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(Hypertension. 2000;35:965.)
© 2000 American Heart Association, Inc.
Scientific Contributions |
Effects of Renal Medullary and Intravenous Norepinephrine on Renal Antihypertensive Function
From the Department of Physiology, Monash University, Clayton Victoria, Australia, and the Department of Physiology (G.B.), University of Göteborg, Göteborg, Sweden.
Correspondence to Anabela G. Correia, Department of Physiology, Monash University, Clayton, Victoria, 3168, Australia. E-mail anabela.correia{at}med.monash.edu.au
Abstract—Increasing renal
arterial pressure activates at least 3
antihypertensive mechanisms: reduced renin release, pressure
natriuresis, and release of a putative renal medullary depressor
hormone. To examine the role of renal medullary perfusion in these
mechanisms, we tested the effects of the infusion of
norepinephrine, either infusion into the renal medullary
interstitium or intravenous infusion, on responses to
increased renal arterial pressure in
pentobarbital-anesthetized rabbits. We used an extracorporeal
circuit, which allows renal arterial pressure to be set to
any level above or below systemic arterial pressure. With
renal arterial pressure initially set at 65 mm Hg,
intravenous and medullary interstitial
norepinephrine (300 ng · kg-1 ·
min-1) similarly increased mean arterial
pressure (by 12% to 17% of baseline) and reduced total renal blood
flow (by 16% to 17%) and cortical perfusion (by 13% to 19%), but
only medullary norepinephrine reduced medullary perfusion
(by 28%). When renal arterial pressure was increased to
160 mm Hg, in steps of 65 mm Hg, urine output and
sodium excretion increased exponentially, and plasma renin activity and
mean arterial pressure fell. Medullary
interstitial but not intravenous
norepinephrine attenuated the increased diuresis
and natriuresis and the depressor response to increased renal
arterial pressure. This suggests that
norepinephrine can act within the renal medulla to inhibit
these renal antihypertensive mechanisms, perhaps by reducing medullary
perfusion. These observations support the concept that medullary
perfusion plays a critical role in the long-term control of
arterial pressure by its influence on pressure
diuresis/natriuresis mechanisms and also by affecting
the release of the putative renal medullary depressor hormone.
Key Words: kidney medulla • laser-Doppler flowmetry • norepinephrine • natriuresis • renal circulation
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