A neuronal architecture underlying autonomic dysreflexia

Jan Elaine Soriano; Remi Hudelle; Lois Mahe; Matthieu Gautier; Alan Yue Yang Teo; Michael A. Skinnider; Achilleas Laskaratos; Steven Ceto; Claudia Kathe; Thomas Hutson; Rebecca Charbonneau; Fady Girgis; Steve Casha; Julien Rimok; Marcus Tso; Kelly Larkin-Kaiser; Nicolas Hankov; Aasta Gandhi; Suje Amir; Xiaoyang Kang; Yashwanth Vyza; Eduardo Martin-Moraud; Stephanie Lacour; Robin Demesmaeker; Leonie Asboth; Quentin Barraud; Mark A. Anderson; Jocelyne Bloch; Jordan W. Squair; Aaron A. Phillips; Gregoire Courtine

doi:10.1038/s41586-025-09487-w

A neuronal architecture underlying autonomic dysreflexia

Jan Elaine Soriano
, Remi Hudelle
, Lois Mahe
, Matthieu Gautier
, Alan Yue Yang Teo
, Michael A. Skinnider
, Achilleas Laskaratos
, Steven Ceto
, Claudia Kathe
, Thomas Hutson
, Rebecca Charbonneau
, Fady Girgis
, Steve Casha
, Julien Rimok
, Marcus Tso
, Kelly Larkin-Kaiser
, Nicolas Hankov
, Aasta Gandhi
, Suje Amir
, Xiaoyang Kang

Yashwanth Vyza, Eduardo Martin-Moraud, Stephanie Lacour, Robin Demesmaeker, Leonie Asboth, Quentin Barraud, Mark A. Anderson, Jocelyne Bloch, Jordan W. Squair, Aaron A. Phillips, Gregoire Courtine

Lewis-Sigler Institute for Integrative Genomics

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Autonomic dysreflexia is a life-threatening medical condition characterized by episodes of uncontrolled hypertension that occur in response to sensory stimuli after spinal cord injury (SCI)¹. The fragmented understanding of the mechanisms underlying autonomic dysreflexia hampers the development of therapeutic strategies to manage this condition, leaving people with SCI at daily risk of heart attack and stroke^{2, 3, 4–5}. Here we expose the neuronal architecture that develops after SCI and causes autonomic dysreflexia. In parallel, we uncover a competing, yet overlapping neuronal architecture activated by epidural electrical stimulation of the spinal cord that safely regulates blood pressure after SCI. The discovery that these adversarial neuronal architectures converge onto a single neuronal subpopulation provided a blueprint for the design of a mechanism-based intervention that reversed autonomic dysreflexia in mice, rats and humans with SCI. These results establish a path towards essential pivotal device clinical trials that will establish the safety and efficacy of epidural electrical stimulation for the effective treatment of autonomic dysreflexia in people with SCI.

Original language	English (US)
Pages (from-to)	1167-1177
Number of pages	11
Journal	Nature
Volume	646
Issue number	8087
DOIs	https://doi.org/10.1038/s41586-025-09487-w
State	Published - Oct 30 2025

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Soriano, J. E., Hudelle, R., Mahe, L., Gautier, M., Teo, A. Y. Y., Skinnider, M. A., Laskaratos, A., Ceto, S., Kathe, C., Hutson, T., Charbonneau, R., Girgis, F., Casha, S., Rimok, J., Tso, M., Larkin-Kaiser, K., Hankov, N., Gandhi, A., Amir, S., ... Courtine, G. (2025). A neuronal architecture underlying autonomic dysreflexia. Nature, 646(8087), 1167-1177. https://doi.org/10.1038/s41586-025-09487-w

@article{d9e1a14ee60849f787d673115a482aca,

title = "A neuronal architecture underlying autonomic dysreflexia",

abstract = "Autonomic dysreflexia is a life-threatening medical condition characterized by episodes of uncontrolled hypertension that occur in response to sensory stimuli after spinal cord injury (SCI)1. The fragmented understanding of the mechanisms underlying autonomic dysreflexia hampers the development of therapeutic strategies to manage this condition, leaving people with SCI at daily risk of heart attack and stroke2, 3, 4–5. Here we expose the neuronal architecture that develops after SCI and causes autonomic dysreflexia. In parallel, we uncover a competing, yet overlapping neuronal architecture activated by epidural electrical stimulation of the spinal cord that safely regulates blood pressure after SCI. The discovery that these adversarial neuronal architectures converge onto a single neuronal subpopulation provided a blueprint for the design of a mechanism-based intervention that reversed autonomic dysreflexia in mice, rats and humans with SCI. These results establish a path towards essential pivotal device clinical trials that will establish the safety and efficacy of epidural electrical stimulation for the effective treatment of autonomic dysreflexia in people with SCI.",

author = "Soriano, \{Jan Elaine\} and Remi Hudelle and Lois Mahe and Matthieu Gautier and Teo, \{Alan Yue Yang\} and Skinnider, \{Michael A.\} and Achilleas Laskaratos and Steven Ceto and Claudia Kathe and Thomas Hutson and Rebecca Charbonneau and Fady Girgis and Steve Casha and Julien Rimok and Marcus Tso and Kelly Larkin-Kaiser and Nicolas Hankov and Aasta Gandhi and Suje Amir and Xiaoyang Kang and Yashwanth Vyza and Eduardo Martin-Moraud and Stephanie Lacour and Robin Demesmaeker and Leonie Asboth and Quentin Barraud and Anderson, \{Mark A.\} and Jocelyne Bloch and Squair, \{Jordan W.\} and Phillips, \{Aaron A.\} and Gregoire Courtine",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = oct,

day = "30",

doi = "10.1038/s41586-025-09487-w",

language = "English (US)",

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Soriano, JE, Hudelle, R, Mahe, L, Gautier, M, Teo, AYY, Skinnider, MA, Laskaratos, A, Ceto, S, Kathe, C, Hutson, T, Charbonneau, R, Girgis, F, Casha, S, Rimok, J, Tso, M, Larkin-Kaiser, K, Hankov, N, Gandhi, A, Amir, S, Kang, X, Vyza, Y, Martin-Moraud, E, Lacour, S, Demesmaeker, R, Asboth, L, Barraud, Q, Anderson, MA, Bloch, J, Squair, JW, Phillips, AA & Courtine, G 2025, 'A neuronal architecture underlying autonomic dysreflexia', Nature, vol. 646, no. 8087, pp. 1167-1177. https://doi.org/10.1038/s41586-025-09487-w

TY - JOUR

T1 - A neuronal architecture underlying autonomic dysreflexia

AU - Soriano, Jan Elaine

AU - Hudelle, Remi

AU - Mahe, Lois

AU - Gautier, Matthieu

AU - Teo, Alan Yue Yang

AU - Skinnider, Michael A.

AU - Laskaratos, Achilleas

AU - Ceto, Steven

AU - Kathe, Claudia

AU - Hutson, Thomas

AU - Charbonneau, Rebecca

AU - Girgis, Fady

AU - Casha, Steve

AU - Rimok, Julien

AU - Tso, Marcus

AU - Larkin-Kaiser, Kelly

AU - Hankov, Nicolas

AU - Gandhi, Aasta

AU - Amir, Suje

AU - Kang, Xiaoyang

AU - Vyza, Yashwanth

AU - Martin-Moraud, Eduardo

AU - Lacour, Stephanie

AU - Demesmaeker, Robin

AU - Asboth, Leonie

AU - Barraud, Quentin

AU - Anderson, Mark A.

AU - Bloch, Jocelyne

AU - Squair, Jordan W.

AU - Phillips, Aaron A.

AU - Courtine, Gregoire

PY - 2025/10/30

Y1 - 2025/10/30

N2 - Autonomic dysreflexia is a life-threatening medical condition characterized by episodes of uncontrolled hypertension that occur in response to sensory stimuli after spinal cord injury (SCI)1. The fragmented understanding of the mechanisms underlying autonomic dysreflexia hampers the development of therapeutic strategies to manage this condition, leaving people with SCI at daily risk of heart attack and stroke2, 3, 4–5. Here we expose the neuronal architecture that develops after SCI and causes autonomic dysreflexia. In parallel, we uncover a competing, yet overlapping neuronal architecture activated by epidural electrical stimulation of the spinal cord that safely regulates blood pressure after SCI. The discovery that these adversarial neuronal architectures converge onto a single neuronal subpopulation provided a blueprint for the design of a mechanism-based intervention that reversed autonomic dysreflexia in mice, rats and humans with SCI. These results establish a path towards essential pivotal device clinical trials that will establish the safety and efficacy of epidural electrical stimulation for the effective treatment of autonomic dysreflexia in people with SCI.

AB - Autonomic dysreflexia is a life-threatening medical condition characterized by episodes of uncontrolled hypertension that occur in response to sensory stimuli after spinal cord injury (SCI)1. The fragmented understanding of the mechanisms underlying autonomic dysreflexia hampers the development of therapeutic strategies to manage this condition, leaving people with SCI at daily risk of heart attack and stroke2, 3, 4–5. Here we expose the neuronal architecture that develops after SCI and causes autonomic dysreflexia. In parallel, we uncover a competing, yet overlapping neuronal architecture activated by epidural electrical stimulation of the spinal cord that safely regulates blood pressure after SCI. The discovery that these adversarial neuronal architectures converge onto a single neuronal subpopulation provided a blueprint for the design of a mechanism-based intervention that reversed autonomic dysreflexia in mice, rats and humans with SCI. These results establish a path towards essential pivotal device clinical trials that will establish the safety and efficacy of epidural electrical stimulation for the effective treatment of autonomic dysreflexia in people with SCI.

UR - https://www.scopus.com/pages/publications/105016707374

UR - https://www.scopus.com/pages/publications/105016707374#tab=citedBy

U2 - 10.1038/s41586-025-09487-w

DO - 10.1038/s41586-025-09487-w

M3 - Article

C2 - 40963010

AN - SCOPUS:105016707374

SN - 0028-0836

VL - 646

SP - 1167

EP - 1177

JO - Nature

JF - Nature

IS - 8087

ER -

A neuronal architecture underlying autonomic dysreflexia

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