Nome |
# |
Complications of epidural spinal stimulation: lessons from the past and alternatives for the future, file dd8a4bf8-bbc3-20a0-e053-d805fe0a8cb0
|
143
|
And yet it moves: Recovery of volitional control after spinal cord injury, file dd8a4bf8-5665-20a0-e053-d805fe0a8cb0
|
78
|
Multilevel Analysis of Locomotion in Immature Preparations Suggests Innovative Strategies to Reactivate Stepping after Spinal Cord Injury, file dd8a4bf7-8e81-20a0-e053-d805fe0a8cb0
|
65
|
And yet it moves: Recovery of volitional control after spinal cord injury, file dd8a4bf8-5664-20a0-e053-d805fe0a8cb0
|
55
|
Using EMG to deliver lumbar dynamic electrical stimulation to facilitate cortico-spinal excitability, file dd8a4bf8-8cd1-20a0-e053-d805fe0a8cb0
|
52
|
Modulation of the activity of the locomotor central pattern generator in the rat spinal cord in vitro, file dd8a4bf7-05b5-20a0-e053-d805fe0a8cb0
|
51
|
Acute neuromodulation restores spinally-induced motor responses after severe spinal cord injury, file dd8a4bf8-b1ae-20a0-e053-d805fe0a8cb0
|
47
|
Neuromodulation of the neural circuits controlling the lower urinary tract, file dd8a4bf7-882b-20a0-e053-d805fe0a8cb0
|
39
|
A “noisy” electrical stimulation protocol favors muscle regeneration in vitro through release of endogenous ATP, file dd8a4bf8-a885-20a0-e053-d805fe0a8cb0
|
39
|
Afferent Input Induced by Rhythmic Limb Movement Modulates Spinal Neuronal Circuits in an Innovative Robotic In Vitro Preparation, file dd8a4bf8-4d64-20a0-e053-d805fe0a8cb0
|
37
|
GABAergic Mechanisms Can Redress the Tilted Balance between Excitation and Inhibition in Damaged Spinal Networks, file dd8a4bf8-fa20-20a0-e053-d805fe0a8cb0
|
36
|
ERG conductance expression modulates the excitability of ventral horn GABAergic interneurons that control rhythmic oscillations in the developing mouse spinal cord, file dd8a4bf8-3efe-20a0-e053-d805fe0a8cb0
|
35
|
Histamine H3 Receptors Expressed in Ventral Horns Modulate Spinal Motor Output, file dd8a4bf8-ab8d-20a0-e053-d805fe0a8cb0
|
30
|
Histamine modulates spinal motoneurons and locomotor circuits, file dd8a4bf7-c4b3-20a0-e053-d805fe0a8cb0
|
29
|
Rat locomotor spinal circuits in vitro are activated by electrical stimulation with noisy waveforms sampled from human gait, file dd8a4bf7-1880-20a0-e053-d805fe0a8cb0
|
22
|
Selective antagonism of A1 adenosinergic receptors strengthens the neuromodulation of sensorimotor network during epidural spinal stimulation, file dd8a4bf9-0224-20a0-e053-d805fe0a8cb0
|
21
|
Nanomolar oxytocin synergizes with weak electrical afferent stimulation to activate the locomotor CPG of the rat spinal cord in vitro., file dd8a4bf7-1a10-20a0-e053-d805fe0a8cb0
|
20
|
Newborn analgesia mediated by oxytocin during delivery, file dd8a4bf7-af49-20a0-e053-d805fe0a8cb0
|
19
|
Differential modulation by tetraethylammonium of the processes underlying network bursting in the neonatal rat spinal cord in vitro, file dd8a4bf7-278f-20a0-e053-d805fe0a8cb0
|
4
|
Passive limb training modulates respiratory rhythmic bursts, file 07d6a489-bbe1-4b6e-8214-eef69908b0bf
|
3
|
Kainate and metabolic perturbation mimicking spinal injury differentially contribute to early damage of locomotor networks in the in vitro neonatal rat spinal cord, file dd8a4bf7-1786-20a0-e053-d805fe0a8cb0
|
3
|
Acute spinal cord injury in vitro: Insight into basic mechanisms, file dd8a4bf7-2364-20a0-e053-d805fe0a8cb0
|
3
|
Staggered multi-site low-frequency electrostimulation effectively induces locomotor patterns in the isolated rat spinal cord, file dd8a4bf7-50d3-20a0-e053-d805fe0a8cb0
|
3
|
Electrical stimulation able to trigger locomotor spinal circuits also induces dorsal horn activity, file dd8a4bf7-6645-20a0-e053-d805fe0a8cb0
|
3
|
Multilevel Analysis of Locomotion in Immature Preparations Suggests Innovative Strategies to Reactivate Stepping after Spinal Cord Injury, file dd8a4bf7-8ac6-20a0-e053-d805fe0a8cb0
|
3
|
Histamine modulates spinal motoneurons and locomotor circuits, file dd8a4bf7-bbb3-20a0-e053-d805fe0a8cb0
|
3
|
Histamine H3 Receptors Expressed in Ventral Horns Modulate Spinal Motor Output, file dd8a4bf8-b503-20a0-e053-d805fe0a8cb0
|
3
|
Mapping lumbar efferent and afferent spinal circuitries via paddle array in a porcine model, file 31bab30b-c4fc-4f56-9599-4d097298b4f0
|
2
|
Oscillatory circuits underlying locomotor networks in the rat spinal cord, file dd8a4bf7-1124-20a0-e053-d805fe0a8cb0
|
2
|
AMPA-evoked acetylcholine release from cultured spinal cord motoneurons and its inhibition by GABA and glycine, file dd8a4bf7-12db-20a0-e053-d805fe0a8cb0
|
2
|
Early spread of hyperexcitability to caudal
dorsal horn networks after a chemically-induced lesion of the rat spinal cord in
vitro, file dd8a4bf7-13ef-20a0-e053-d805fe0a8cb0
|
2
|
Dynamics of early locomotor network dysfunction following
a focal lesion in an in vitro model of spinal injury, file dd8a4bf7-1498-20a0-e053-d805fe0a8cb0
|
2
|
A1 adenosine receptor modulation of chemically and electrically evoked lumbar locomotor network activity in isolated newborn rat spinal cords, file dd8a4bf7-151a-20a0-e053-d805fe0a8cb0
|
2
|
Fictive locomotor patterns generated by tetraethylammonium application to the neonatal rat spinal cord in vitro, file dd8a4bf7-159c-20a0-e053-d805fe0a8cb0
|
2
|
Schwann cell migration and neurite outgrowth are influenced by media conditioned by epineurial fibroblasts, file dd8a4bf7-186e-20a0-e053-d805fe0a8cb0
|
2
|
Extracellular stimulation with human “noisy” electromyographic patterns facilitates myotube activity, file dd8a4bf7-1d82-20a0-e053-d805fe0a8cb0
|
2
|
Characteristics of the electrical oscillations evoked by 4-aminopyridine on dorsal root fibers and their relation to fictive locomotor patterns in the rat spinal cord in vitro, file dd8a4bf7-1da0-20a0-e053-d805fe0a8cb0
|
2
|
GABA(A) and strychnine-sensitive glycine receptors modulate N-methyl-d-aspartate-evoked acetylcholine release from rat spinal motoneurons: A possible role in neuroprotection, file dd8a4bf7-2003-20a0-e053-d805fe0a8cb0
|
2
|
A new model of nerve injury in the rat reveals a role of Regulator of G protein Signaling 4 in tactile hypersensitivity, file dd8a4bf7-562c-20a0-e053-d805fe0a8cb0
|
2
|
Neuromodulation of the neural circuits controlling the lower urinary tract, file dd8a4bf7-5875-20a0-e053-d805fe0a8cb0
|
2
|
Suprapontine Structures Modulate Brainstem and Spinal Networks, file 44d699a3-3e97-4595-9ce0-97699f1bb2a4
|
1
|
Neuromodulation and restoration of motor responses after severe spinal cord injury, file 6b3a6a5f-86fa-49ed-a7cb-f07844fe3e22
|
1
|
Stochastic spinal neuromodulation tunes the intrinsic logic of spinal neural networks, file 799bb016-0c85-4ee6-831a-48cb0a819166
|
1
|
Activation of group I metabotropic glutamate receptors depresses recurrent inhibition of motoneurons in the neonatal rat spinal cord in vitro, file dd8a4bf7-0f3f-20a0-e053-d805fe0a8cb0
|
1
|
Modulation of rhythmic patterns and cumulative depolarization by group I metabotropic glutamate receptors in the neonatal rat spinal cord in vitro, file dd8a4bf7-109c-20a0-e053-d805fe0a8cb0
|
1
|
Anoxic persistence of lumbar respiratory bursts and block of lumbar locomotion in newborn rat brainstem-spinal cords, file dd8a4bf7-1152-20a0-e053-d805fe0a8cb0
|
1
|
Tuning and playing a motor rhythm: how metabotropic glutamate receptors orchestrate generation of motor patterns in the mammalian central nervous system, file dd8a4bf7-121a-20a0-e053-d805fe0a8cb0
|
1
|
Distinct subtypes of group I metabotropic glutamate receptors on rat spinal neurons mediate complex facilitatory and inhibitory effects, file dd8a4bf7-12dd-20a0-e053-d805fe0a8cb0
|
1
|
The locomotor central pattern generator of the rat spinal cord in vitro is optimally activated by noisy dorsal root waveforms, file dd8a4bf7-1459-20a0-e053-d805fe0a8cb0
|
1
|
Co-application of noisy patterned electrical stimuli and NMDA plus serotonin facilitates fictive locomotion in the rat spinal cord, file dd8a4bf7-1566-20a0-e053-d805fe0a8cb0
|
1
|
Electrophysiological effects of 4-aminopyridine on fictive locomotor activity of the rat spinal cord in vitro, file dd8a4bf7-1b88-20a0-e053-d805fe0a8cb0
|
1
|
Effect of metabotropic glutamate receptor activity on rhythmic discharges of the neonatal rat spinal cord in vitro, file dd8a4bf7-27ca-20a0-e053-d805fe0a8cb0
|
1
|
Two Distinct Stimulus Frequencies Delivered Simultaneously at Low Intensity Generate Robust Locomotor Patterns, file dd8a4bf7-6101-20a0-e053-d805fe0a8cb0
|
1
|
Deconstructing locomotor networks with experimental injury to define their membership, file dd8a4bf7-ab35-20a0-e053-d805fe0a8cb0
|
1
|
Low micromolar concentrations of 4-aminopyridine facilitate fictive locomotion expressed by the rat spinal cord in vitro, file dd8a4bf7-b8ff-20a0-e053-d805fe0a8cb0
|
1
|
Afferent Input Induced by Rhythmic Limb Movement Modulates Spinal Neuronal Circuits in an Innovative Robotic In Vitro Preparation, file dd8a4bf8-55eb-20a0-e053-d805fe0a8cb0
|
1
|
A “noisy” electrical stimulation protocol favors muscle regeneration in vitro through release of endogenous ATP, file dd8a4bf8-699e-20a0-e053-d805fe0a8cb0
|
1
|
Dynamic electrical stimulation enhances the recruitment of spinal interneurons by corticospinal input, file ea25bf7f-e13a-475e-8b33-41f7c2f1858b
|
1
|
Totale |
890 |