Technology-driven combinatorial therapy to rewire the spinal cord after injury (ReWire)

Lead Research Organisation: Imperial College London
Department Name: Brain Sciences

Abstract

ReWIRE will combine innovative translational neurotechnologies and rehabilitation interventions for the repair and restoration of neurological functions following injury of the spinal cord (SC). The proposed research program will equip next-generation scientists with unique skills to develop disruptive therapeutic solutions for patients with paralysis. Recent technological breakthroughs have triggered a paradigm shift in the conception of therapies aimed to restore function after spinal cord injury (SCI). Novel drug delivery systems and biomaterial bridges have been engineered to reduce secondary injury and scarring, to stimulate and guide regenerating nerve fibres across the lesion site, and to promote functional reconnection with intact tissue. Additionally, neuromodulation therapies can reactivate spinal circuits below a SCI, allowing people with chronic paralysis to regain voluntary control of walking. In conjunction with rehabilitation, neurological recovery was promoted that persisted without neuromodulation, suggesting a rewiring of the SC as demonstrated in preclinical models. To bypass an injury, neuromodulation has been linked to brain signals to re-establish cortical
control over spinal circuits by employing electrical nerve stimulation and robotic systems. Advances in robotics are significantly augmenting the impact of neurorehabilitation by inducing new natural "wired" connections. The aim of ReWIRE is to leverage all these technical and therapeutic breakthroughs in the framework of multiple PhD projects that will continuously interact to converge toward effective combinatorial treatments for SCI. ReWIRE will focus on three inter-woven objectives: i) establish an international, interdisciplinary, and intersectoral educational network, ii) build an SCI clinical data platform, and, iii) position Europe at the forefront of therapy for SCI.

Publications

10 25 50
 
Title spatial metabolomics 
Description spatial metabolomics to measure metabolites in tissue samples 
Type Of Material Biological samples 
Year Produced 2024 
Provided To Others? No  
Impact ability to analyse energy metabolism in the nervous system 
 
Description biomaterials 
Organisation Northwestern University
Country United States 
Sector Academic/University 
PI Contribution Dr. Samuel Stupp
Collaborator Contribution provide biomaterials for spinal cord injury resercrh
Impact experiments are ongoing
Start Year 2023