The objective of this research is to restore the ability to walk to spinal cord injured (SCI) individuals. Previous studies (by several researchers) have demonstrated that FES can effectively restore legged mobility (with the help of a stability aid), and that such legged mobility can provide significant physiological and psychological benefits to SCI users. Due to the potential of collapse (from muscle fatigue) and the need to guide uncontrolled degrees of freedom, hybrid systems appear to offer the greatest promise for commercially viable gait restoration. As such, recent efforts by various researchers have focused (and are focusing) on the development of hybrid systems. Despite this, a commercially viable hybrid FES system does not yet exist. The intent of this proposal is to develop a commercially feasible gait restoration system, namely one that eliminates the possibility of collapse (due to muscle fatigue), has a low threshold for implementation and use, provides a stable, efficient gait (i.e., a swing-through gait primarily powered by the lower limbs), and is donned and doffed independently and with a minimal level of effort. The proposed system utilizes a hybrid FES approach, which combines two channels of surface stimulation (quadriceps of each leg) with a unique microcomputer-controlled orthosis, called a joint-coupled controlled-brake orthosis (JCO), the combination of which provides a stable, safe, commercially viable gait restoration system for paralyzed persons. Specifically, the use of surface stimulation pro- vides a low threshold of implementation, but at the cost of limited muscular access (i.e., inability to directly access deep hip flexion muscles). This limitation is addressed by the orthosis, which includes a mechanical biasing of the knee joint and unidirectionally couples knee flexion to hip flexion, and with this combination pro- vides the hip and knee flexion required for reliable swing-through gait. The effect of muscle fatigue is greatly diminished by utilizing unique controllable brakes at the hip and knee joints to provide isometric torques (in place of muscle stimulation), and since the knee brakes are normally locked, the risk of collapse is essentially eliminated (even in the event of a power failure). The orthosis provides for smooth, repeatable control of limb trajectories, which is enabled by the combination of joint angle sensors and the proportionally controllable brakes, which are used to guide the limbs (i.e., joint angles) along a desired trajectory. Since the power for gait is provided by metabolic sources, the orthosis requires a minimal amount of on-board power. Finally, the approach is designed to facilitate independent donning and doffing with minimal user effort. As such, the pro- posed system has the characteristics (i.e., fail-safe, low fatigue, moderate exertion, easy don/doff, low electric- al power requirements) of a commercially viable self-contained gait restoration system. If successful, the pro- posed approach could transition in a direct manner to a viable commercial product, and therefore could significantly improve the quality of life of many SCI individuals suffering from complete paralysis of the lower limb.

Public Health Relevance

There are currently about 255,000 spinal cord injured individuals in the United States, with roughly 12,000 new injuries sustained each year, of which approximately 6300 of these (cases per year) result in complete paralysis of the legs with sufficient remaining arm functionality to potentially use the proposed gait restoration approach. Among the significant impairments resulting from paraplegia is the loss of legged mobility. The system proposed herein is intended as a supplement to (and not as a replacement of) a wheelchair, and in particular is intended to provide many of the physiological and psychological benefits of legged mobility that a wheelchair cannot, such as decreased osteoporosis, reduced incidence of decubitus ulcers, improved cardiovascular health, improved bowel and bladder function, reduced spasticity, and increased morale, self-image, and self- esteem.

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Research Project (R01)
Project #
5R01HD059832-02
Application #
7915709
Study Section
Musculoskeletal Rehabilitation Sciences Study Section (MRS)
Program Officer
Shinowara, Nancy
Project Start
2009-08-15
Project End
2014-06-30
Budget Start
2010-07-01
Budget End
2011-06-30
Support Year
2
Fiscal Year
2010
Total Cost
$301,887
Indirect Cost
Name
Vanderbilt University Medical Center
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
004413456
City
Nashville
State
TN
Country
United States
Zip Code
37212
Ha, Kevin H; Murray, Spencer A; Goldfarb, Michael (2016) An Approach for the Cooperative Control of FES With a Powered Exoskeleton During Level Walking for Persons With Paraplegia. IEEE Trans Neural Syst Rehabil Eng 24:455-66
Ekelem, Andrew; Murray, Spencer; Goldfarb, Michael (2015) Preliminary assessment of variable geometry stair ascent and descent with a powered lower limb orthosis for individuals with paraplegia. Conf Proc IEEE Eng Med Biol Soc 2015:4671-4
Murray, Spencer A; Goldfarb, Michael (2015) An analysis of physiological signals as a measure of task engagement in a multi-limb-coordination motor-learning task. Conf Proc IEEE Eng Med Biol Soc 2015:2103-6
Murray, Spencer A; Ha, Kevin H; Hartigan, Clare et al. (2015) An assistive control approach for a lower-limb exoskeleton to facilitate recovery of walking following stroke. IEEE Trans Neural Syst Rehabil Eng 23:441-9
Farris, Ryan J; Quintero, Hugo A; Murray, Spencer A et al. (2014) A preliminary assessment of legged mobility provided by a lower limb exoskeleton for persons with paraplegia. IEEE Trans Neural Syst Rehabil Eng 22:482-90
Murray, Spencer A; Ha, Kevin H; Goldfarb, Michael (2014) An assistive controller for a lower-limb exoskeleton for rehabilitation after stroke, and preliminary assessment thereof. Conf Proc IEEE Eng Med Biol Soc 2014:4083-6
Murray, Spencer; Goldfarb, Michael (2012) Towards the use of a lower limb exoskeleton for locomotion assistance in individuals with neuromuscular locomotor deficits. Conf Proc IEEE Eng Med Biol Soc 2012:1912-5
Quintero, Hugo A; Farris, Ryan J; Goldfarb, Michael (2012) A Method for the Autonomous Control of Lower Limb Exo-skeletons for Persons with Paraplegia. J Med Device 6:
Ha, Kevin H; Quintero, Hugo A; Farris, Ryan J et al. (2012) Enhancing stance phase propulsion during level walking by combining FES with a powered exoskeleton for persons with paraplegia. Conf Proc IEEE Eng Med Biol Soc 2012:344-7
Farris, Ryan J; Quintero, Hugo A; Goldfarb, Michael (2012) Performance evaluation of a lower limb exoskeleton for stair ascent and descent with paraplegia. Conf Proc IEEE Eng Med Biol Soc 2012:1908-11

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