BACKGROUND: Intracranial pressure elevation, peaking three to seven post-stroke is well recognized following large strokes. Data following small-moderate stroke are limited. Therapeutic hypothermia improves outcome after cardiac arrest, is strongly neuroprotective in experimental stroke, and is under clinical trial in stroke. Hypothermia lowers elevated intracranial pressure; however, rebound intracranial pressure elevation and neurological deterioration may occur during rewarming. HYPOTHESES: (1) Intracranial pressure increases 24 h after moderate and small strokes. (2) Short-duration hypothermia-rewarming, instituted before intracranial pressure elevation, prevents this 24 h intracranial pressure elevation. METHODS: Long-Evans rats with two hour middle cerebral artery occlusion or outbred Wistar rats with three hour middle cerebral artery occlusion had intracranial pressure measured at baseline and 24 h. Wistars were randomized to 2·5 h hypothermia (32·5°C) or normothermia, commencing 1 h after stroke. RESULTS: In Long-Evans rats (n = 5), intracranial pressure increased from 10·9 ± 4·6 mmHg at baseline to 32·4 ± 11·4 mmHg at 24 h, infarct volume was 84·3 ± 15·9 mm(3) . In normothermic Wistars (n = 10), intracranial pressure increased from 6·7 ± 2·3 mmHg to 31·6 ± 9·3 mmHg, infarct volume was 31·3 ± 18·4 mm(3) . In hypothermia-treated Wistars (n = 10), 24 h intracranial pressure did not increase (7·0 ± 2·8 mmHg, P < 0·001 vs. normothermia), and infarct volume was smaller (15·4 ± 11·8 mm(3) , P < 0·05). CONCLUSIONS: We saw major intracranial pressure elevation 24 h after stroke in two rat strains, even after small strokes. Short-duration hypothermia prevented the intracranial pressure rise, an effect sustained for at least 18 h after rewarming. The findings have potentially important implications for design of future clinical trials.
BACKGROUND: Intracranial pressure elevation, peaking three to seven post-stroke is well recognized following large strokes. Data following small-moderate stroke are limited. Therapeutic hypothermia improves outcome after cardiac arrest, is strongly neuroprotective in experimental stroke, and is under clinical trial in stroke. Hypothermia lowers elevated intracranial pressure; however, rebound intracranial pressure elevation and neurological deterioration may occur during rewarming. HYPOTHESES: (1) Intracranial pressure increases 24 h after moderate and small strokes. (2) Short-duration hypothermia-rewarming, instituted before intracranial pressure elevation, prevents this 24 h intracranial pressure elevation. METHODS: Long-Evans rats with two hour middle cerebral artery occlusion or outbred Wistar rats with three hour middle cerebral artery occlusion had intracranial pressure measured at baseline and 24 h. Wistars were randomized to 2·5 h hypothermia (32·5°C) or normothermia, commencing 1 h after stroke. RESULTS: In Long-Evans rats (n = 5), intracranial pressure increased from 10·9 ± 4·6 mmHg at baseline to 32·4 ± 11·4 mmHg at 24 h, infarct volume was 84·3 ± 15·9 mm(3) . In normothermic Wistars (n = 10), intracranial pressure increased from 6·7 ± 2·3 mmHg to 31·6 ± 9·3 mmHg, infarct volume was 31·3 ± 18·4 mm(3) . In hypothermia-treated Wistars (n = 10), 24 h intracranial pressure did not increase (7·0 ± 2·8 mmHg, P < 0·001 vs. normothermia), and infarct volume was smaller (15·4 ± 11·8 mm(3) , P < 0·05). CONCLUSIONS: We saw major intracranial pressure elevation 24 h after stroke in two rat strains, even after small strokes. Short-duration hypothermia prevented the intracranial pressure rise, an effect sustained for at least 18 h after rewarming. The findings have potentially important implications for design of future clinical trials.
Authors: Daniel J Beard; Damian D McLeod; Caitlin L Logan; Lucy A Murtha; Mohammad S Imtiaz; Dirk F van Helden; Neil J Spratt Journal: J Cereb Blood Flow Metab Date: 2015-02-11 Impact factor: 6.200
Authors: Lucy A Murtha; Damian D McLeod; Debbie Pepperall; Sarah K McCann; Daniel J Beard; Amelia J Tomkins; William M Holmes; Christopher McCabe; I Mhairi Macrae; Neil J Spratt Journal: J Cereb Blood Flow Metab Date: 2015-03-31 Impact factor: 6.200
Authors: Xue-Han Ning; Outi M Villet; Ming Ge; Laigam N Sekhar; Marshall A Corson; Tracy S Tylee; Lu-Ping Fan; Lin Yao; Chun Zhu; Aaron K Olson; Norman E Buroker; Cheng-Su Xu; David L Anderson; Yong-Kian Soh; Elise Wang; Shi-Han Chen; Michael A Portman Journal: Ther Hypothermia Temp Manag Date: 2014-12-16 Impact factor: 1.286
Authors: Amelia J Tomkins; Nadine Schleicher; Lucy Murtha; Manfred Kaps; Christopher R Levi; Max Nedelmann; Neil J Spratt Journal: Exp Transl Stroke Med Date: 2015-01-27
Authors: Erik B Kulstad; Melissa Naiman; Patrick Shanley; Frank Garrett; Todd Haryu; Donald Waller; Farshid Azarafrooz; Daniel Mark Courtney Journal: BMC Anesthesiol Date: 2015-02-04 Impact factor: 2.217
Authors: Lucy A Murtha; Daniel J Beard; Julia T Bourke; Debbie Pepperall; Damian D McLeod; Neil J Spratt Journal: Front Aging Neurosci Date: 2016-05-27 Impact factor: 5.750
Authors: Lucy A Murtha; Qing Yang; Mark W Parsons; Christopher R Levi; Daniel J Beard; Neil J Spratt; Damian D McLeod Journal: Fluids Barriers CNS Date: 2014-06-06