Brainstem neurons survive the identical ischemic stress that kills higher neurons: insight to the persistent vegetative state

Global ischemia caused by heart attack, pulmonary failure, near-drowning or traumatic brain injury often damages the higher brain but not the brainstem, leading to a 'persistent vegetative state' where the patient is awake but not aware. Approximately 30,000 U.S. patients are held captive...

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Bibliographic Details
Published in:	PloS one Vol. 9; no. 5; p. e96585
Main Authors:	Brisson, C Devin, Hsieh, Yi-Ting, Kim, Danielle, Jin, Albert Y, Andrew, R David
Format:	Journal Article
Language:	English
Published:	United States Public Library of Science 06-05-2014 Public Library of Science (PLoS)
Subjects:	Animals Beading Biology and Life Sciences Brain Brain damage Brain injuries Brain Ischemia - metabolism Brain Ischemia - physiopathology Brain slice preparation Brain stem Brain Stem - metabolism Brain Stem - physiopathology Cell survival Cerebellar Cortex - metabolism Cerebellar Cortex - physiopathology Cerebellum Comparative analysis Corpus Striatum - metabolism Corpus Striatum - physiopathology Cortex Cortex (somatosensory) Dendrites - metabolism Dendrites - physiology Depolarization Deprivation Drowning Glucose Gray Matter - metabolism Gray Matter - physiopathology Head injuries Heart attack Heart diseases Hippocampus Hippocampus - metabolism Hippocampus - physiopathology Hypothalamus Hypothalamus - metabolism Hypothalamus - physiopathology Hypoxia Ischemia Light transmittance Medicine and Health Sciences Membrane potential Membrane Potentials - physiology Mesencephalon Mice Microscopy Motor nuclei Myocardial infarction Na+/K+-exchanging ATPase Neocortex - metabolism Neocortex - physiopathology Neostriatum Neuroimaging Neurons Neurons - metabolism Neurons - physiology Nuclei (cytology) Ouabain Oxygen Palytoxin Persistent vegetative state Persistent Vegetative State - metabolism Persistent Vegetative State - physiopathology Rats Rats, Sprague-Dawley Rodents Sodium-Potassium-Exchanging ATPase - metabolism Somatosensory cortex Substantia grisea Sucrose Thalamus Thalamus - metabolism Thalamus - physiopathology Traumatic brain injury Vasoconstriction Ontario Canada Canada
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Summary:	Global ischemia caused by heart attack, pulmonary failure, near-drowning or traumatic brain injury often damages the higher brain but not the brainstem, leading to a 'persistent vegetative state' where the patient is awake but not aware. Approximately 30,000 U.S. patients are held captive in this condition but not a single research study has addressed how the lower brain is preferentially protected in these people. In the higher brain, ischemia elicits a profound anoxic depolarization (AD) causing neuronal dysfunction and vasoconstriction within minutes. Might brainstem nuclei generate less damaging AD and so be more resilient? Here we compared resistance to acute injury induced from simulated ischemia by 'higher' hippocampal and striatal neurons versus brainstem neurons in live slices from rat and mouse. Light transmittance (LT) imaging in response to 10 minutes of oxygen/glucose deprivation (OGD) revealed immediate and acutely damaging AD propagating through gray matter of neocortex, hippocampus, striatum, thalamus and cerebellar cortex. In adjacent brainstem nuclei, OGD-evoked AD caused little tissue injury. Whole-cell patch recordings from hippocampal and striatal neurons under OGD revealed sudden membrane potential loss that did not recover. In contrast brainstem neurons from locus ceruleus and mesencephalic nucleus as well as from sensory and motor nuclei only slowly depolarized and then repolarized post-OGD. Two-photon microscopy confirmed non-recoverable swelling and dendritic beading of hippocampal neurons during OGD, while mesencephalic neurons in midbrain appeared uninjured. All of the above responses were mimicked by bath exposure to 100 µM ouabain which inhibits the Na+/K+ pump or to 1-10 nM palytoxin which converts the pump into an open cationic channel. Therefore during ischemia the Na+/K+ pump of higher neurons fails quickly and extensively compared to naturally resilient hypothalamic and brainstem neurons. The selective survival of lower brain regions that maintain vital functions will support the persistent vegetative state.
Bibliography:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 Conceived and designed the experiments: RDA CDB. Performed the experiments: RDA CDB YH DK. Analyzed the data: RDA CDB YH DK. Contributed reagents/materials/analysis tools: RDA AYJ. Wrote the paper: RDA CDB. Competing Interests: The authors have declared that no competing interests exist.
ISSN:	1932-6203 1932-6203
DOI:	10.1371/journal.pone.0096585