Epidural Stimulation Induced Modulation of Spinal Locomotor Networks in Adult Spinal Rats

Lavrov, Igor; Dy, Christine J.; Fong, Andy J.; Gerasimenko, Yury; Courtine, Grégoire; Zhong, Hui; Roy, Roland R.; Edgerton, V. Reggie

doi:10.1523/jneurosci.0080-08.2008

Cited by 140 publications

(131 citation statements)

References 41 publications

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“…To encourage locomotion via electrical spinal cord stimulation, rectangular pulses were delivered through L2 and S1 electrodes (40 Hz, 0.2 ms duration, 200-400µA) 9 . …”

Section: Electrochemical Neuroprosthesismentioning

confidence: 99%

Multisystem Neuroprosthetic Training Improves Bladder Function After Severe Spinal Cord Injury

et al. 2013

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BACKGROUND: Severe spinal cord injury (SCI) leads to neurogenic bladder dysfunction. We recently developeda multi-system neuroprosthetic training program (MSNT) that promotes plastic changes capable of restoring refinedlocomotion in rats with severe SCI. We investigated whether MSNTinfluences the formation of posttraumatic bladder dysfunction. MATERIALS AND METHODS: Adult rats were randomly assigned to a SCI (n=8) and to a control intact (n=4) group. SCI consisted of two opposite lateral hemisections (T7, T11), thusinterrupting all direct supraspinal input. After SCI, 4 rats were subjected to MSNT, 4 rats were non-trained. After 8 weekswe performed urodynamics and evaluated kidney function (creatinine, cystatin C). Bladder investigation included morphological, histological and immunohistochemical evaluations. RESULTS: Bladder capacity increased 3-fold in trained and 7-fold in non-trained compared to intact animals. During filling,we found 2.7 ± 1.1 non-voiding contractions (NVC) in trained, compared to 12.6 ± 5.2 in non-trained rats. Bladder morphology was similar in trained and intact rats, non-trained ratsexhibited detrusor hypertrophycharacterized by increased detrusor thickness and decreased connective tissue to smooth muscle ratio. The general nerve density, labeled with PGP9.5, was significantly increased in trained and significantly decreased in non-trained rats. The relative proportion of NF200-postive afferent nerves was significantly lower in trained compared to intact and non-trained rats. NPY-positive fibers showed a significantly lower density in non-trained rats. CONCLUSIONS: MSNT effectively counteracts the formation of neurogenic bladder dysfunction after severe SCI and might contribute to preserving bladder function and preventing long-term complications in patients with severe SCI. MULTI-SYSTEM NEUROPROSTHETIC TRAINING IMPROVES BLADDER FUNCTION AFTER SEVERE SPINAL CORD INJURY

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“…To encourage locomotion via electrical spinal cord stimulation, rectangular pulses were delivered through L2 and S1 electrodes (40 Hz, 0.2 ms duration, 200-400µA) 9 . …”

Section: Electrochemical Neuroprosthesismentioning

confidence: 99%

Multisystem Neuroprosthetic Training Improves Bladder Function After Severe Spinal Cord Injury

et al. 2013

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“…It may provide a new therapeutic approach to complete SCI, as well as objective, electrophysiological proofs for the autonomous activity of lumbar CPG. Studies on both lab animals 61 and humans (a total of 10 patients) showed that low frequency electrical stimulation (2.2-50 Hz) with epidural electrodes elicited stepping-like movements; although a synergistic activation of kinematic chains (triple flexions alternating with extensions) was observed, it is obvious that a functional gait could not be achieved. 62,63 It should be noted that this technique involves some significant risks for the patient, such as infections, local hemorrhages, etc.…”

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confidence: 99%

A review of published reports on neuroprotection in spinal cord injury

et al. 2009

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Study design: Literature review. Objectives: To review the main published current neuroprotection research trends and results in spinal cord injury (SCI). Setting: This paper is the result of a collaboration between a group of European scientists. Methods: Recent studies, especially in genetic, immune, histochemical and bio (nano)-technological fields, have provided new insight into the cellular and molecular mechanisms occurring within the central nervous system (NS), including SCIs. As a consequence, a new spectrum of therapies aiming to antagonize the 'secondary injury' pathways (that is, to provide neuroprotection) and also to repair such classically irreparable structures is emerging. We reviewed the most significant published works related to such novel, but not yet entirely validated, clinical practice therapies. Results: There have been identified many molecules, primarily expressed by heterogenous glial and neural subpopulations of cells, which are directly or indirectly critical for tissue damaging/sparing/ re-growth inhibiting, angiogenesis and neural plasticity, and also various substances/energy vectors with regenerative properties, such as MAG (myelin-associated glycoprotein), Omgp (oligodendrocyte myelin glycoprotein), KDI (synthetic: Lysine-Asparagine-Isoleucine 'g-1 of Laminin Kainat Domain'), Nogo (Neurite outgrowth inhibitor), NgR (Nogo protein Receptor), the Rho signaling pathway (superfamily of 'Rho-dopsin geneFincluding neurotransmitterFreceptors'), EphA4 (Ephrine), GFAP (Glial Fibrillary Acidic Protein), different subtypes of serotonergic and glutamatergic receptors, antigens, antibodies, immune modulators, adhesion molecules, scavengers, neurotrophic factors, enzymes, hormones, collagen scar inhibitors, remyelinating agents and neurogenetic/plasticity inducers, all aiming to preserve/re-establish the morphology and functional connections across the lesion site. Accordingly, modern research and experimental SCI therapies focus on several intricate, rather overlapping, therapeutic objectives and means, such as neuroprotective, neurotrophic, neurorestorative, neuroreparative, neuroregenerative, neuro(re)constructive and neurogenetic interventions. Conclusion: The first three of these therapeutical directions are generically assimilated as neuroprotective, and are synthetically presented and commented in this paper in an attempt to conceptually systematize them; thus, the aim of this article is, by emphasizing the state-of-the art in the domain, to optimize theoretical support in selecting the most effective pharmacological and physical interventions for preventing, as much as possible, paralysis, and for maximizing recovery chances after SCI.

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“…The lack of effectiveness of electrical stimulation can be attributed to the filtering effect of CPG interneurons receiving synaptic inputs from the spinal rhythm generator to gate the flow of sensory information in the spinal cord (Sillar 1991). Interestingly, a better outcome is observed when stimuli are applied close to the spinal cord region, which putatively contains the CPG (Kiehn and Butt 2003), using epidural (Lavrov et al 2008a(Lavrov et al , 2008b or intraspinal (Gaunt et al 2006) electrodes.…”

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confidence: 99%

Coapplication of noisy patterned electrical stimuli and NMDA plus serotonin facilitates fictive locomotion in the rat spinal cord

Dose

Taccola

2012

Journal of Neurophysiology

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, consisting of intrinsically variable weak waveforms applied to a single dorsal root is very effective (though not optimal as it eventually wanes away) in activating the locomotor program of the isolated rat spinal cord. The present study explored whether combination of FListim with low doses of pharmacological agents that raise network excitability might further improve the functional outcome, using this in vitro model. FListim was applied together with N-methyl-D-aspartate (NMDA) ϩ serotonin, while fictive locomotion (FL) was electrophysiologically recorded from lumbar ventral roots. Superimposing FListim on FL evoked by these neurochemicals persistently accelerated locomotorlike cycles to a set periodicity and modulated cycle amplitude depending on FListim rate. Trains of stereotyped rectangular pulses failed to replicate this phenomenon. The GABA B agonist baclofen dose dependently inhibited, in a reversible fashion, FL evoked by either FListim or square pulses. Sustained episodes of FL emerged when FListim was delivered, at an intensity subthreshold for FL, in conjunction with subthreshold pharmacological stimulation. Such an effect was, however, not found when high potassium solution instead of NMDA ϩ serotonin was used. These results suggest that the combined action of subthreshold FListim (e.g., via epidural stimulation) and neurochemicals should be tested in vivo to improve locomotor rehabilitation after injury. In fact, reactivation of spinal locomotor circuits by conventional electrical stimulation of afferent fibers is difficult, while pharmacological activation of spinal networks is clinically impracticable due to concurrent unwanted effects. We speculate that associating subthreshold chemical and electrical inputs might decrease side effects when attempting to evoke human locomotor patterns. fictive locomotion; central pattern generator; dorsal root train; FListim IN THE ISOLATED SPINAL CORD of the neonatal rat, episodes of locomotor-like oscillations can be recorded from lumbar (L) 2 and L5 ventral roots (VRs), alternating between the left and right sides of the cord, due to rhythmic activation of flexor and extensor motor pools, respectively

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Epidural Stimulation Induced Modulation of Spinal Locomotor Networks in Adult Spinal Rats

Cited by 140 publications

References 41 publications

Multisystem Neuroprosthetic Training Improves Bladder Function After Severe Spinal Cord Injury

Multisystem Neuroprosthetic Training Improves Bladder Function After Severe Spinal Cord Injury

A review of published reports on neuroprotection in spinal cord injury

Coapplication of noisy patterned electrical stimuli and NMDA plus serotonin facilitates fictive locomotion in the rat spinal cord

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