Biomechanical Analysis of Functional Electrical Stimulation on Trunk Musculature During Wheelchair Propulsion

Background. The objective of this study was to examine how surface electrical stimulation of trunk musculature influences the kinematic, kinetic, and metabolic characteristics, as well as shoulder muscle activity, during wheelchair propulsion. Methods. Eleven participants with spinal cord injury propelled their own wheelchairs on a dynamometer at a speed of 1.3 m/s for three 5-minute trials. During a propulsion trial, 1 of 3 stimulation levels (HIGH, LOW, and OFF) was randomly applied to the participant’s abdominal and back muscle groups with a surface functional electrical stimulation device. Propulsion kinetics, trunk kinematics, metabolic responses, and surface electromyographic (EMG) activity of 6 shoulder muscles were collected synchronously. Kinetic, kinematic, and EMG variables were recorded during 3 time intervals (30 seconds each) within a 5-minute trial. Metabolic variables were recorded through the entire 5-minute trial. Results. Participants with HIGH stimulation increased their gross mechanical efficiency (P = .05) during wheelchair propulsion. No differences were found in shoulder EMG activity, energy expenditure, and trunk motion between stimulation levels. Conclusion. Functional electrical stimulation on the trunk musculature has potential advantages in helping manual wheelchair users with spinal cord injury improve propulsion efficiency without placing additional demands on shoulder musculature.

[1]  A. Kralj,et al.  Functional Electrical Stimulation: Standing and Walking after Spinal Cord Injury , 1989 .

[2]  Robert Gailey,et al.  Advances in lower-limb prosthetic technology. , 2010, Physical medicine and rehabilitation clinics of North America.

[3]  H E Veeger,et al.  Effect of handrim velocity on mechanical efficiency in wheelchair propulsion. , 1992, Medicine and science in sports and exercise.

[4]  D. Cardenas,et al.  Upper extremity pain after spinal cord injury , 1999, Spinal Cord.

[5]  H E Veeger,et al.  Biomechanics and physiology in active manual wheelchair propulsion. , 2001, Medical engineering & physics.

[6]  H E Veeger,et al.  Quasi-static analysis of muscle forces in the shoulder mechanism during wheelchair propulsion. , 1996, Journal of biomechanics.

[7]  Rory A Cooper,et al.  A kinetic analysis of manual wheelchair propulsion during start-up on select indoor and outdoor surfaces. , 2005, Journal of rehabilitation research and development.

[8]  R A Cooper,et al.  Shoulder imaging abnormalities in individuals with paraplegia. , 2001, Journal of rehabilitation research and development.

[9]  Rory A. Cooper,et al.  Design features that affect the maneuverability of wheelchairs and scooters. , 2010, Archives of physical medicine and rehabilitation.

[10]  Rory A Cooper,et al.  Quality-of-life technology for people with spinal cord injuries. , 2010, Physical medicine and rehabilitation clinics of North America.

[11]  P. Schantz,et al.  Movement and muscle activity pattern in wheelchair ambulation by persons with para-and tetraplegia. , 1999, Scandinavian journal of rehabilitation medicine.

[12]  T Gordon,et al.  Muscle atrophy and procedures for training after spinal cord injury. , 1994, Physical therapy.

[13]  C J Newsam,et al.  Isometric shoulder torque in subjects with spinal cord injury. , 1994, Archives of physical medicine and rehabilitation.

[14]  Heidi Horstmann Koester,et al.  Research in computer access assessment and intervention. , 2010, Physical medicine and rehabilitation clinics of North America.

[15]  M. Boninger,et al.  Required vs. elective research and in-depth scholarship programs in the medical student curriculum. , 2010, Academic medicine : journal of the Association of American Medical Colleges.

[16]  J. Perry,et al.  The effect of level of spinal cord injury on shoulder joint kinetics during manual wheelchair propulsion. , 2001, Clinical biomechanics.

[17]  J. Quintern,et al.  Functional neuromuscular stimulation for standing after spinal cord injury. , 1990, Archives of physical medicine and rehabilitation.

[18]  H E Veeger,et al.  Wheelchair racing: effects of rim diameter and speed on physiology and technique. , 1988, Medicine and science in sports and exercise.

[19]  Margaret A. Finley,et al.  The biomechanics of wheelchair propulsion in individuals with and without upper-limb impairment. , 2004, Journal of rehabilitation research and development.

[20]  Rory A Cooper,et al.  Shoulder and elbow motion during two speeds of wheelchair propulsion: a description using a local coordinate system , 1998, Spinal Cord.

[21]  M. Boninger,et al.  Surface electromyography activity of trunk muscles during wheelchair propulsion. , 2006, Clinical biomechanics.

[22]  Kersti A M Samuelsson,et al.  The effect of rear-wheel position on seating ergonomics and mobility efficiency in wheelchair users with spinal cord injuries: a pilot study. , 2004, Journal of rehabilitation research and development.

[23]  John V. Basmajian,et al.  Electrode placement in EMG biofeedback , 1980 .

[24]  R Aissaoui,et al.  Evaluation of the new flexible contour backrest for wheelchairs. , 2000, Journal of rehabilitation research and development.

[25]  R H Rozendal,et al.  The effect of rear wheel camber in manual wheelchair propulsion. , 1989, Journal of rehabilitation research and development.

[26]  Rory A Cooper,et al.  Joystick control for powered mobility: current state of technology and future directions. , 2010, Physical medicine and rehabilitation clinics of North America.

[27]  P. London Injury , 1969, Definitions.

[28]  L. Twomey,et al.  Upper limb function in persons with long term paraplegia and implications for independence: Part I , 1994, Paraplegia.

[29]  D. Siewiorek,et al.  Virtual coach technology for supporting self-care. , 2010, Physical medicine and rehabilitation clinics of North America.

[30]  Michael L Boninger,et al.  Reliability of quantitative ultrasound measures of the biceps and supraspinatus tendons. , 2009, Academic radiology.

[31]  Peter M. Kant,et al.  Implementation of a longitudinal mentored scholarly project: an approach at two medical schools. , 2010, Academic medicine : journal of the Association of American Medical Colleges.

[32]  JoAnne K. Gronley,et al.  Electromyographic activity of shoulder muscles during wheelchair propulsion by paraplegic persons. , 1996, Archives of physical medicine and rehabilitation.

[33]  R. Triolo,et al.  The effects of trunk stimulation on bimanual seated workspace , 2004, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[34]  J. Kinney,et al.  Energy Metabolism, Indirect Calorimetry, and Nutrition , 1989 .

[35]  Alicia M Koontz,et al.  Trunk movement patterns and propulsion efficiency in wheelchair users with and without SCI , 2004 .

[36]  Rory A. Cooper,et al.  An analysis of trunk excursion in manual wheelchair users , 2004 .

[37]  L. V. D. van der Woude,et al.  Wheelchair propulsion technique and mechanical efficiency after 3 wk of practice. , 2002, Medicine and science in sports and exercise.

[38]  S. D. Shimada,et al.  Three-dimensional pushrim forces during two speeds of wheelchair propulsion. , 1997, American journal of physical medicine & rehabilitation.

[39]  Upper Limb Nerve Entrapment Syndromes in Veterans With Lower Limb Amputations , 2010, PM & R : the journal of injury, function, and rehabilitation.

[40]  Ian Rice,et al.  Hand Rim Wheelchair Propulsion Training Using Biomechanical Real-Time Visual Feedback Based on Motor Learning Theory Principles , 2010, The journal of spinal cord medicine.

[41]  Jacquelin Perry,et al.  Effects of spinal cord injury level on the activity of shoulder muscles during wheelchair propulsion: an electromyographic study. , 2004, Archives of physical medicine and rehabilitation.

[42]  K. Sinnott,et al.  Factors associated with thoracic spinal cord injury, lesion level and rotator cuff disorders , 2000, Spinal Cord.

[43]  H E Veeger,et al.  Effectiveness of force application in manual wheelchair propulsion in persons with spinal cord injuries. , 1998, American journal of physical medicine & rehabilitation.

[44]  D. Theisen,et al.  Wheelchair Propulsion Biomechanics , 2001, Sports medicine.

[45]  J. Perry,et al.  Temporal-spatial characteristics of wheelchair propulsion. Effects of level of spinal cord injury, terrain, and propulsion rate. , 1996, American journal of physical medicine & rehabilitation.

[46]  C E Beekman,et al.  Energy cost of propulsion in standard and ultralight wheelchairs in people with spinal cord injuries. , 1999, Physical therapy.

[47]  R A Cooper,et al.  Methods for determining three-dimensional wheelchair pushrim forces and moments: a technical note. , 1997, Journal of rehabilitation research and development.

[48]  Kai-Nan An,et al.  Muscle force and its role in joint dynamic stability. , 2002, Clinical orthopaedics and related research.

[49]  R J Triolo,et al.  Inter-rater reliability of a clinical test of standing function. , 1995, The journal of spinal cord medicine.

[50]  Alicia M Koontz,et al.  Does upper-limb muscular demand differ between preferred and nonpreferred sitting pivot transfer directions in individuals with a spinal cord injury? , 2009, Journal of rehabilitation research and development.

[51]  Fong-Chin Su,et al.  Mechanical energy and power flow of the upper extremity in manual wheelchair propulsion. , 2003, Clinical biomechanics.

[52]  D J Sanderson,et al.  Kinematic features of wheelchair propulsion. , 1985, Journal of biomechanics.