Cerebrospinal fluid influx drives acute ischemic tissue swelling

Humberto Mestre; Ting Du; Amanda M. Sweeney; Guojun Liu; Andrew J. Samson; Weiguo Peng; Kristian Nygaard Mortensen; Frederik Filip Stæger; Peter A.R. Bork; Logan Bashford; Edna R. Toro; Jeffrey Tithof; Douglas H. Kelley; John H. Thomas; Poul G. Hjorth; Erik A. Martens; Rupal I. Mehta; Orestes Solis; Pablo Blinder; David Kleinfeld; Hajime Hirase; Yuki Mori; Maiken Nedergaard

doi:10.1126/science.aaw7462

Cerebrospinal fluid influx drives acute ischemic tissue swelling

Humberto Mestre, Ting Du, Amanda M. Sweeney, Guojun Liu, Andrew J. Samson, Weiguo Peng, Kristian Nygaard Mortensen, Frederik Filip Stæger, Peter A.R. Bork, Logan Bashford, Edna R. Toro, Jeffrey Tithof, Douglas H. Kelley, John H. Thomas, Poul G. Hjorth, Erik A. Martens, Rupal I. Mehta, Orestes Solis, Pablo Blinder, David KleinfeldHajime Hirase, Yuki Mori, Maiken Nedergaard

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Abstract

Stroke affects millions each year. Poststroke brain edema predicts the severity of eventual stroke damage, yet our concept of how edema develops is incomplete and treatment options remain limited. In early stages, fluid accumulation occurs owing to a net gain of ions, widely thought to enter from the vascular compartment. Here, we used magnetic resonance imaging, radiolabeled tracers, and multiphoton imaging in rodents to show instead that cerebrospinal fluid surrounding the brain enters the tissue within minutes of an ischemic insult along perivascular flow channels. This process was initiated by ischemic spreading depolarizations along with subsequent vasoconstriction, which in turn enlarged the perivascular spaces and doubled glymphatic inflow speeds. Thus, our understanding of poststroke edema needs to be revised, and these findings could provide a conceptual basis for development of alternative treatment strategies.

Original language	English (US)
Article number	eaaw7462
Journal	Science
Volume	367
Issue number	6483
DOIs	https://doi.org/10.1126/science.aaw7462
State	Published - Mar 13 2020
Externally published	Yes

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© 2020 American Association for the Advancement of Science. All rights reserved.

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Mestre, H., Du, T., Sweeney, A. M., Liu, G., Samson, A. J., Peng, W., Mortensen, K. N., Stæger, F. F., Bork, P. A. R., Bashford, L., Toro, E. R., Tithof, J., Kelley, D. H., Thomas, J. H., Hjorth, P. G., Martens, E. A., Mehta, R. I., Solis, O., Blinder, P., ... Nedergaard, M. (2020). Cerebrospinal fluid influx drives acute ischemic tissue swelling. Science, 367(6483), Article eaaw7462. https://doi.org/10.1126/science.aaw7462

Mestre, H, Du, T, Sweeney, AM, Liu, G, Samson, AJ, Peng, W, Mortensen, KN, Stæger, FF, Bork, PAR, Bashford, L, Toro, ER, Tithof, J, Kelley, DH, Thomas, JH, Hjorth, PG, Martens, EA, Mehta, RI, Solis, O, Blinder, P, Kleinfeld, D, Hirase, H, Mori, Y & Nedergaard, M 2020, 'Cerebrospinal fluid influx drives acute ischemic tissue swelling', Science, vol. 367, no. 6483, eaaw7462. https://doi.org/10.1126/science.aaw7462

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abstract = "Stroke affects millions each year. Poststroke brain edema predicts the severity of eventual stroke damage, yet our concept of how edema develops is incomplete and treatment options remain limited. In early stages, fluid accumulation occurs owing to a net gain of ions, widely thought to enter from the vascular compartment. Here, we used magnetic resonance imaging, radiolabeled tracers, and multiphoton imaging in rodents to show instead that cerebrospinal fluid surrounding the brain enters the tissue within minutes of an ischemic insult along perivascular flow channels. This process was initiated by ischemic spreading depolarizations along with subsequent vasoconstriction, which in turn enlarged the perivascular spaces and doubled glymphatic inflow speeds. Thus, our understanding of poststroke edema needs to be revised, and these findings could provide a conceptual basis for development of alternative treatment strategies.",

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AU - Martens, Erik A.

AU - Mehta, Rupal I.

AU - Solis, Orestes

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AU - Kleinfeld, David

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AU - Mori, Yuki

AU - Nedergaard, Maiken

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AB - Stroke affects millions each year. Poststroke brain edema predicts the severity of eventual stroke damage, yet our concept of how edema develops is incomplete and treatment options remain limited. In early stages, fluid accumulation occurs owing to a net gain of ions, widely thought to enter from the vascular compartment. Here, we used magnetic resonance imaging, radiolabeled tracers, and multiphoton imaging in rodents to show instead that cerebrospinal fluid surrounding the brain enters the tissue within minutes of an ischemic insult along perivascular flow channels. This process was initiated by ischemic spreading depolarizations along with subsequent vasoconstriction, which in turn enlarged the perivascular spaces and doubled glymphatic inflow speeds. Thus, our understanding of poststroke edema needs to be revised, and these findings could provide a conceptual basis for development of alternative treatment strategies.

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Cerebrospinal fluid influx drives acute ischemic tissue swelling

Abstract

Bibliographical note

UN SDGs

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