Implications of Assist-As-Needed Robotic Step Training after a Complete Spinal Cord Injury on Intrinsic Strategies of Motor Learning

Cai, L.L.; Fong, Andy J.; Otoshi, Chad K.; Liang, Yongqiang; Burdick, Joel W.; Roy, Roland R.; Edgerton, V. Reggie

doi:10.1523/jneurosci.2266-06.2006

Cited by 311 publications

(223 citation statements)

References 18 publications

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“…In most of these studies, however, a distinction is not made as to whether the pharmacological agent is actually inducing locomotion vs. changing the physiological state of the spinal cord so that it can generate locomotion when the afferent systems are allowed to control the motor output. In reports of the facilitation of locomotion in response to either strychnine or quipazine, it was clear that the drug itself, at least for the dosages used, did not induce stepping (Cai et al, 2006b;de Leon et al, 1999;Fong et al, 2005). When the hindlimbs were placed on a moving treadmill belt after administration of the drug, however, effective weight-bearing locomotion could be generated.…”

Section: The Enabling and Synergistic Effects Of Pharmacological Intementioning

confidence: 99%

“…To address the question of whether there was an important interactive effect of the pharmacological intervention and the training, we administered the 5-HT receptor agonist quipazine daily to a group of spinal mice that were step trained and to a group that were not trained (Cai et al, 2006b;Fong et al, 2005). The non-trained mice receiving quipazine showed no sustained improvement in stepping over a period of several weeks, whereas the trained mice receiving quipazine showed a significant improvement in stepping ability.…”

Section: Use-dependent Plasticitymentioning

confidence: 99%

“…This way, only when the trajectory deviates from the desired training trajectory greatly, does the robotic device assist the animal back to the target training trajectory. In this experiment (Cai et al, 2006b), one group was assisted such that each leg could operate independently. A second group was assisted with the additional criterion being that the two limbs must function in an alternating, out of phase fashion.…”

Section: Are the Variations In The Pathways Activated From Step To Stmentioning

confidence: 99%

“…Thus we are currently using a computational learning model to test our hypothesis that there is an optimal level of variation in the kinematics and dynamics of stepping. We predict that step training related learning will not occur if the pattern is too fixed or too variable (Cai et al, 2006b). 6. Gaining access to the spinal circuitry that can generate locomotion in humans: taking advantage of state-dependent modulation of the spinal circuitry while using afferents as a source of control…”

Section: Are the Variations In The Pathways Activated From Step To Stmentioning

confidence: 99%

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Training locomotor networks

Edgerton

Courtine

Gerasimenko

et al. 2008

Brain Research Reviews

275

205

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For a complete adult spinal rat to regain some weight-bearing stepping capability, it appears that a sequence of specific proprioceptive inputs that are similar, but not identical, from step to step must be generated over repetitive step cycles. Furthermore, these cycles must include the activation of specific neural circuits that are intrinsic to the lumbosacral spinal cord segments. For these sensorimotor pathways to be effective in generating stepping, the spinal circuitry must be modulated to an appropriate excitability level. This level of modulation is sustained from supraspinal input in intact, but not spinal, rats. In a series of experiments with complete spinal rats, we have shown that an appropriate level of excitability of the spinal circuitry can be achieved using widely different means. For example, this modulation level can be acquired pharmacologically, via epidural electrical stimulation over specific lumbosacral spinal cord segments, and/or by use-dependent mechanisms such as step or stand training. Evidence as to how each of these treatments can "tune" the spinal circuitry to a "physiological state" that enables it to respond appropriately to proprioceptive input will be presented. We have found that each of these interventions can enable the proprioceptive input to actually control extensive details that define the dynamics of stepping over a range of speeds, loads, and directions. A series of experiments will be described that illustrate sensory control of stepping and standing after a spinal cord injury and the necessity for the "physiological state" of the spinal circuitry to be modulated within a critical window of excitability for this control to be manifested. The present findings have important consequences not only for our understanding of how the motor pattern for stepping is formed, but also for the design of rehabilitation intervention to restore lumbosacral circuit function in humans following a spinal cord injury.

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Section: The Enabling and Synergistic Effects Of Pharmacological Intementioning

confidence: 99%

Section: Use-dependent Plasticitymentioning

confidence: 99%

Section: Are the Variations In The Pathways Activated From Step To Stmentioning

confidence: 99%

Section: Are the Variations In The Pathways Activated From Step To Stmentioning

confidence: 99%

See 2 more Smart Citations

Training locomotor networks

Edgerton

Courtine

Gerasimenko

et al. 2008

Brain Research Reviews

275

205

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“…This is the impedancebase control. To help the movement of patients with minimal helping force, the control strategy call "Assistance-as-need" (AAN) have been presented in ref [14][15] and the potential of AAN strategies has been shown in upper-limb training of stroke patients [16][17]. The challenge-based control strategy will make the movement of the participant limb more difficult or challenging.…”

Section: Introductionmentioning

confidence: 99%

A Novel Design and Implementation of a 4-DOF Upper Limb Exoskeleton for Stroke Rehabilitation with Active Assistive Control Strategy

Sutapun¹,

Sangveraphunsiri²

2017

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Abstract. We developed a robot, CUREs (Chulalongkorn University Rehabilitation Robotic Exoskeleton system), for upper extremity rehabilitation. The active assistive control strategy based on the impedance force control is developed and implemented to obtain assistive-resistive paths tracking for rehabilitation activities. The desired trajectory or rehabilitated training pattern for each specific patient need to be assigned first by a medical doctor and a physical therapy. The therapist can program the desired trajectory by guiding the patient arm based on the assigned path pattern and the set of via points will be stored and used for generating the desired trajectory. The desired trajectory will be stored specific for the patient and can be called back anytime. During the rehabilitation, the robot can assist and resist the patient's arm to follow the desired trajectory. If the patient has difficulty moving his arm to track the desired path, the robot will help by adding more torque to help the patient to move his arm to reduce the error between the desired path and the actual posture. And if the patient himself can move his arm tracking the desired path, the robot will not apply any more force to assist or resist. The necessary state variables such as angular position and torque can be recorded during the training. The main purpose of the experiment, follow the medical ethic, is to assure that there is no side effect for using this rehabilitation robot. Five subacute stroke patients participated in this pilot study. All patients have severe upper extremity weakness. The medical doctor will assign the training pattern based on patient condition. The result showed that the Fugl-Meyer Assessment Upper Extremity Scale was improved after 10 days of training in all participants without any sign of side effect.

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An Active Orthosis for Gait Rehabilitation

Hussain

Xie

2013

Mechatronics

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Implications of Assist-As-Needed Robotic Step Training after a Complete Spinal Cord Injury on Intrinsic Strategies of Motor Learning

Cited by 311 publications

References 18 publications

Training locomotor networks

Training locomotor networks

A Novel Design and Implementation of a 4-DOF Upper Limb Exoskeleton for Stroke Rehabilitation with Active Assistive Control Strategy

An Active Orthosis for Gait Rehabilitation

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