Pronounced species divergence in corticospinal tract reorganization and functional recovery after lateralized spinal cord injury favors primates

Quentin Barraud, Grégoire Courtine, Lucia Florinda Friedli Wittler, Pavel Musienko, Rubia van den Brand
American Association for the Advancement of Science, 2015
Article

Résumé

Experimental and clinical studies suggest that primate species exhibit greater recovery after lateralized compared to symmetrical spinal cord injuries. Although this observation has major implications for designing clinical trials and translational therapies, advantages in recovery of nonhuman primates over other species have not been shown statistically to date, nor have the associated repair mechanisms been identified. We monitored recovery in more than 400 quadriplegic patients and found that functional gains increased with the laterality of spinal cord damage. Electrophysiological analyses suggested that corticospinal tract reorganization contributes to the greater recovery after lateralized compared with symmetrical injuries. To investigate underlying mechanisms, we modeled lateralized injuries in rats and monkeys using a lateral hemisection, and compared anatomical and functional outcomes with patients who suffered similar lesions. Standardized assessments revealed that monkeys and humans showed greater recovery of locomotion and hand function than did rats. Recovery correlated with the formation of corticospinal detour circuits below the injury, which were extensive in monkeys but nearly absent in rats. Our results uncover pronounced interspecies differences in the nature and extent of spinal cord repair mechanisms, likely resulting from fundamental differences in the anatomical and functional characteristics of the motor systems in primates versus rodents. Although rodents remain essential for advancing regenerative therapies, the unique response of the primate corticospinal tract after injury reemphasizes the importance of primate models for designing clinically relevant treatments.

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https://infoscience.epfl.ch/record/213156?ln=fr

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Quentin Barraud, Grégoire Courtine, Lucia Florinda Friedli Wittler, Pavel Musienko, Rubia van den Brand
American Association for the Advancement of Science, 2015
Article

Résumé

Official source

https://infoscience.epfl.ch/record/213156?ln=fr

À propos de ce résultat

Concepts associés (17)

Concepts associés

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Publications associées (22)

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Electrical spinal cord stimulation protocols to regulate motor and autonomic functions in people with neurological disorders

Robin Jonathan Demesmaeker

Neurological disorders such as spinal cord injury (SCI) massively reduce independence and quality of life. Most often, the majority of the nervous system is still fully or partially spared, but dysfunctional due to aberrant or absent descending input from the brain. Neuromodulation techniques restore function by artificially engaging these neuronal circuits. Given its central position and multi- functional role, the spinal cord provides an excellent gateway for such therapies.Epidural Electrical Stimulation (EES) of the spinal cord has been put forward as a potential therapy to restore motor and autonomic function after SCI. Throughout the last decade, our laboratory developed the concept of biomimetic EES. Spatiotemporal stimulation parameters are optimized to re-establish the natural dynamics of the underlying spinal circuitry. Strong evidence in rodent and non- human primate models suggests that biomimetic EES could promote locomotion and haemodynamic stability after severe SCI, leading to a push for rapid clinical translation of this potentially game-changing therapy. This clinical translation is the pivot of my thesis.The first part focuses on the recovery of leg motor control after SCI. The results of a first-in-human clinical trial in 9 participants with chronic SCI are presented. We developed a set of targeted neurotechnologies that include a new epidurally implanted electrode array, real-time communication and tailormade software systems that enable the precise delivery of biomimetic EES. We demon- strate that biomimetic EES can be optimized to immediately restore a vast number of leg motor functions such as walking and cycling, as well as trunk posture. Furthermore, after 5 months of intensive EES-enabled volitional training, participants did not only all improve their motor performance while using EES, they moreover regained volitional control over previously paralyzed muscles. This neuro- logical recovery correlated with a reduced metabolic activity in the spinal cord, suggesting spinal remodeling. A systematic pre-clinical approach identified a specific neuronal population mediating these effects.The second part of my thesis considers another critically important body function: haemodynamic management. Orthostatic hypo- tension is a major health issue after severe SCI and stems from a disconnection between the vasomotor regulatory centres in the brainstem and the sympathetic circuitry that adjusts peripheral vascular resistance. Preclinical work in rodents showed that EES ap- plied to the low-thoracic spinal cord could restore haemodynamic stability after SCI. On the path towards clinical translation, we implemented closed-loop control of EES in a non-human primate model of SCI to maintain haemodynamic stability during orthostatic challenge. I moreover present a case-study that demonstrates the transferability of thoracic EES to improve haemodynamic manage- ment in a patient with Multiple System Atrophy (MSA). A marked reduction of orthostatic hypotension led to a clinically relevant decrease in fainting episodes and considerably improved quality of life.My thesis demonstrates the prosthetic and therapeutic effects of biomimetic EES and highlights its ability to immediately restore body functions and boost neurological recovery after SCI and in MSA. These results strengthen the belief that EES holds the potential to evolve into a relevant and efficient therapeutic intervention in a plentitude of neurological disorders.

EPFL2021

Chargement

After a spinal cord injury (SCI), only half of affected individuals regain voluntary control of leg movements below the level of the lesion. Anatomical, electrophysiological and imaging data revealed that even the most severe forms of SCI usually spare a small bridge of tissue in the surrounding of the lesion cavity. These bridges contain residual fibers from brain projections that maintain a physical connection with the lumbar spinal cord, where the circuits coordinating leg movements reside. However, without therapeutic interventions, these spared fibers will fail to conduct nervous information from brain centers to the spinal circuits below injury, leading to permanent paralysis. It is accepted that spontaneous regeneration of lesioned fibers is limited in the adult nervous system, but hope for motor recovery lies in the capacity of the spared neural motor network to readapt and find compensational routes. In the past, a neuroprosthetic rehabilitation strategy combining electrochemical neuromodulation of the spinal cord during robot-assisted overground locomotion was developed for rats to restore volitional control of the paralyzed legs. Such rehabilitation platforms was developed for rats, enabling large-scale studies prior to pre-clinical trials in non-human primates. However, most innovative tools for the manipulation of specific populations of neurons are currently designed for mice, and these techniques are essential to establish causality between the anatomical reorganization and the observed functional recovery. In the first part of this thesis, we developed a robotic interface with end-effector modules that can be rapidly exchanged between experiments with rats or mice. The functionalities of the robot are tailored to the size and weight of the animal, to the personalized need of assistance and to the type of performed task. Using this platform, the next part of the thesis uncovers the mechanisms enabling motor recovery after a clinically relevant injury model â a severe spinal cord contusion. Such injury leads to permanent leg motor deficits with very little spontaneous recovery. Similar to humans, the modelled contusion injury induce highly variable white matter damage with undefined neural pathway sparing. For the first time, we show that the rehabilitation strategy enabled rats to regain supraspinal control of leg movements that persisted without any neuromodulation even during unpracticed motor tasks. We then investigated the reorganization of the spared circuitry that mediated this functional recovery after contusion. Despite interruption of direct corticospinal projections, we showed that the motor cortex regained adaptive control over the paralyzed legs during neuromodulation of lumbar circuits. We found that the cortical command was relayed through spared glutamatergic projection neurons in the reticular formation. Indeed, due to the distributed spatial topography of reticulospinal projections, the contusion systematically spares a subset of these projections. Extensive training promoted plasticity of the identified cortico-reticulo-spinal pathway mediating a motor cortex dependent recovery of voluntary leg movements. As the anatomy and function of reticulospinal pathways are well-conserved across mammals, this pathway may be recruited by similar therapeutic interventions to improve recovery in humans.

EPFL2017

Chargement

Animal Models of Neurologic Disorders: A Nonhuman Primate Model of Spinal Cord Injury

Grégoire Courtine

Primates are an important and unique animal resource. We have developed a nonhuman primate model of spinal cord injury (SCI) to expand our knowledge of normal primate motor function, to assess the impact of disease and injury on sensory and motor function, and to test candidate therapies before they are applied to human patients. The lesion model consists of a lateral spinal cord hemisection at the C7 spinal level with subsequent examination of behavioral, electrophysiological, and anatomical outcomes. Results to date have revealed significant neuroanatomical and functional differences between rodents and primates that impact the development of candidate therapies. Moreover, these findings suggest the importance of testing some therapeutic approaches in nonhuman primates prior to the use of invasive approaches in human clinical trials. Our primate model is intended to: 1) lend greater positive predictive value to human translatable therapies, 2) develop appropriate methods for human translation, 3) lead to basic discoveries that might not be identified in rodent models and are relevant to human translation, and 4) identify new avenues of basic research to “reverse-translate” important questions back to rodent models

2012

Chargement

Electrical spinal cord stimulation protocols to regulate motor and autonomic functions in people with neurological disorders

Robin Jonathan Demesmaeker

EPFL2021

EPFL2017