Development of a Crutch Substitute for Mimicking Human Natural Walking Gait

Nina Robson; Gabrielle Martinez; Michael Villavecer; Justin Chin; Bryan Hollowayi; Salar Nosratabadi; Larry Tlilayatz

doi:10.15377/2409-9694.2014.01.02.6

Articles

Vol. 1 No. 2 (2014)

Development of a Crutch Substitute for Mimicking Human Natural Walking Gait

Nina Robson⁺⁻
Gabrielle Martinez⁺⁻
Michael Villavecer⁺⁻
Justin Chin⁺⁻
Bryan Hollowayi⁺⁻
Salar Nosratabadi ⁺⁻
Larry Tlilayatz⁺⁻

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DOI: https://doi.org/10.15377/2409-9694.2014.01.02.6
Submitted: March 10, 2014
Published: 01.07.2021

Abstract

In order to resolve some of the disadvantages of conventional crutch designs, as well as some of the existing crutch-substitute devices, available on the market, a novel Exo-Limb crutch design is presented. The Exo-limb is a hands-free crutch meant to enhance and replace standard underarm crutches and other competitive products during injury rehabilitation. The focus of this research has been on creating a cost-effective passive device that mimics humans natural walking gait using purely mechanical components. Prior to the design, human natural treadmill walking was monitored by a 3D Motion Capture System and a reference end¢‚¬€œfoot trajectory with a ¢‚¬Ëœteardrop shape¢‚¬„¢ was acquired. Considering the design objectives, natural human walking and comfort, and other factors such as load capacity and weight of the device, the final design was determined. In order to satisfy the design objectives a kinematic synthesis, previously developed by one of the co-authors, is applied to test if the end¢‚¬€œfoot trajectory of the designed crutch substitute smoothly follows the desired reference, ¢‚¬Ëœteardrop shape¢‚¬„¢ in the vicinity of two specified task points, heel strike and toe off. A prototype of the final design was fabricated and its performance was tested by 2 mph treadmill walking. The research and developments made in this project with regard to mimicking the natural walking gait are important contributions that find applications in different areas, such as military, robotic locomotion, injury recovery and physical therapy.

References

Hai-Eng P, Swierzewski Stanley J. Overview of ankle injuries. Health communities: risk Factors & causes of ankle injuries. http://www.healthcommunities.com/ankle-injuries/ index.shtml
Nagpurkar A, Troeller A. An evaluation of crutch energetics using standard and hands-free crutches. Clinical Biomechanics (n.d.): 1-8. Web.
Epstein S. Art, History, and the Crutch. Ann Medical History 1937; 9: 304-313.
Emami M, Jamali S. Investigation of ergonomic issues in crutch design and present an innovation, in Proc. of APIEMS Asia Pacific Industrial Engineering & Management Systems Conference (APIEMS) 2009; pp. 2939-2943.
Ginanneschi F, Filippou F, Milani P, Biasella A, Rossi A. Ulnar nerve compression neuropathy at Guyon's canal caused by crutch walking: Case report with ultrasonographic nerve imaging. Archives of Physical Medicine and Rehabilitation 2009; 90(3): 522-524.
Fisher S, Patterson R. Energy cost of ambulation with crutches. Archives of Physical Medicine and Rehabilitation 1981; 62(6): 250-256.
www.iwalk-free.com
Robson N, McCarthy JM, Kinematic synthesis with contact direction and curvature constraints on the workpiece. Proc ASME IDETC 2007.
Passive assistive walking device. Final Report. California State University, Fullerton. Senior Mechanical Engineering Students. Fullerton, CA 2012.
Texas aggie mechanical crutch. Final Report. Texas A&M Senior Engineering Technology Students. TAMU, College Station, TX 2011.
Bassett, et al. Pedometer-measured physical activity and health behaviors in US adults. Medicine & Science in Sports & Exercise, Official Journal of the American College of Sports Medicine 2010.

Keywords

Human walking gait, crutch substitute, “teardrop” trajectory.

How to Cite

Nina Robson, Gabrielle Martinez, Michael Villavecer, Justin Chin, Bryan Hollowayi, Salar Nosratabadi, & Larry Tlilayatz. (2021). Development of a Crutch Substitute for Mimicking Human Natural Walking Gait. International Journal of Robotics and Automation Technology, 1(2), 99–105. https://doi.org/10.15377/2409-9694.2014.01.02.6

[1] Hai-Eng P, Swierzewski Stanley J. Overview of ankle injuries. Health communities: risk Factors & causes of ankle injuries. http://www.healthcommunities.com/ankle-injuries/ index.shtml

[2] Nagpurkar A, Troeller A. An evaluation of crutch energetics using standard and hands-free crutches. Clinical Biomechanics (n.d.): 1-8. Web.

[3] Epstein S. Art, History, and the Crutch. Ann Medical History 1937; 9: 304-313.

[4] Emami M, Jamali S. Investigation of ergonomic issues in crutch design and present an innovation, in Proc. of APIEMS Asia Pacific Industrial Engineering & Management Systems Conference (APIEMS) 2009; pp. 2939-2943.

[5] Ginanneschi F, Filippou F, Milani P, Biasella A, Rossi A. Ulnar nerve compression neuropathy at Guyon's canal caused by crutch walking: Case report with ultrasonographic nerve imaging. Archives of Physical Medicine and Rehabilitation 2009; 90(3): 522-524.

[6] Fisher S, Patterson R. Energy cost of ambulation with crutches. Archives of Physical Medicine and Rehabilitation 1981; 62(6): 250-256.

[7] www.iwalk-free.com

[8] Robson N, McCarthy JM, Kinematic synthesis with contact direction and curvature constraints on the workpiece. Proc ASME IDETC 2007.

[9] Passive assistive walking device. Final Report. California State University, Fullerton. Senior Mechanical Engineering Students. Fullerton, CA 2012.

[10] Texas aggie mechanical crutch. Final Report. Texas A&M Senior Engineering Technology Students. TAMU, College Station, TX 2011.

[11] Bassett, et al. Pedometer-measured physical activity and health behaviors in US adults. Medicine & Science in Sports & Exercise, Official Journal of the American College of Sports Medicine 2010.