantar soft tissue during simulations. Journal of Biomechanics 1998, 31:847-853.
16. Gilchrist L.A., Winter D.A. A two-part, viscoelastic foot model for use in gait simulations. Journal of Biomechanics 1996, 29:795-798.
17. Savelberg H.H.C.M, Lange ALHd. Assessment of the horizontal, fore-aft component of the ground reaction force from insole pressure patterns by using artificial neural networks. Clinical Biomechanics 1999, 14:585-592.
18. Jackson J.E. A User's Guide to Principal Components 2003, Wiley, New York.
19. Dejnabadi H., Jolles B.M., Aminian K. A new approach for quantitative analysis of inter-joint coordination during gait. Biomedical Engineering IEEE Transactions 2008, 55:755-764.
20. Nelles O. Nonlinear System Identification 2001, Springer, Berlin.
21. Hornik K., Stinchcombe M., White H. Multilayer feedforward networks are universal approximators. Neural Networks 1989, 2:359-366.