New Treatment Helps Patients With a Spinal Cord Injury (Medicine)

Spinal cord injuries disrupt the mechanism by which our bodies regulate blood pressure. A team of Swiss and Canadian scientists have developed a treatment that allows patients to regain control of their blood pressure, using targeted electrical spinal-cord stimulation. No medication is required. The team’s findings were published today in Nature.

An international team of scientists headed by Grégoire Courtine at EPFL and CHUV and Aaron Phillips at the University of Calgary has developed a treatment that can dramatically improve the lives of patients with a spinal cord injury.

“A serious and underrecognized result of these injuries is unstable blood pressure, which can have devastating consequences that reduce quality of life and are life threatening. Unfortunately, there are no effective therapies for unstable blood pressure after spinal cord injury”. said Dr. Aaron Phillips, co-lead author of the study (see affiliations below). “We created the first platform to understand the mechanisms underlying blood pressure instability after spinal cord injury.”

Their findings, published today in Nature, builds on research that has already enabled several paraplegics to walk again through epidural electrical stimulation (EES). But instead of targeting the region of the spinal cord that produces leg movements, they delivered EES in the region containing the neural circuits that regulate blood pressure. In addition, they adapted the stimulation protocol in real-time based on measurements taken by a blood-pressure monitor implanted in an artery. The monitor measures blood pressure continuously, and adapts the instructions sent to a pacemaker that in turn delivers electrical pulses over the spinal cord. The stimulation is biomimetic, since it recapitulates the natural activation of the body’s hemodynamic system. “The stimulation compensates for the broken communication line between the patient’s central nervous system and sympathetic nervous system,” says Courtine.

The research team initially tested their method in preclinical rodent and nonhuman primate models in order to understand the mechanisms that disrupt blood pressure modulation after spinal cord injury, and to identify where and how the stimulation patterns should be applied to obtain the desired hemodynamic responses. Jocelyne Bloch, the neurosurgeon who heads the .NeuroRestore research center with Courtine and who carried out the surgical implants, was surprised at how quickly the stimulation protocol worked. “It was impressive to see the blood pressure rise to the target level immediately after the stimulation was applied,” she says.

The electrical stimulation treatment provided a huge relief – much more effective than medication.

— Richdeep Gill, first patient

After these initial tests, the scientists tried their method on a human patient.

“I suffered from daily episodes of low blood pressure, especially in the morning and evening,” says Richi, 38 years old. “But since I’ve had the implant, it happens much less often – maybe once every couple of weeks.” Himself a surgeon, Richi lost the use of all four limbs after a sport accident. “Those daily episodes of hypotension were a real burden. They also disturbed my vision and prevented me from performing even simple everyday tasks. The electrical stimulation treatment provided a huge relief – much more effective than medication.”

One of the physicians working with Richi, Dr. Sean Dukelow, states: “Since using this system, Richi was able to completely stop all drugs he was using to manage blood pressure instability. This has been transformative, and over the long-term may reduce Richi’s risk of cardiovascular disease.”
The team intends to continue its research thanks to a large grant received from the US Defense Advanced Research Projects Agency (DARPA). At the same time, Onward (formerly GTX Medical) – a startup based at EPFL Innovation Park and in the Netherlands – will develop and market clinical devices based on the team’s discoveries.

Image credit: © 2021 EPFL Mediacom Communication visuelle


Reference: Jordan W. Squair, Matthieu Gautier, Lois Mahe, Jan Elaine Soriano, Andreas Rowald, Arnaud Bichat, Newton Cho, Mark A. Anderson, Nicholas D. James, Jerome Gandar, Anthony V. Incognito, Giuseppe Schiavone, Zoe K. Sarafis, Achilleas Laskaratos, Kay Bartholdi, Robin Demesmaeker, Salif Komi, Charlotte Moerman, Bita Vaseghi, Berkeley Scott, Ryan Rosentreter, Claudia Kathe, Jimmy Ravier, Laura McCracken, Xiaoyang Kang, Nicolas Vachicouras, Florian Fallegger, Ileana Jelescu, YunLong Cheng, Qin Li, Rik Buschman, Nicolas Buse, Tim Denison, Sean Dukelow, Rebecca Charbonneau, Ian Rigby, Steven K. Boyd, Philip J. Millar, Eduardo Martin Moraud, Marco Capogrosso, Fabien B. Wagner, Quentin Barraud, Erwan Bezard, Stéphanie P. Lacour, Jocelyne Bloch, Grégoire Courtine & Aaron A. Phillips, ‘Neuroprosthetic baroreflex controls haemodynamics after spinal cord injury’. Nature, January 27th, 2021, DOI 10.1038/s41586-020-03180-w https://www.nature.com/articles/s41586-020-03180-w


Provided by EPFL

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