Feasibility of closed-loop controller for righting seated posture after spinal cord injury

Murphy, Julie O.; Audu, Musa L.; Lombardo, Lisa M.; Foglyano, Kevin M.; Triolo, Ronald J.

doi:10.1682/jrrd.2013.09.0200

Cited by 35 publications

(28 citation statements)

References 35 publications

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“…Neural stimulation can improve skeletal alignment, alter trunk position, enable bimanual reach and expand seated work volume, and restore erect upright sitting from a fully forward flexed position [20]. Electrically activating the paralyzed core hip and trunk muscles can stabilize seated posture and improve manual wheelchair efficiency [21] and prevent forward falls in response to applied disturbances [22,23]. Results of this study indicate that potentially destabilizing events can be detected from a relatively small number of sensors with relatively simple classification algorithms.…”

Section: Discussionmentioning

confidence: 99%

Detecting destabilizing wheelchair conditions for maintaining seated posture

Crawford

Armstrong

Loparo

et al. 2017

Disability and Rehabilitation: Assistive Technology

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Purpose The purpose of this study was to detect and classify potentially destabilizing conditions encountered by manual wheelchair users with spinal cord injuries (SCI) to dynamically increase stability and prevent falls. Methods A volunteer with motor complete T11 paraplegia repeatedly propelled his manual wheelchair over level ground and simulated destabilizing conditions including sudden stops, bumps and rough terrain. Wireless inertial measurement units attached to the wheelchair frame and his sternum recorded associated accelerations and angular velocities. Algorithms based on mean, standard deviation and minimum Mahalanobis distance between conditions were constructed and applied to the data off-line to discriminate between events. Classification accuracy was computed to assess effects of sensor position and potential for automatically selecting a dynamic intervention to best stabilize the wheelchair user. Results The decision algorithm based on acceleration signals successfully differentiated destabilizing conditions and level over-ground propulsion with classification accuracies of 95.8, 58.3 and 91.7% for the chest, wheelchair and both sensors, respectively. Conclusion Mahalanobis distance classification based on trunk accelerations is a feasible method for detecting destabilizing events encountered by wheelchair users and may serve as an effective trigger for protective interventions. Incorporating data from wheelchair-mounted sensors decreases the false negative rate.

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Section: Discussionmentioning

confidence: 99%

Detecting destabilizing wheelchair conditions for maintaining seated posture

Crawford

Armstrong

Loparo

et al. 2017

Disability and Rehabilitation: Assistive Technology

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“…Moreover, they resulted in tools for evaluating more sophisticated control systems that might allow users to set their own task-dependent postures, and maintain balance during internal or external perturbations. Recent studies have established the feasibility of a self-righting control system that works on the dynamic movement of the trunk to automatically return to an erect posture from forward-flexed positions by monitoring trunk tilt and modulating stimulation to the trunk and hip extensors appropriately (Figure 7) 62 . In this study, five individuals with SCI volunteered to test a simple threshold-based set-point controller.…”

Section: Trunk Control and Posture With Fesmentioning

confidence: 99%

Functional Electrical Stimulation and Spinal Cord Injury

Triolo

Elias

et al. 2014

Physical Medicine and Rehabilitation Clinics of North America

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165

122

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Synopsis Spinal cord injuries (SCI) can disrupt communications between the brain and the body, leading to a loss of control over otherwise intact neuromuscular systems. The use of electrical stimulation (ES) of the central and peripheral nervous system can take advantage of these intact neuromuscular systems to provide therapeutic exercise options, to allow functional restoration, and even to manage or prevent many medical complications following SCI. The use of ES for the restoration of upper extremity, lower extremity and truncal functions can make many activities of daily living a potential reality for individuals with SCI. Restoring bladder and respiratory functions and preventing pressure ulcers may significantly decrease the morbidity and mortality following SCI. Many of the ES devices are already commercially available and should be considered by all SCI clinicians routinely as part of the lifelong rehabilitation care plan for all eligible individuals with SCI.

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“…This large number of transfers also contributes to the development or perpetuation of secondary upper limbs musculoskeletal impairments over time and it is known that after SCI, individuals have great risks of pain and injury in the upper limb due to joint overloads during activities of daily living [11], [1], [2]. Functional electrical stimulation (FES) can be used as a potential technological resource to assist these people during transfers [8], [10], [6], [5]. However, how the user activates the stimulation poses a problem.…”

Section: Introductionmentioning

confidence: 99%

Towards transfers in paraplegia assisted by electrical stimulation and inertial system

Fonseca

Lopes

Ochoa-Diaz

et al. 2017

2017 IEEE Life Sciences Conference (LSC)

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Spinal cord injured (SCI) patients that have no lower limb motor function perform several transfers during a day. Those transfers are from and to a wheelchair, a car, a hygienic chair, among other situations. These repetitive motions can cause overload on their upper limbs over time. Functional Electrical Stimulation may be used to induce contraction on knee extensors, providing additional support at the joint level during transfer. However, the design of the interface with which to control the onset of stimulation is challenging. The use of some automated system is beneficial, particularly since the user is using both hands to perform the transfer. Therefore, the precise moment of activation is important because, if erroneous, it can cause the user's loss of balance. A system with which the users themselves can activate the stimulation with triggers in gloves is used to collect kinematic data from SCI patients during Sitting Pivot Transfers. The results show that the trunk angle can be used along a threshold for a reliable assistance device. Strategies for portability using a wireless inertial measurement unit are also discussed.

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Feasibility of closed-loop controller for righting seated posture after spinal cord injury

Cited by 35 publications

References 35 publications

Detecting destabilizing wheelchair conditions for maintaining seated posture

Detecting destabilizing wheelchair conditions for maintaining seated posture

Functional Electrical Stimulation and Spinal Cord Injury

Towards transfers in paraplegia assisted by electrical stimulation and inertial system

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