Electrical Stimulation of Spared Corticospinal Axons Augments Connections with Ipsilateral Spinal Motor Circuits after Injury

Brus-Ramer, Marcel; Carmel, Jason B.; Chakrabarty, Samit; Martin, John H.

doi:10.1523/jneurosci.3489-07.2007

Cited by 172 publications

(252 citation statements)

References 43 publications

(50 reference statements)

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“…Unilateral cortical injury or pyramidotomy also deprives the spinal cord unilaterally of direct cortical input. In adult rodents, sprouting of the CST from the intact side across the midline can be induced by suppression of the neurite growth inhibitor Nogo pathway (Thallmair et al, 1998;Wiessner et al, 2003), by local neurotrophic factors (Zhou and Shine, 2003), or by electrical stimulation of the injury-spared CST (Brus-Ramer et al, 2007). The rearranged CST is crucial for the observed recovery of skilled movements (Kartje-Tillotson et al, 1987).…”

Section: Introductionmentioning

confidence: 99%

Functional and Anatomical Reorganization of the Sensory-Motor Cortex after Incomplete Spinal Cord Injury in Adult Rats

Ghosh¹,

Sydekum²,

Haiss³

et al. 2009

J. Neurosci.

157

112

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A lateral hemisection injury of the cervical spinal cord results in Brown-Séquard syndrome in humans and rats. The hands/forelimbs on the injured side are rendered permanently impaired, but the legs/hindlimbs recover locomotor functions. This is accompanied by increased use of the forelimb on the uninjured side. Nothing is known about the cortical circuits that correspond to these behavioral adaptations. In this study, on adult rats with cervical spinal cord lateral hemisection lesions (at segment C3/4), we explored the sensory representation and corticospinal projection of the intact (ipsilesional) cortex. Using blood oxygenation level-dependent functional magnetic resonance imaging and voltage-sensitive dye (VSD) imaging, we found that the cortex develops an enhanced representation of the unimpaired forepaw by 12 weeks after injury. VSD imaging also revealed the cortical spatio-temporal dynamics in response to electrical stimulation of the ipsilateral forepaw or hindpaw. Interestingly, stimulation of the ipsilesional hindpaw at 12 weeks showed a distinct activation of the hindlimb area in the intact, ipsilateral cortex, probably via the injury-spared spinothalamic pathway. Anterograde tracing of corticospinal axons from the intact cortex showed sprouting to recross the midline, innervating the spinal segments below the injury in both cervical and lumbar segments. Retrograde tracing of these midline-crossing axons from the cervical spinal cord (at segment C6/7) revealed the formation of a new ipsilateral forelimb representation in the cortex. Our results demonstrate profound reorganizations of the intact sensory-motor cortex after unilateral spinal cord injury. These changes may contribute to the behavioral adaptations, notably for the recovery of the ipsilesional hindlimb.

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Section: Introductionmentioning

confidence: 99%

Functional and Anatomical Reorganization of the Sensory-Motor Cortex after Incomplete Spinal Cord Injury in Adult Rats

Ghosh¹,

Sydekum²,

Haiss³

et al. 2009

J. Neurosci.

157

112

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“…In the absence of any resources on the paretic side, however, where ipsilesional motor systems are damaged beyond threshold level, harnessing contralesional activity may be partially adaptive through formation of atypical connections [60][61][62].…”

Section: Alternate Substrates and Their Role In Recovery: Contralesiomentioning

confidence: 99%

Invasive Neurostimulation in Stroke Rehabilitation

Plow

Machado

2014

Neurotherapeutics

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The last decade has seen a growing interest in adjuvant treatments that synergistically influence mechanisms underlying rehabilitation of paretic upper limb in stroke. One such approach is invasive neurostimulation of spared cortices at the periphery of a lesion. Studies in animals have shown that during training of paretic limb, adjuvant stimulation targeting the peri-infarct circuitry enhances mechanisms of its reorganization, generating functional advantage. Success of early animal studies and clinical reports, however, failed to translate to a phase III clinical trial. As lesions in humans are diffuse, unlike many animal models, peri-infarct circuitry may not be a feasible, or consistent target across most. Instead, alternate mechanisms, such as changing transcallosal inhibition between hemispheres, or reorganization of other viable regions in motor control, may hold greater potential. Here, we review comprehensive mechanisms of clinical recovery and factors that govern which mechanism(s) become operative when. We suggest novel approaches that take into account a patient's initial clinical-functional state, and findings from neuroimaging and neurophysiology to guide to their most suitable mechanism for ideal targeting. Further, we suggest new localization schemes, and bypass strategies that indirectly target peri-lesional circuitry, and methods that serve to counter technical and theoretical challenge in identifying and stimulating such targets at the periphery of infarcts in humans. Last, we describe how stimulation may modulate mechanisms differentially across varying phases of recovery-a temporal effect that may explain missed advantage in clinical trials and help plan for the next stage. With information presented here, future trials would effectively be able to target patient's specific mechanism(s) with invasive (or noninvasive) neurostimulation for the greatest, most consistent benefit. [2], which remains one of the most important predictors of disability and poor quality of life [3]. Disability adds to the costs of disease management that total $74 billion/ year [4]. Developing methods to effectively alleviate residual deficits will reduce health and economic burden of stroke.Several evidence-based rehabilitative approaches have been developed with prominent ones, including neuromuscular electrical stimulation [5], motor learning [6], robotic training [7] constraint-induced movement therapy [8], and bilateral arm training [9], etc. In spite of extensive therapy, recovery is frequently incomplete [10]. There is a critical need for adjuvant strategies that augment rehabilitative outcomes of paretic hand.The last decade has seen a growing interest in the promise of adjuvant treatments that synergistically influence mechanisms associated with rehabilitation. One such approach is invasive neuromodulation, involving electrical stimulation applied to cortical or subcortical targets spared by stroke. By directly stimulating viable targets, it is believed that potential for plasticity underlying reh...

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“…One approach to facilitate motor recovery after neurotrauma is to target intact or spared pathways. For example, in a recent study published in The Journal of Neuroscience, spared corticospinal axons were chronically stimulated to strengthen their connections with spinal circuits in adult rats (Brus-Ramer et al, 2007). Results indicated that activity-dependent mechanisms facilitate plasticity of spared ipsilateral corticospinal axons after injury.…”

mentioning

confidence: 99%

“…For example, in a recent study published in The Journal of Neuroscience, spared corticospinal axons were chronically stimulated to strengthen their connections with spinal circuits in adult rats (Brus-Ramer et al, 2007). Results indicated that activity-dependent mechanisms facilitate plasticity of spared ipsilateral corticospinal axons after injury.In the study by Brus-Ramer et al (2007), the left pyramidal tract of adult rats was lesioned, abolishing corticospinal projections to the ipsilateral and contralateral spinal cord. In some rats, an electrode was placed over the right pyramidal tract to chronically stimulate spared corticospinal axons after lesion.…”

mentioning

confidence: 99%

“…The relative proportions of ipsilateral corticospinal presynaptic terminals contacting different types of postsynaptic partners could be determined and compared between groups. More direct synaptic contacts with motoneurons could indicate that spared ipsilateral corticospinal axons are attempting to form new and more direct spinal motor circuits.To determine whether structural changes correlated with an increased transmission efficacy of spared corticospinal axons, Brus-Ramer et al (2007) stimulated the intact pyramid and recorded the electroneurogram of the deep radial nerves. This allowed them to determine the motor thresholds (that is, the threshold of stimulation required to evoke a response in the nerve) of intact ipsilateral and contralateral corticospinal projections in all groups of rats.…”

mentioning

confidence: 99%

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Strengthening Corticospinal Connections with Chronic Electrical Stimulation after Injury

Frigon

Yakovenko²,

Gritsenko³

et al. 2008

J. Neurosci.

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Damage to descending tracts from supraspinal structures impairs motor function below the level of the lesion, and efforts are being made to elucidate the mechanisms promoting the recovery process. One approach to facilitate motor recovery after neurotrauma is to target intact or spared pathways. For example, in a recent study published in The Journal of Neuroscience, spared corticospinal axons were chronically stimulated to strengthen their connections with spinal circuits in adult rats (Brus-Ramer et al., 2007). Results indicated that activity-dependent mechanisms facilitate plasticity of spared ipsilateral corticospinal axons after injury.In the study by Brus-Ramer et al. (2007), the left pyramidal tract of adult rats was lesioned, abolishing corticospinal projections to the ipsilateral and contralateral spinal cord. In some rats, an electrode was placed over the right pyramidal tract to chronically stimulate spared corticospinal axons after lesion. The intact ipsilateral corticospinal tract was subsequently examined using electrophysiological and anatomical techniques. Comparisons were made between intact rats, rats with lesion only, rats with corticospinal stimulation only, and lesioned rats that underwent stimulation.To compare the extent of axon collateral sprouting and synapse formation between groups, the anterograde tracers biotinylated dextran amine (BDA) and Lucifer yellow-dextran amine were injected into "spared" and "lesioned" motor cortices, respectively, 2 weeks before the pyramidal tract lesion. The authors found that total axon length, density of terminations, and boutons from spared ipsilateral corticospinal axons increased in the cervical spinal gray matter with injury or stimulation alone, but the combined lesionplus-stimulation group displayed the largest effect [Brus-Ramer et al. (2007), their High-resolution electron microscopy would be necessary to show conclusively what neurons the spared ipsilateral corticospinal axons synapse onto. Because BDA labeling is revealed with diaminobenzidine, which precipitates into an electron-dense reaction product, the BDA-labeled ipsilateral corticospinal presynaptic terminals could be visualized directly and their postsynaptic partners identified using retrograde tracers, immunocytochemical markers, or morphological criteria. The relative proportions of ipsilateral corticospinal presynaptic terminals contacting different types of postsynaptic partners could be determined and compared between groups. More direct synaptic contacts with motoneurons could indicate that spared ipsilateral corticospinal axons are attempting to form new and more direct spinal motor circuits.To determine whether structural changes correlated with an increased transmission efficacy of spared corticospinal axons, Brus-Ramer et al. (2007) stimulated the intact pyramid and recorded the electroneurogram of the deep radial nerves. This allowed them to determine the motor thresholds (that is, the threshold of stimulation required to evoke a response in the nerve) of intact ipsilateral...

show abstract

Electrical Stimulation of Spared Corticospinal Axons Augments Connections with Ipsilateral Spinal Motor Circuits after Injury

Cited by 172 publications

References 43 publications

Functional and Anatomical Reorganization of the Sensory-Motor Cortex after Incomplete Spinal Cord Injury in Adult Rats

Functional and Anatomical Reorganization of the Sensory-Motor Cortex after Incomplete Spinal Cord Injury in Adult Rats

Invasive Neurostimulation in Stroke Rehabilitation

Strengthening Corticospinal Connections with Chronic Electrical Stimulation after Injury

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