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1.
Brain ; 145(2): 787-797, 2022 04 18.
Article in English | MEDLINE | ID: mdl-34581781

ABSTRACT

Cerebral oedema develops after anoxic brain injury. In two models of asphyxial and asystolic cardiac arrest without resuscitation, we found that oedema develops shortly after anoxia secondary to terminal depolarizations and the abnormal entry of CSF. Oedema severity correlated with the availability of CSF with the age-dependent increase in CSF volume worsening the severity of oedema. Oedema was identified primarily in brain regions bordering CSF compartments in mice and humans. The degree of ex vivo tissue swelling was predicted by an osmotic model suggesting that anoxic brain tissue possesses a high intrinsic osmotic potential. This osmotic process was temperature-dependent, proposing an additional mechanism for the beneficial effect of therapeutic hypothermia. These observations show that CSF is a primary source of oedema fluid in anoxic brain. This novel insight offers a mechanistic basis for the future development of alternative strategies to prevent cerebral oedema formation after cardiac arrest.


Subject(s)
Brain Edema , Heart Arrest , Hypothermia, Induced , Hypoxia, Brain , Animals , Brain , Brain Edema/etiology , Heart Arrest/complications , Heart Arrest/therapy , Humans , Hypoxia, Brain/complications , Mice
2.
Science ; 367(6483)2020 03 13.
Article in English | MEDLINE | ID: mdl-32001524

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.


Subject(s)
Brain Edema/cerebrospinal fluid , Brain Edema/etiology , Glymphatic System/physiopathology , Stroke/cerebrospinal fluid , Stroke/complications , Animals , Aquaporin 5/metabolism , Brain Edema/diagnostic imaging , Magnetic Resonance Imaging , Male , Mice , Mice, Inbred C57BL , Stroke/diagnostic imaging , Vasoconstriction
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