Your search keyword '"Taccola G"' showing total 6 results

1. Dynamic electrical stimulation enhances the recruitment of spinal interneurons by corticospinal input.

Author

Taccola G, Kissane R, Culaclii S, Apicella R, Liu W, Gad P, Ichiyama RM, Chakrabarty S, and Edgerton VR

Subjects

Humans, Evoked Potentials, Motor physiology, Electric Stimulation, Interneurons, Spinal Cord, Pyramidal Tracts physiology, Spinal Cord Injuries, Spinal Cord Stimulation

Abstract

Highly varying patterns of electrostimulation (Dynamic Stimulation, DS) delivered to the dorsal cord through an epidural array with 18 independent electrodes transiently facilitate corticospinal motor responses, even after spinal injury. To partly unravel how corticospinal input are affected by DS, we introduced a corticospinal platform that allows selective cortical stimulation during the multisite acquisition of cord dorsum potentials (CDPs) and the simultaneous supply of DS. Firstly, the epidural interface was validated by the acquisition of the classical multisite distribution of CDPs and their input-output profile elicited by pulses delivered to peripheral nerves. Apart from increased EMGs, DS selectively increased excitability of the spinal interneurons that first process corticospinal input, without changing the magnitude of commands descending from the motor cortex, suggesting a novel correlation between muscle recruitment and components of cortically-evoked CDPs. Finally, DS increases excitability of post-synaptic spinal interneurons at the stimulation site and their responsiveness to any residual supraspinal control, thus supporting the use of electrical neuromodulation whenever the motor output is jeopardized by a weak volitional input, due to a partial disconnection from supraspinal structures and/or neuronal brain dysfunctions., Competing Interests: Declaration of Competing Interest VRE, a researcher on the study team holds shareholder interest in Onward and holds certain inventorship rights on intellectual property licensed by The Regents of the University of California to Onward. VRE, and PG, researchers on the study team hold shareholder interest in SpineX Inc. PG is an employee of SpineX Inc. WL holds shareholder interest in Aneuvo as well as inventorship of IPs licensed by The Regents of the University of California to Aneuvo., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

2. Stochastic spinal neuromodulation tunes the intrinsic logic of spinal neural networks.

Author

Taccola G, Ichiyama RM, Edgerton VR, and Gad P

Subjects

Humans, Logic, Movement, Neural Networks, Computer, Spinal Cord, Spinal Cord Injuries therapy

Abstract

The present review focuses on the physiological states of spinal networks, which are stochastically modulated by continuously changing ensembles of proprioceptive and supraspinal input resulting in highly redundant neural networks. Spinal epidural interfaces provide a platform for probing spinal network dynamics and connectivity among multiple motor pool-specific spinal networks post-injury under in vivo experimental conditions. Continuous epidural low-frequency pulses at low intensity can evoke motor responses of stochastically changing amplitudes and with an oscillatory pattern of modulation. The physiological significance of this oscillatory pattern, intrinsic to "resting" spinal networks and observed in both uninjured and injured locomotor circuits, is unclear. This neural variability among spinal networks appears to be a fundamental mechanism of the network's design and not a "noise" interfering with movement control. Data to date also suggest that the greater the level of stimulation above motor threshold, the greater the loss of modulation over the motor output that is physiologically provided by interneuronal networks, which integrate naturally occurring proprioceptive and cutaneous input generated during movement. Sub-motor threshold spinal electrical stimulation experiments demonstrate a range of functional improvements of multiple physiological systems when used in concert with sensorimotor training after spinal cord injury. Although our understanding of the systemic, cellular and molecular modulatory mechanisms that trigger these activity-dependent adaptive processes remain incomplete, some basic physiological principles have evolved, at least at the systemic and neural network levels and to some degree at the cellular level., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

3. Acute neuromodulation restores spinally-induced motor responses after severe spinal cord injury.

Author

Taccola G, Gad P, Culaclii S, Wang PM, Liu W, and Edgerton VR

Subjects

Animals, Electromyography, Female, Lumbar Vertebrae, Rats, Rats, Sprague-Dawley, Recovery of Function physiology, Spinal Cord Injuries physiopathology, Evoked Potentials, Motor physiology, Spinal Cord physiopathology, Spinal Cord Injuries therapy, Spinal Cord Stimulation methods

Abstract

Epidural electrical spinal stimulation can facilitate recovery of volitional motor control in individuals that have been completely paralyzed for more than a year. We recently reported a novel neuromodulation method named Dynamic Stimulation (DS), which short-lastingly increased spinal excitability and generated a robust modulation of locomotor networks in fully-anesthetized intact adult rats. In the present study, we applied repetitive DS patterns to four lumbosacral segments acutely after a contusive injury at lumbar level. Repetitive DS delivery restored the spinally-evoked motor EMG responses that were previously suppressed by a calibrated spinal cord contusion. Sham experiments without DS delivery did not allow any spontaneous recovery. Thus, DS uniquely provides the potential for a greater long-term functional recovery after paralysis., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

4. A "noisy" electrical stimulation protocol favors muscle regeneration in vitro through release of endogenous ATP.

Author

Bosutti A, Bernareggi A, Massaria G, D'Andrea P, Taccola G, Lorenzon P, and Sciancalepore M

Subjects

Animals, Electric Stimulation, Electromyography, Male, Mice, Mice, Inbred C57BL, Muscle Development, Myoblasts, Skeletal physiology, Myogenin metabolism, PAX7 Transcription Factor metabolism, Adenosine Triphosphate metabolism, Muscle Fibers, Skeletal physiology, Regeneration

Abstract

An in vitro system of electrical stimulation was used to explore whether an innovative "noisy" stimulation protocol derived from human electromyographic recordings (EMGstim) could promote muscle regeneration. EMGstim was delivered to cultured mouse myofibers isolated from Flexor Digitorum Brevis, preserving their satellite cells. In response to EMGstim, immunostaining for the myogenic regulatory factor myogenin, revealed an increased percentage of elongated myogenin-positive cells surrounding the myofibers. Conditioned medium collected from EMGstim-treated cell cultures, promoted satellite cells differentiation in unstimulated myofiber cell cultures, suggesting that extracellular soluble factors could mediate the process. Interestingly, the myogenic effect of EMGstim was mimicked by exogenously applied ATP (0.1 μM), reduced by the ATP diphosphohydrolase apyrase and prevented by blocking endogenous ATP release with carbenoxolone. In conclusion, our results show that "noisy" electrical stimulations favor muscle progenitor cell differentiation most likely via the release of endogenous ATP from contracting myofibres. Our data also suggest that "noisy" stimulation protocols could be potentially more efficient than regular stimulations to promote in vivo muscle regeneration after traumatic injury or in neuropathological diseases., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

5. A new model of nerve injury in the rat reveals a role of Regulator of G protein Signaling 4 in tactile hypersensitivity.

Author

Taccola G, Doyen PJ, Damblon J, Dingu N, Ballarin B, Steyaert A, Rieux AD, Forget P, Hermans E, Bosier B, and Deumens R

Subjects

Action Potentials drug effects, Action Potentials physiology, Analysis of Variance, Animals, Benzothiazoles pharmacology, Biophysics, Calcium-Binding Proteins metabolism, Disease Models, Animal, Electric Stimulation, Female, Functional Laterality, Ganglia, Spinal drug effects, Ganglia, Spinal metabolism, Glial Fibrillary Acidic Protein metabolism, Hyperalgesia metabolism, Hyperalgesia pathology, Microfilament Proteins metabolism, Pain Threshold drug effects, Pain Threshold physiology, Peripheral Nerve Injuries metabolism, Pyrimidines pharmacology, RGS Proteins antagonists & inhibitors, RGS Proteins genetics, RNA, Messenger metabolism, Rats, Rats, Sprague-Dawley, Spinal Cord Dorsal Horn drug effects, Spinal Cord Dorsal Horn metabolism, Time Factors, Up-Regulation drug effects, Hyperalgesia etiology, Peripheral Nerve Injuries complications, RGS Proteins metabolism, Up-Regulation physiology

Abstract

Tactile hypersensitivity is one of the most debilitating symptoms of neuropathic pain syndromes. Clinical studies have suggested that its presence at early postoperative stages may predict chronic (neuropathic) pain after surgery. Currently available animal models are typically associated with consistent tactile hypersensitivity and are therefore limited to distinguish between mechanisms that underlie tactile hypersensitivity as opposed to mechanisms that protect against it. In this study we have modified the rat model of spared nerve injury, restricting the surgical lesion to a single peripheral branch of the sciatic nerve. This modification reduced the prevalence of tactile hypersensitivity from nearly 100% to approximately 50%. With this model, we here also demonstrated that the Regulator of G protein Signaling 4 (RGS4) was specifically up-regulated in the lumbar dorsal root ganglia and dorsal horn of rats developing tactile hypersensitivity. Intrathecal delivery of the RGS4 inhibitor CCG63802 was found to reverse tactile hypersensitivity for a 1h period. Moreover, tactile hypersensitivity after modified spared nerve injury was most frequently persistent for at least four weeks and associated with higher reactivity of glial cells in the lumbar dorsal horn. Based on these data we suggest that this new animal model of nerve injury represents an asset in understanding divergent neuropathic pain outcomes, so far unravelling a role of RGS4 in tactile hypersensitivity. Whether this model also holds promise in the study of the transition from acute to chronic pain will have to be seen in future investigations., (Copyright © 2016. Published by Elsevier Inc.)

Published

2016

6. Neuromodulation of the neural circuits controlling the lower urinary tract.

Author

Gad PN, Roy RR, Zhong H, Gerasimenko YP, Taccola G, and Edgerton VR

Subjects

Animals, Disease Models, Animal, Electrodes, Implanted, Electromyography, Evoked Potentials, Motor physiology, Exercise Therapy, Female, Hindlimb innervation, Locomotion physiology, Muscle, Skeletal physiopathology, Peripheral Nerves physiology, Rats, Rats, Sprague-Dawley, Electric Stimulation Therapy, Neural Pathways physiology, Spinal Cord Injuries complications, Spinal Cord Injuries therapy, Urinary Tract physiopathology, Urination physiology

Abstract

The inability to control timely bladder emptying is one of the most serious challenges among the many functional deficits that occur after a spinal cord injury. We previously demonstrated that electrodes placed epidurally on the dorsum of the spinal cord can be used in animals and humans to recover postural and locomotor function after complete paralysis and can be used to enable voiding in spinal rats. In the present study, we examined the neuromodulation of lower urinary tract function associated with acute epidural spinal cord stimulation, locomotion, and peripheral nerve stimulation in adult rats. Herein we demonstrate that electrically evoked potentials in the hindlimb muscles and external urethral sphincter are modulated uniquely when the rat is stepping bipedally and not voiding, immediately pre-voiding, or when voiding. We also show that spinal cord stimulation can effectively neuromodulate the lower urinary tract via frequency-dependent stimulation patterns and that neural peripheral nerve stimulation can activate the external urethral sphincter both directly and via relays in the spinal cord. The data demonstrate that the sensorimotor networks controlling bladder and locomotion are highly integrated neurophysiologically and behaviorally and demonstrate how these two functions are modulated by sensory input from the tibial and pudental nerves. A more detailed understanding of the high level of interaction between these networks could lead to the integration of multiple neurophysiological strategies to improve bladder function. These data suggest that the development of strategies to improve bladder function should simultaneously engage these highly integrated networks in an activity-dependent manner., (Copyright © 2016. Published by Elsevier Inc.)

Published

2016