Effects of low flow on pulmonary vascular flow-pressure curves and pulmonary vascular impedance

doi:10.1016/S0008-6363(98)00301-0

Cardiovascular Research 1999 42(1):183-192; doi:10.1016/S0008-6363(98)00301-0
© 1999 by European Society of Cardiology

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Effects of low flow on pulmonary vascular flow–pressure curves and pulmonary vascular impedance

Serge Brimioulle^*, Marco Maggiorini, Jean Stephanazzi, Françoise Vermeulen, Philippe Lejeune and Robert Naeije

Laboratory of Cardiovascular and Respiratory Physiology, Free University of Brussels, Brussels, Belgium

^* Corresponding author. Department of Intensive Care, Erasme University Hospital, Lennik Road 808, B-1070 Brussels, Belgium. Tel.: +32-2-555-4410; fax: 32-2-555-4698, E-mail address: sbrimi@ulb.ac.be (S. Brimioulle)

Objective: Flow–pressure curves and vascular impedanceare commonly used to investigate pulmonary circulation, butthey may be affected at low flow by reflex neurohumoral activation.We therefore investigated the mechanical effects and the reflexeffects of decreased flow on pulmonary vascular resistance andimpedance. Methods: In ten anaesthetized dogs, we compared flow–pressurecurves generated in less than 10 s to prevent sympathetic activation(fast curves), or generated over 20–30 min to allow neurohumoralequilibration (slow curves), in hyperoxia (inspired oxygen,40%) and in hypoxia (inspired oxygen, 10%), before and afteradrenergic blockade by phentolamine and propranolol. Resistancewas assessed from the flow–pressure relationship. Impedancewas computed from instantaneous flow and pressure obtained withan ultrasonic flowmeter and a micromanometer-tipped catheter.Results: At baseline, fast flow–pressure curves were steeperand had a lower pressure intercept. Transient low flow did notaffect heart rate or pulmonary arterial elastance. Sustainedlow flow increased heart rate, resistance and elastance, suggestingbaroreceptor-induced sympathetic stimulation. After adrenergicblockade, no difference persisted between effects of transientand sustained low flow. In hypoxia, slow and fast flow–pressurecurves were similar. Hypoxia increased heart rate and resistancebut did not decrease elastance, suggesting chemoreceptor-inducedsympathetic stimulation. In hypoxia, differences between transientand sustained low flow were no longer significant, and werecompletely suppressed by adrenergic blockade. In two additionaldogs, epinephrine infusion increased pulmonary vascular resistanceand elastance. Conclusions: We conclude that (1) compared totransient low flow, sustained low flow is associated with increasesin distal resistance and proximal elastance due to sympatheticstimulation and (2) these differences between the effects oftransient and sustained low flow do not persist in hypoxia,because of an already present chemoreceptor-induced sympatheticstimulation.

KEYWORDS Pulmonary circulation; Resistance; Impedance; Elastance; Hypoxia; Baroreceptor; Chemoreceptor; Sympathetic system; Adrenergic blockade

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