Cerebral Autoregulation in Subjects Adapted and Not Adapted to High Altitude

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Stroke. 2000;31:2314-2318

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(Stroke. 2000;31:2314.)
© 2000 American Heart Association, Inc.

Original Contributions

Cerebral Autoregulation in Subjects Adapted and Not Adapted to High Altitude

Gerard F. A. Jansen, MD; Anne Krins, BSc; Buddha Basnyat, MD; Andries Bosch, PhD Joseph A. Odoom, PhD

From the Departments of Anesthesiology (G.F.A.J., A.K., J.A.O.) and Neurosurgery (A.B.), Academic Medical Centre, University of Amsterdam, Amsterdam, the Netherlands, and Nepal International Clinic (B.B.), Kathmandu, Nepal. Correspondence and reprint requests to Gerard F.A. Jansen, MD, Department of Anesthesiology, H-1-Z, Academic Medical Centre, University of Amsterdam, PO Box 22660, 1100 DD Amsterdam, Netherlands.

Background and Purpose—Impaired cerebral autoregulation(CA) from high-altitude hypoxia may cause high-altitude cerebraledema in newcomers to a higher altitude. Furthermore, it isassumed that high-altitude natives have preserved CA. However,cerebral autoregulation has not been studied at altitude.

Methods—We studied CA in 10 subjects at sea level andin 9 Sherpas and 10 newcomers at an altitude of 4243 m by evaluating theeffect of an increase of mean arterial blood pressure (MABP)with phenylephrine infusion on the blood flow velocity in themiddle cerebral artery (Vmca), using transcranial Doppler. Theoretically,no change of Vmca in response to an increase in MABP would implyperfect autoregulation. Complete loss of autoregulation is presentif Vmca changes proportionally with changes of MABP.

Results—In the sea-level group, at a relative MABP increaseof 23±4% during phenylephrine infusion, relative Vmcadid not change essentially from baseline Vmca (2±7%, P=0.36),which indicated intact autoregulation. In the Sherpa group,at a relative MABP increase of 29±7%, there was a uniformand significant increase of Vmca of 24±9% (P<0.0001)from baseline Vmca, which indicated loss of autoregulation.The newcomers showed large variations of Vmca in response toa relative MABP increase of 21±6%. Five subjects showed increasesof Vmca of 22% to 35%, and 2 subjects showed decreases of Vmcaof 21% and 23%.

Conclusions—All Sherpas and the majority of the newcomersshowed impaired CA. It indicates that an intact autoregulatoryresponse to changes in blood pressure is probably not a hallmarkof the normal human cerebral vasculature at altitude and thatimpaired CA does not play a major role in the occurrence ofcerebral edema in newcomers to the altitude.

Key Words: altitude • autoregulation • phenylephrine • ultrasonography

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