Refinements of hybrid neurophysical volume conductor models and application to study epidural electrical stimulation of the cervical spinal cord

Nathan Antoine Greiner
EPFL, 2020
Thèse EPFL

Résumé

After spinal cord injury (SCI), the communication between the brain and spinal neural circuits below the lesion is disrupted, leading to paralysis. Epidural electrical stimulation (EES) of the lumbosacral spinal cord has been shown to restore locomotion and promote long-term recovery of voluntary leg control in individuals affected by SCI. EES predominantly engages sensory nerve fibers in dorsal roots and dorsal columns, modulating the motor output of lumbosacral spinal segments via mono- and poly-synaptic pathways.

Similar sensorimotor circuits involved in upper-limb motor control are located in the cervical segments, suggesting that EES could also be applied to promote arm and hand function in tetraplegic patients after SCI. However, the ability of EES to modulate specific cervical motor nuclei, likely essential to promote upper-limb function, remains largely unexplored.

Hybrid neurophysical volume conductor models have been valuable to unravel the mechanisms of lumbosacral EES and are still intensively used to design implantable electrode arrays and stimulation strategies. Via a two-steps computational scheme in which geometrical factors have a significant influence, they allow to compute the tridimensional electric potential induced in biological tissues and assess the electrical response of neurons and nerve fibers.

In this thesis, I have conceived a new geometrical model to represent the spinal cord including notably the spinal roots, I refined the geometry of spinal nerve fibers, and I have developed a software suite implementing these models and enabling the semi-automatic construction of detailed hybrid models from user configuration datasets.

I used this suite to construct a hybrid model of EES of the macaque monkey cervical spinal cord to explore the potential targets of cervical EES and evaluate the recruitment selectivity of epidural electrode arrays specifically tailored to the cervical spinal cord. Electrophysiological experiments led on actual macaque monkeys overall corroborated the findings from the model: cervical EES can selectively modulate specific upper-limb motor nuclei via the direct recruitment of dorsal root primary afferents, but the specificity is limited notably by the mix of distinct afferent populations in the dorsal roots.

One way to increase this specificity might be to target individual rootlets, for which multipolar stimulation configurations could be decisive. I have reviewed the strategies employed to represent and search for optimal multipolar configurations using hybrid models, and I propose a new economic and versatile approach whose validity is proven on the theoretical ground.

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https://infoscience.epfl.ch/record/276224?ln=fr

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Nathan Antoine Greiner
EPFL, 2020
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/276224?ln=fr

À propos de ce résultat

Concepts associés (9)

Concepts associés

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Publications associées (4)

Publications associées

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Biodegradable scaffolds promote tissue remodeling and functional improvement in non-human primates with acute spinal cord injury

Grégoire Courtine, Isabel Laura Vollenweider

Tissue loss significantly reduces the potential for functional recovery after spinal cord injury. We previously showed that implantation of porous scaffolds composed of a biodegradable and biocompatible block copolymer of Poly-lactic-co-glycolic acid and Poly-L-lysine improves functional recovery and reduces spinal cord tissue injury after spinal cord hemisection injury in rats. Here, we evaluated the safety and efficacy of porous scaffolds in non-human Old-World primates (Chlorocebus sabaeus) after a partial and complete lateral hemisection of the thoracic spinal cord. Detailed analyses of kinematics and muscle activity revealed that by twelve weeks after injury fully hemisected monkeys implanted with scaffolds exhibited significantly improved recovery of locomotion compared to non-implanted control animals. Twelve weeks after injury, histological analysis demonstrated that the spinal cords of monkeys with a hemisection injury implanted with scaffolds underwent appositional healing characterized by a significant increase in remodeled tissue in the region of the hemisection compared to non-implanted controls. The number of glial fibrillary acidic protein immunopositive astrocytes was diminished within the inner regions of the remodeled tissue layer in treated animals. Activated macrophage and microglia were present diffusely throughout the remodeled tissue and concentrated at the interface between the preserved spinal cord tissue and the remodeled tissue layer. Numerous unphosphorylated neurofilament H and neuronal growth associated protein positive fibers and myelin basic protein positive cells may indicate neural sprouting inside the remodeled tissue layer of treated monkeys. These results support the safety and efficacy of polymer scaffolds in a primate model of acute spinal cord injury. A device substantially similar to the device described here is the subject of an ongoing human clinical trial. (C) 2017 Elsevier Ltd. All rights reserved.

2017

Chargement

Advantages of soft subdural implants for the delivery of electrochemical neuromodulation therapies to the spinal cord

Marco Capogrosso, Grégoire Courtine, Jérôme Gandar, Nathan Antoine Greiner, Stéphanie Lacour, Eduardo Martin Moraud, Ivan Rusev Minev, Pavel Musienko, Polina Shkorbatova, Nikolaus Wenger

Objective. We recently developed soft neural interfaces enabling the delivery of electrical and chemical stimulation to the spinal cord. These stimulations restored locomotion in animal models of paralysis. Soft interfaces can be placed either below or above the dura mater. Theoretically, the subdural location combines many advantages, including increased selectivity of electrical stimulation, lower stimulation thresholds, and targeted chemical stimulation through local drug delivery. However, these advantages have not been documented, nor have their functional impact been studied in silico or in a relevant animal model of neurological disorders using a multimodal neural interface. Approach. We characterized the recruitment properties of subdural interfaces using a realistic computational model of the rat spinal cord that included explicit representation of the spinal roots. We then validated and complemented computer simulations with electrophysiological experiments in rats. We additionally performed behavioral experiments in rats that received a lateral spinal cord hemisection and were implanted with a soft interface. Main results. In silico and in vivo experiments showed that the subdural location decreased stimulation thresholds compared to the epidural location while retaining high specificity. This feature reduces power consumption and risks of long-term damage in the tissues, thus increasing the clinical safety profile of this approach. The hemisection induced a transient paralysis of the leg ipsilateral to the injury. During this period, the delivery of electrical stimulation restricted to the injured side combined with local chemical modulation enabled coordinated locomotor movements of the paralyzed leg without affecting the non-impaired leg in all tested rats. Electrode properties remained stable over time, while anatomical examinations revealed excellent bio-integration properties. Significance. Soft neural interfaces inserted subdurally provide the opportunity to deliver electrical and chemical neuromodulation therapies using a single, bio-compatible and mechanically compliant device that effectively alleviates locomotor deficits after spinal cord injury

2018

Chargement

Diseases or injuries affecting the nervous system can dramatically disrupt the quality of life. Despite extensive efforts towards treating dysfunctional nervous systems, the pharmacological and electrical approaches generally involved lack the temporal and spatial resolutions needed to selectively modulate neural activity. The somatosensory system intertwines numerous neural populations with distinct functionalities, whose specific neuromodulation would be beneficial for the alleviation of chronic pain and the restoration of locomotion after spinal cord injury. This thesis aims to develop a new generation of electrical and optical neural interfaces to selectively parse the somatosensory system. At the peripheral nerve level, we proposed an optical cuff and a wireless optoelectronic system to deliver epineural optogenetic stimulations in freely-behaving mice. The former consists of a soft elastomeric cuff wrapped around the sciatic nerve and integrated into a thin optic fiber. We demonstrated consistent orderly recruitment of motor units with optical stimulations in Thy1::ChR2 mice. This optocuff represents a simple, yet efficient, solution to probe the peripheral nervous system using optogenetics. However, untethered experimentation offers more versatility for fine neuromodulation applications. Within this framework, we developed a system comprising an ultra-miniaturized wireless stimulator and a soft circumneural ÎŒ-LED array to deliver optogenetic stimulations to the sciatic nerve. This optoelectronic implant conformed to the nerveâs morphology and complied with its dynamic motion. We demonstrated the systemâs efficacy via optogenetic activation of nociceptors in TRPV1::ChR2 mice. Both the optocuff and the wireless optoelectronic system exhibited seamless bio-integration after chronic implantation, thus highlighting the benefits of soft neurotechnology for interfacing with peripheral nerves. At the spinal level, we introduced a transversal electrode array for multipolar epidural stimulation of the spinal cord. The silicone materials used for its fabrication conferred this implant with mechanical properties matching the dura mater, allowing for remarkable biocompatibility following long-term implantation. Based on the spinal cord anatomy, this implant displayed a wide distribution of neural electrodes at a single spinal level, which enabled selective recruit- ment of posterior spinal roots. This novel paradigm was implemented to a spatio-temporal stimulation protocol and demonstrated potential in restoring locomotion after spinal cord injury. Finally, we reported a soft ÎŒ-LED array to deliver optogenetic stimulations in deep spinal structures. Insertion of this thin (< 100 ÎŒm) optoelectronic implant in the mouse epidural space did not provoke tissue damages while maintaining its functionality with normal dynamic motion. As a proof-of-principle, we showed concomitant electromyographic activity with epidural optical stimulations in Thy1::ChR2 mice. This premise offers a large range of opportunities to probe the spinal circuits involved in sensory processing and locomotion. In conclusion, these selective neural interfaces are proposed as innovative tools to unravel peripheral and spinal neural circuits. This venue will support the development of relevant clinical treatments for tackling dysfunctional neural systems. Eventually, these implant concepts pave the way for the translation of fine neuromodulation therapies in humans.

EPFL2019

Chargement

EPFL2019

Biodegradable scaffolds promote tissue remodeling and functional improvement in non-human primates with acute spinal cord injury

Grégoire Courtine, Isabel Laura Vollenweider

2017

Advantages of soft subdural implants for the delivery of electrochemical neuromodulation therapies to the spinal cord

Marco Capogrosso, Grégoire Courtine, Jérôme Gandar, Nathan Antoine Greiner, Stéphanie Lacour, Eduardo Martin Moraud, Ivan Rusev Minev, Pavel Musienko, Polina Shkorbatova, Nikolaus Wenger

2018