Long-Term Spinal Cord Stimulation After Chronic Complete Spinal Cord Injury Enables Volitional Movement in the Absence of Stimulation

Pino, Isabela Peña; Hoover, Caleb; Venkatesh, Shivani; Ahmadi, Aliya; Sturtevant, Dylan; Patrick, Nick; Freeman, David J.; Parr, Ann M.; Samadani, Uzma; Balser, David; Krassioukov, Andrei V.; Phillips, Aaron A.; Netoff, Theoden I.; Darrow, David

doi:10.3389/fnsys.2020.00035

Cited by 58 publications

(51 citation statements)

References 33 publications

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“…Future work should also consider optimal rehabilitative interventions to combine with SCS. While there is ample pre-clinical evidence to suggest that SCS is more effective when combined with afferent feedback due to locomotor training [28][29][30], our study, and the recent clinical studies using epidural SCS [18,34], suggest that recovery of volitional motor control can occur when SCS is combined with simple exercises (incorporating descending volitional drive), which are cheaper and more accessible to the SCI population.…”

Section: Clinical Implications and Future Workmentioning

confidence: 67%

“…No recovery (with tSCS off) was observed in P2, despite evidence of voluntary motor performance in the presence of tSCS during training sessions (see Video S1). Previous studies using epidural SCS in people with motor complete SCI have also reported considerable improvements in motor control (in the presence of SCS) in all participants (n = 12) [19,32,34], but recovery of volitional motor control with SCS off was only observed in a subset of these (5/12). Pre-clinical trials, using epidural SCS combined with step training, have also reported that animals with severe complete transections only show detectable improvements in stepping when stimulation is on, whereas animals with less severe injuries and greater lesion sparing were able to recover voluntary motor control when stimulation was absent [28][29][30]52].…”

Section: Recovery Of Volitional Motor Control (In the Absence Of Tscs)mentioning

confidence: 82%

“…SCS had been shown to regulate this with better prognosis for those with underlying excitability at baseline, for example, in spastic conditions [28,55]. Indeed, one recent study reported that the recovery of volitional control (with SCS off), observed after one-month of epidural SCS, was correlated with spasticity scores at baseline [34]; those authors proposed that baseline spasticity might be a marker for preserved corticospinal tract axons [56]. Given that tonic sub-threshold SCS has been reported to attenuate neural hyper-excitability and recover spinal inhibitory control in people with SCI [25,26,57], and has been successfully used in the treatment of spasticity [58,59], it is also possible that acute reductions in spasticity (due to SCS) enabled the participants access to these retained pathways, which were otherwise masked by hyper-excitability in the central nervous system.…”

Section: Recovery Of Volitional Motor Control (In the Absence Of Tscs)mentioning

confidence: 99%

“…Furthermore, it has recently been reported that this recovery of volitional motor control after SCS training was possible even when the SCS was switched off, indicative of neuroplastic recovery. This was achieved in people with incomplete SCI after several months of epidural SCS combined with intensive locomotor training [ 33 ], and in people with motor complete injuries after one month of daily epidural SCS, used to achieve volitional movement and specific autonomic functions (such as blood pressure regulation) [ 34 ].…”

Section: Introductionmentioning

confidence: 99%

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The Effects of Adding Transcutaneous Spinal Cord Stimulation (tSCS) to Sit-To-Stand Training in People with Spinal Cord Injury: A Pilot Study

Al'Joboori¹,

Massey²,

Knight

et al. 2020

JCM

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Spinal cord stimulation may enable recovery of volitional motor control in people with chronic Spinal Cord Injury (SCI). In this study we explored the effects of adding SCS, applied transcutaneously (tSCS) at vertebral levels T10/11, to a sit-to-stand training intervention in people with motor complete and incomplete SCI. Nine people with chronic SCI (six motor complete; three motor incomplete) participated in an 8-week intervention, incorporating three training sessions per week. Participants received either tSCS combined with sit-to-stand training (STIM) or sit-to-stand training alone (NON-STIM). Outcome measures were carried out before and after the intervention. Seven participants completed the intervention (STIM N = 5; NON-STIM N = 2). Post training, improvements in International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI) motor scores were noted in three STIM participants (range 1.0–7.0), with no change in NON-STIM participants. Recovery of volitional lower limb muscle activity and/or movement (with tSCS off) was noted in three STIM participants. Unassisted standing was not achieved in any participant, although standing with minimal assistance was achieved in one STIM participant. This pilot study has shown that the recruitment of participants, intervention and outcome measures were all feasible in this study design. However, some modifications are recommended for a larger trial.

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Section: Clinical Implications and Future Workmentioning

confidence: 67%

Section: Recovery Of Volitional Motor Control (In the Absence Of Tscs)mentioning

confidence: 82%

Section: Recovery Of Volitional Motor Control (In the Absence Of Tscs)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

The Effects of Adding Transcutaneous Spinal Cord Stimulation (tSCS) to Sit-To-Stand Training in People with Spinal Cord Injury: A Pilot Study

Al'Joboori¹,

Massey²,

Knight

et al. 2020

JCM

View full text Add to dashboard Cite

show abstract

“…Recovery relies on an intact central pattern generator (CPG) (106)(107)(108)(109)(110)(111) and often task-specific or locomotor training to engage the necessary proprioceptive and sensorimotor networks (112)(113)(114)(115)(116). Through EES and locomotor therapy in humans, many individuals have recovered some form of volitional sensorimotor control (10, 11, 27), although recent reports suggest that similar results can be achieved without the need for locomotor training (117,118).…”

Section: Ees To Restore Motor Function After Scimentioning

confidence: 99%

Electrical epidural stimulation of the cervical spinal cord: implications for spinal respiratory neuroplasticity after spinal cord injury

Malone

Nosacka

Nash

et al. 2021

Journal of Neurophysiology

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Traumatic cervical spinal cord injury (cSCI) can lead to damage of bulbospinal pathways to the respiratory motor nuclei and consequent life-threatening respiratory insufficiency due to respiratory muscle paralysis/paresis. Reports of electrical epidural stimulation (EES) of the lumbosacral spinal cord to enable locomotor function after SCI are encouraging, with some evidence of facilitating neural plasticity. Here, we detail the development and success of EES in recovering locomotor function with consideration of stimulation parameters and safety measures to develop effective EES protocols. EES is just beginning to be applied in other motor, sensory, and autonomic systems; however, there has only been moderate success in preclinical studies aimed at improving breathing function after cSCI. Thus, we explore rationale for applying EES to the cervical spinal cord, targeting the phrenic motor nucleus for the restoration of breathing. We also suggest cellular/molecular mechanisms by which EES may induce respiratory plasticity including a brief examination of sex-related differences in these mechanisms. Finally, we suggest more attention be paid to the effects of specific electrical parameters that have been used in the development of EES protocols and how that can impact the safety and efficacy for those receiving this therapy. Ultimately, we aim to inform readers about the potential benefits of EES in the phrenic motor system and encourage future studies in this area.

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Materials for Implantable Surface Electrode Arrays: Current Status and Future Directions

Tringides

Mooney

2022

Advanced Materials

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with the outermost layer of biological tissues, often spanning a significant surface area. Devices typically have multiple electrodes that aim to monitor and modulate cells and tissues in a minimally invasive manner, using biomaterials designed to evoke minimal inflammatory responses. Applications of Surface Electrode Arrays RecordingBecause surface electrode arrays can record a "snapshot" of the electrical activity at distinct locations, these arrays are useful to monitor the function of a tissue. Though the recordings are typically local field potentials, with electrodes that are small enough to modulate as little of a location as possible while still maintaining a sufficiently high conductivity, single units from individual cells have been reported. Clinically, these recordings are used to map the epicardial surface to identify instances, and potentially mechanisms, of chronic atrial fibrillation, [1] dysfunction of ventricular tachycardia caused by congenital defects, [2] and other abnormal conduction conditions in the cardiac system. Clinical electrocorticogram (ECoG) is used to identify similar functional changes on the cortical surface of the brain, most commonly to identify epileptic focal center(s), or detect seizure activity. [3][4][5][6][7] Other functional uses of ECoG include intraoperative monitoring during tumor resection. [8] A surgeon can ask a patient to perform an activity such as a speech and then identify and avoid the active cortical regions during surgery, to avoid major disruptions to the patient quality of life. StimulationInstead of passively monitoring electrical activity, multielectrode surface arrays can provide electrical current to the underlying tissue and induce a desired excitatory or inhibitory response. The applications for stimulating surface electrode arrays are often therapeutic and include implantable pacemakers, which restore a normal cardiac rhythm by providing external and overriding cues to the cardiomyocytes responsible for establishing a sinus rhythm. [9] Pulses delivered to specific regions of the spinal cord are used to manage chronic pain, [10][11][12] and more recently as a therapy to promote neuronal plasticity in Surface electrode arrays are mainly fabricated from rigid or elastic materials, and precisely manipulated ductile metal films, which offer limited stretchability. However, the living tissues to which they are applied are nonlinear viscoelastic materials, which can undergo significant mechanical deformation in dynamic biological environments. Further, the same arrays and compositions are often repurposed for vastly different tissues rather than optimizing the materials and mechanical properties of the implant for the target application. By first characterizing the desired biological environment, and then designing a technology for a particular organ, surface electrode arrays may be more conformable, and offer better interfaces to tissues while causing less damage. Here, the various materials used in each component of a surface electrode array are first r...

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Long-Term Spinal Cord Stimulation After Chronic Complete Spinal Cord Injury Enables Volitional Movement in the Absence of Stimulation

Cited by 58 publications

References 33 publications

The Effects of Adding Transcutaneous Spinal Cord Stimulation (tSCS) to Sit-To-Stand Training in People with Spinal Cord Injury: A Pilot Study

The Effects of Adding Transcutaneous Spinal Cord Stimulation (tSCS) to Sit-To-Stand Training in People with Spinal Cord Injury: A Pilot Study

Electrical epidural stimulation of the cervical spinal cord: implications for spinal respiratory neuroplasticity after spinal cord injury

Materials for Implantable Surface Electrode Arrays: Current Status and Future Directions

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