Spatiotemporal Maps of Proprioceptive Inputs to the Cervical Spinal Cord During Three-Dimensional Reaching and Grasping

Proprioceptive feedback is a critical component of voluntary movement planning and execution. Neuroprosthetic technologies aiming at restoring movement must interact with it to restore accurate motor control. Optimization and design of such technologies depends on the availability of quantitative insights into the neural dynamics of proprioceptive afferents during functional movements. However, recording proprioceptive neural activity during unconstrained movements in clinically relevant animal models presents formidable challenges. In this work, we developed a computational framework to estimate the spatiotemporal patterns of proprioceptive inputs to the cervical spinal cord during three-dimensional arm movements in monkeys. We extended a biomechanical model of the monkey arm with ex-vivo measurements, and combined it with models of mammalian group-Ia, Ib and II afferent fibers. We then used experimental recordings of arm kinematics and muscle activity of two monkeys performing a reaching and grasping task to estimate muscle stretches and forces with computational biomechanics. Finally, we projected the simulated proprioceptive firing rates onto the cervical spinal roots, thus obtaining spatiotemporal maps of spinal proprioceptive inputs during voluntary movements. Estimated maps show complex and markedly distinct patterns of neural activity for each of the fiber populations spanning the spinal cord rostro-caudally. Our results indicate that reproducing the proprioceptive information flow to the cervical spinal cord requires complex spatio-temporal modulation of each spinal root. Our model can support the design of neuroprosthetic technologies as well as in-silico investigations of the primate sensorimotor system.

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

Unconstrained three-dimensional reaching in Rhesus monkeys

Grégoire Courtine

To better understand normative behavior for quantitative evaluation of motor recovery after injury, we studied arm movements by non-injured Rhesus monkeys during a food-retrieval task. While seated, monkeys reached, grasped, and retrieved food items. We recorded three-dimensional kinematics and muscle activity, and used inverse dynamics to calculate joint moments due to gravity, segmental interactions, and to the muscles and tissues of the arm. Endpoint paths showed curvature in three dimensions, suggesting that maintaining straight paths was not an important constraint. Joint moments were dominated by gravity. Generalized muscle and interaction moments were less than half of the gravitational moments. The relationships between shoulder and elbow resultant moments were linear during both reach and retrieval. Although both reach and retrieval required elbow flexor moments, an elbow extensor (triceps brachii) was active during both phases. Antagonistic muscles of both the elbow and hand were co-activated during reach and retrieval. Joint behavior could be described by lumped-parameter models analogous to torsional springs at the joints. Minor alterations to joint quasi-stiffness properties, aided by interaction moments, result in reciprocal movements that evolve under the influence of gravity. The strategies identified in monkeys to reach, grasp, and retrieve items will allow the quantification of prehension during recovery after a spinal cord injury and the effectiveness of therapeutic interventions

2011

The role of sensorimotor afferent feedback in mediating functional recovery after spinal cord injury

Kay Alexander Bartholdi

Spinal cord injury (SCI) leads to permanent deficits in sensory and motor function due to the physical disruption of descending and ascending pathways. As a consequence, spinal circuits below the level of lesion remain in an intact, but inactive state. A number of studies have shown that epidural electrical stimulation (EES) of the lumbar spinal cord can reactivate these spinal circuits after SCI. EES reversed paralysis of lower limbs in rodent and primate models of SCI as well as in a number of clinical case studies. However, although the positive effects of EES have been documented, little is known about the neural circuits through which EES enables motor pattern formation after SCI. In the first part of this thesis, we examined the neural circuits activated by EES. In the past, modeling experiments highlighted a pivotal role for large-diameter, myelinated afferent circuits in mediating the facilitating effects of EES after SCI. Using calcium imaging and chemogenetic inactivation experiments, we confirmed that EES primarily recruits proprioceptive and low-threshold mechanoreceptor feedback circuits. We next sought to exploit this knowledge to specifically enhance the effects of EES. We found that alpha2a receptors are prominently expressed on proprioceptive afferent neurons in DRGs, whereas alpha2c receptors are located on low-threshold mechanoreceptor interneurons in the dorsal spinal horn. Based on this knowledge, we built a computational model that identified beneficial and detrimental interactions between EES and noradrenergic circuits. This understanding guided the design of a circuit-specific, electrochemical neuromodulation that specifically gated the effects of EES towards proprioceptive feedback circuits and re-established locomotion in paralyzed mice and rats. The second part of this thesis uncovers the impact of movement on sensory afferent pathways. For this, mice were exposed to environmental enrichment (EE) or standard housing (SH). We found that EE primed sensory dorsal root ganglia neurons, inducing a lasting increase in their regenerative potential after SCI. This EE-mediated increase in regenerative potential was confined to proprioceptive afferent neurons and characterized through increased calcium signalling and CBP-dependent histone acetylation which is associated with enhanced gene expression. In a next step, we mimicked the exposure to EE using pharmacology. The pharmacological activation of CBP after injury enhanced axonal growth of proprioceptive afferent fibers and enhanced the recovery of sensory and motor functions. Here, we provide direct and conclusive experimental evidence for the mechanistic understanding of EES and EE and how they mediate functional recovery after SCI. Based on this knowledge, we identified specific receptors and epigenetic mechanisms for pharmacological modulation. Our findings demonstrate the importance of large-diameter afferent fibers in mediating functional recovery and will be important in establishing a framework for the design of targeted neuromodulation therapies after SCI in human patients.