Literature DB >> 20547971

Cerebrovascular regulation during transient hypotension and hypertension in humans.

Yu-Chieh Tzeng1, Chris K Willie, Greg Atkinson, Samuel J E Lucas, Aaron Wong, Philip N Ainslie.   

Abstract

The cerebrovasculature dilates or constricts in response to acute blood pressure changes to stabilize cerebral blood flow across a range of blood pressures. It is unclear, however, whether such dynamic cerebral autoregulation (dCA) is equally effective in responding to falling versus rising blood pressure. In this study we applied a pharmacological approach to evaluate dCA gain to transient hypotension and hypertension and compared this method with 2 established indices of dCA that do not explicitly differentiate between dCA efficacy and falling versus rising blood pressure. Middle cerebral arterial velocity and blood pressure recordings were made in 26 healthy volunteers randomized to 2 protocols. In 10 subjects, dCA gain to transient hypotension induced with intravenous nitroprusside was compared with dCA gain to transient hypertension induced with intravenous phenylephrine. In 16 subjects, dCA gain to transient hypotension induced with intravenous nitroprusside was compared with the rate of regulation and autoregulatory index derived from transient hypotension induced with the thigh cuff deflation technique. dCA gain to transient hypotension induced with intravenous nitroprusside was unrelated to dCA gain to transient hypertension induced with intravenous phenylephrine (r=0.06; P=0.87) and was consistently greater than dCA gain to transient hypertension induced with intravenous phenylephrine (0.57+/-0.16 versus 0.31+/-0.20 cm/s per millimeter of mercury; P<0.01). However, dCA gain to transient hypotension induced with intravenous nitroprusside was inversely related to the rate of regulation (r=-0.52; P=0.037) and autoregulatory index (r=-0.66; P=0.005). These data indicate that, under our laboratory conditions, dCA appears to be inherently nonlinear with disparate efficacy against rising and falling blood pressure, and dCA gain derived from pharmacologically induced transient hypotension correlates with established nonpharmacological indices of dCA.

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Year:  2010        PMID: 20547971     DOI: 10.1161/HYPERTENSIONAHA.110.152066

Source DB:  PubMed          Journal:  Hypertension        ISSN: 0194-911X            Impact factor:   10.190


  39 in total

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Review 5.  Integrative regulation of human brain blood flow.

Authors:  Christopher K Willie; Yu-Chieh Tzeng; Joseph A Fisher; Philip N Ainslie
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6.  Phenylephrine alteration of cerebral blood flow during orthostasis: effect on n-back performance in chronic fatigue syndrome.

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7.  Assessment of the cerebral pressure-flow relationship using psychological stress to manipulate blood pressure.

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Review 8.  The impact of cerebrovascular aging on vascular cognitive impairment and dementia.

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Review 9.  Integrative physiological and computational approaches to understand autonomic control of cerebral autoregulation.

Authors:  Can Ozan Tan; J Andrew Taylor
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10.  Blood pressure decrease correlates with tau pathology and memory decline in hypertensive elderly.

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Journal:  Neurobiol Aging       Date:  2013-08-19       Impact factor: 4.673
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