Stroke-induced neuroplasticity in spiny mice in the absence of tissue regeneration

Benjamin M. Kidd; Justin A. Varholick; Dana M. Tuyn; Pradip K. Kamat; Zachary D. Simon; Lei Liu; Mackenzie P. Mekler; Marjory Pompilus; Jodi L. Bubenik; Mackenzie L. Davenport; Helmut A. Carter; Matteo M. Grudny; W. Brad Barbazuk; Sylvain Doré; Marcelo Febo; Eduardo Candelario-Jalil; Malcolm Maden; Maurice S. Swanson

doi:10.1038/s41536-024-00386-8

Stroke-induced neuroplasticity in spiny mice in the absence of tissue regeneration

Benjamin M. Kidd
, Justin A. Varholick
, Dana M. Tuyn
, Pradip K. Kamat
, Zachary D. Simon
, Lei Liu
, Mackenzie P. Mekler
, Marjory Pompilus
, Jodi L. Bubenik
, Mackenzie L. Davenport
, Helmut A. Carter
, Matteo M. Grudny
, W. Brad Barbazuk
, Sylvain Doré
, Marcelo Febo
, Eduardo Candelario-Jalil
, Malcolm Maden
, Maurice S. Swanson

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

4 Scopus citations

Abstract

Stroke is a major cause of disability for adults over 40 years of age. While research into animal models has prioritized treatments aimed at diminishing post-stroke damage, no studies have investigated the response to a severe stroke injury in a highly regenerative adult mammal. Here we investigate the effects of transient ischemia on adult spiny mice, Acomys cahirinus, due to their ability to regenerate multiple tissues without scarring. Transient middle cerebral artery occlusion was performed and Acomys showed rapid behavioral recovery post-stroke yet failed to regenerate impacted brain regions. An Acomys brain atlas in combination with functional (f)MRI demonstrated recovery coincides with neuroplasticity. The strength and quality of the global connectome are preserved post-injury with distinct contralateral and ipsilateral brain regions compensating for lost tissue. Thus, we propose Acomys recovers functionally from an ischemic stroke injury not by tissue regeneration but by altering its brain connectome.

Original language	English (US)
Article number	41
Journal	npj Regenerative Medicine
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41536-024-00386-8
State	Published - Dec 2024
Externally published	Yes

ASJC Scopus subject areas

Medicine (miscellaneous)
Biomedical Engineering
Developmental Biology
Cell Biology

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Kidd, B. M., Varholick, J. A., Tuyn, D. M., Kamat, P. K., Simon, Z. D., Liu, L., Mekler, M. P., Pompilus, M., Bubenik, J. L., Davenport, M. L., Carter, H. A., Grudny, M. M., Barbazuk, W. B., Doré, S., Febo, M., Candelario-Jalil, E., Maden, M., & Swanson, M. S. (2024). Stroke-induced neuroplasticity in spiny mice in the absence of tissue regeneration. npj Regenerative Medicine, 9(1), Article 41. https://doi.org/10.1038/s41536-024-00386-8

Kidd, BM, Varholick, JA, Tuyn, DM, Kamat, PK, Simon, ZD, Liu, L, Mekler, MP, Pompilus, M, Bubenik, JL, Davenport, ML, Carter, HA, Grudny, MM, Barbazuk, WB, Doré, S, Febo, M, Candelario-Jalil, E, Maden, M & Swanson, MS 2024, 'Stroke-induced neuroplasticity in spiny mice in the absence of tissue regeneration', npj Regenerative Medicine, vol. 9, no. 1, 41. https://doi.org/10.1038/s41536-024-00386-8

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title = "Stroke-induced neuroplasticity in spiny mice in the absence of tissue regeneration",

abstract = "Stroke is a major cause of disability for adults over 40 years of age. While research into animal models has prioritized treatments aimed at diminishing post-stroke damage, no studies have investigated the response to a severe stroke injury in a highly regenerative adult mammal. Here we investigate the effects of transient ischemia on adult spiny mice, Acomys cahirinus, due to their ability to regenerate multiple tissues without scarring. Transient middle cerebral artery occlusion was performed and Acomys showed rapid behavioral recovery post-stroke yet failed to regenerate impacted brain regions. An Acomys brain atlas in combination with functional (f)MRI demonstrated recovery coincides with neuroplasticity. The strength and quality of the global connectome are preserved post-injury with distinct contralateral and ipsilateral brain regions compensating for lost tissue. Thus, we propose Acomys recovers functionally from an ischemic stroke injury not by tissue regeneration but by altering its brain connectome.",

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AU - Kidd, Benjamin M.

AU - Varholick, Justin A.

AU - Tuyn, Dana M.

AU - Kamat, Pradip K.

AU - Simon, Zachary D.

AU - Liu, Lei

AU - Mekler, Mackenzie P.

AU - Pompilus, Marjory

AU - Bubenik, Jodi L.

AU - Davenport, Mackenzie L.

AU - Carter, Helmut A.

AU - Grudny, Matteo M.

AU - Barbazuk, W. Brad

AU - Doré, Sylvain

AU - Febo, Marcelo

AU - Candelario-Jalil, Eduardo

AU - Maden, Malcolm

AU - Swanson, Maurice S.

PY - 2024/12

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N2 - Stroke is a major cause of disability for adults over 40 years of age. While research into animal models has prioritized treatments aimed at diminishing post-stroke damage, no studies have investigated the response to a severe stroke injury in a highly regenerative adult mammal. Here we investigate the effects of transient ischemia on adult spiny mice, Acomys cahirinus, due to their ability to regenerate multiple tissues without scarring. Transient middle cerebral artery occlusion was performed and Acomys showed rapid behavioral recovery post-stroke yet failed to regenerate impacted brain regions. An Acomys brain atlas in combination with functional (f)MRI demonstrated recovery coincides with neuroplasticity. The strength and quality of the global connectome are preserved post-injury with distinct contralateral and ipsilateral brain regions compensating for lost tissue. Thus, we propose Acomys recovers functionally from an ischemic stroke injury not by tissue regeneration but by altering its brain connectome.

AB - Stroke is a major cause of disability for adults over 40 years of age. While research into animal models has prioritized treatments aimed at diminishing post-stroke damage, no studies have investigated the response to a severe stroke injury in a highly regenerative adult mammal. Here we investigate the effects of transient ischemia on adult spiny mice, Acomys cahirinus, due to their ability to regenerate multiple tissues without scarring. Transient middle cerebral artery occlusion was performed and Acomys showed rapid behavioral recovery post-stroke yet failed to regenerate impacted brain regions. An Acomys brain atlas in combination with functional (f)MRI demonstrated recovery coincides with neuroplasticity. The strength and quality of the global connectome are preserved post-injury with distinct contralateral and ipsilateral brain regions compensating for lost tissue. Thus, we propose Acomys recovers functionally from an ischemic stroke injury not by tissue regeneration but by altering its brain connectome.

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Stroke-induced neuroplasticity in spiny mice in the absence of tissue regeneration

Abstract

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