Involuntary stepping after chronic spinal cord injury

Calancie, Blair; Needham-Shropshire, Belinda M.; Jacobs, Patrick L.; Willer, Keith; Zych, Gregory A.; Green, Barth A.

doi:10.1093/brain/117.5.1143

Cited by 316 publications

(49 citation statements)

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“…In turn, it has been possible to activate the locomotor CPG by administration i.t., of a variety of pharmacological agents to acutely spinalized marmoset monkeys (Callithrix jacchus) in the absence of phasic afferent input to the spinal cord (Fedirchuk et al, 1998). Spontaneous expression, within weeks or months post-SCI, of rhythmic movements (myoclonus or locomotor-like movements) in humans have also been reported (Pozos and Iaizzo, 1991; Bussel et al, 1992, 1988; Calancie et al, 1994; Chervin et al, 2003; Calancie, 2006; Consentino et al, 2006; Gerasimenko et al, 2008, 2010; Nadeau et al, 2010; Field-Fote et al, 2012; Gorodnichev et al, 2012; Rye and Trotti, 2012). …”

Section: Cpgs In Humans: Evidence From Direct Stimulation and Spontanmentioning

confidence: 94%

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Preclinical evidence supporting the clinical development of central pattern generator-modulating therapies for chronic spinal cord-injured patients

Guertin

2014

Front. Hum. Neurosci.

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Ambulation or walking is one of the main gaits of locomotion. In terrestrial animals, it may be defined as a series of rhythmic and bilaterally coordinated movement of the limbs which creates a forward movement of the body. This applies regardless of the number of limbs—from arthropods with six or more limbs to bipedal primates. These fundamental similarities among species may explain why comparable neural systems and cellular properties have been found, thus far, to control in similar ways locomotor rhythm generation in most animal models. The aim of this article is to provide a comprehensive review of the known structural and functional features associated with central nervous system (CNS) networks that are involved in the control of ambulation and other stereotyped motor patterns—specifically Central Pattern Generators (CPGs) that produce basic rhythmic patterned outputs for locomotion, micturition, ejaculation, and defecation. Although there is compelling evidence of their existence in humans, CPGs have been most studied in reduced models including in vitro isolated preparations, genetically-engineered mice and spinal cord-transected animals. Compared with other structures of the CNS, the spinal cord is generally considered as being well-preserved phylogenetically. As such, most animal models of spinal cord-injured (SCI) should be considered as valuable tools for the development of novel pharmacological strategies aimed at modulating spinal activity and restoring corresponding functions in chronic SCI patients.

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Section: Cpgs In Humans: Evidence From Direct Stimulation and Spontanmentioning

confidence: 94%

“…No clear answer exists in humans (Calancie et al, 1994; Byrnes et al, 2006). However, related spontaneous plasticity events have clearly been shown in animal models to be associated with some immediate early gene expression (IEG) in CPG-corresponding areas of the spinal cord.…”

Section: Cpgs In Humans: Evidence From Direct Stimulation and Spontanmentioning

confidence: 99%

Preclinical evidence supporting the clinical development of central pattern generator-modulating therapies for chronic spinal cord-injured patients

Guertin

2014

Front. Hum. Neurosci.

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“…A variety of studies have defined intersegmental neuronal networks in the lumbar spinal cord region that are responsible for simple hindlimb locomotion (5,127,138). These are known as central pattern generators, and evidence suggests that similar generators are found in primate and human spinal cord (28,44,106). Although central pattern generators are under the influence of primary afferents and descending pathways, locomotor activity can be generated without these inputs (105).…”

Section: Intraspinal Transplantsmentioning

confidence: 99%

“…One strategy for achieving this goal is the use of fetal cells, which provide a substrate with both embryonic neurons and neurotrophic factors that may promote axon regeneration or may provide remyelinating substrates that will enhance electrical conduction in the population of spared but demyelinated axons. Schwann cell/peripheral nerve conduits, oligodendrocytes, and, recently, olfactory ensheathing cells have all been used as substrates for promoting remyelination in the spinal cord after SCI (16,28,35,62,75,79,98,109,112,111,139,151,152). More recently, pluripotent stem cells have been proposed as a restorative substrate after SCI (133,136,148).…”

Section: Intraspinal Transplantsmentioning

confidence: 99%

Olfactory Ensheathing Cells: Bridging the Gap in Spinal Cord Injury

2000

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Spinal cord injury (SCI) continues to be an insidious and challenging problem for scientists and clinicians. Recent neuroscientific advances have changed the pessimistic notion that axons are not capable of significant extension after transection. The challenges of recovering from SCI have been broadly divided into four areas: 1) cell survival; 2) axon regeneration (growth); 3) correct targeting by growing axons; and 4) establishment of correct and functional synaptic appositions. After acute SCI, there seems to be a therapeutic window of opportunity within which the devastating consequences of the secondary injury can be ameliorated. This is supported by several observations in which apoptotic glial cells have been identified up to 1 week after acute SCI. Moreover, autopsy studies have identified anatomically preserved but unmyelinated axons that could potentially subserve normal physiological properties. These observations suggest that therapeutic strategies after SCI can be directed into two broad modalities: 1) prevention or amelioration of the secondary injury, and 2) restorative or regenerative interventions. Intraspinal transplants have been used after SCI as a means for restoring the severed neuraxis. Fetal cell transplants and, more recently, progenitor cells have been used to restore intraspinal circuitry or to serve as relay for damaged axons. In an attempt to remyelinate anatomically preserved but physiologically disrupted axons, newer therapeutic interventions have incorporated the transplantation of myelinating cells, such as Schwann cells, oligodendrocytes, and olfactory ensheathing cells. Of these cells, the olfactory ensheathing cells have become a more favorable candidate for extensive remyelination and axonal regeneration. Olfactory ensheathing cells are found along the full length of the olfactory nerve, from the basal lamina of the epithelium to the olfactory bulb, crossing the peripheral nervous system-central nervous system junction. In vitro, these cells promote robust axonal growth, in part through cell adhesion molecules and possibly by secretion of neurotrophic growth factors that support axonal elongation and extension. In animal models of SCI, transplantation of ensheathing cells supports axonal remyelination and extensive migration throughout the length of the spinal cord. Although the specific properties of these cells that govern enhanced axon regeneration remain to be elucidated, it seems certain that they will contribute to the establishment of new horizons in SCI research.

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“…For patients with a completely transected spinal cord, it is possible to induce, modulate and stop rhythmic contractions of the trunk and lower limb extensor muscles; however, these rhythmic contractions never occurred spontaneously and had only a one-step cycle duration (Bussel et al 1996). On the other hand, for patients with incomplete lesions, several studies reported subjects with the presence of alternating flexor and extensor activity (Calancie et al 1994). …”

Section: Introductionmentioning

confidence: 99%

Interlimb coordination in body-weight supported locomotion: A pilot study

Seiterle

Susko

Artemiadis

et al. 2015

Journal of Biomechanics

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Locomotion involves complex neural networks responsible for automatic and volitional actions. During locomotion, motor strategies can rapidly compensate for any obstruction or perturbation that could interfere with forward progression. In this pilot study, we examined the contribution of interlimb pathways for evoking muscle activation patterns in the contralateral limb when a unilateral perturbation was applied and in the case where body weight was externally supported. In particular, the latency of neuromuscular responses was measured, while the stimulus to afferent feedback was limited. The pilot experiment was conducted with six healthy young subjects. It employed the MIT-Skywalker (beta-prototype), a novel device intended for gait therapy. Subjects were asked to walk on the split-belt treadmill, while a fast unilateral perturbation was applied mid-stance by unexpectedly lowering one side of the split-treadmill walking surfaces. Subject's weight was externally supported via the body-weight support system consisting of an underneath bicycle seat and the torso was stabilized via a loosely fitted chest harness. Both the weight support and the chest harness limited the afferent feedback. The unilateral perturbations evoked changes in the electromyographic activity of the non-perturbed contralateral leg. The latency of all muscle responses exceeded 100 ms, which precludes the conjecture that spinal cord alone is responsible for the perturbation response. It suggests the role of supraspinal or midbrain level pathways at the inter-leg coordination during gait.

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Involuntary stepping after chronic spinal cord injury

Cited by 316 publications

References 0 publications

Preclinical evidence supporting the clinical development of central pattern generator-modulating therapies for chronic spinal cord-injured patients

Preclinical evidence supporting the clinical development of central pattern generator-modulating therapies for chronic spinal cord-injured patients

Olfactory Ensheathing Cells: Bridging the Gap in Spinal Cord Injury

Interlimb coordination in body-weight supported locomotion: A pilot study

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