Mechanisms of pulsus paradoxus during resistive respiratory loading and asthma

To determine the mechanisms of pulsus paradoxus during asthma, six subjects known to have cold air bronchial hyperreactivity were studied while in a quiescent phase of their disease. All were free of significant airway obstruction at the time of study. After placement of an esophageal balloon to estimate intrathoracic pressure, the subjects were assessed during quiet breathing, resistive airway loading and then during a stable period of airway obstruction induced by cold air. Steady state left ventricular volume and performance were measured using radionuclide ventriculography; right ventricular volume was calculated from the stroke volume ratio and right ventricular ejection fraction. Cardiac cycles were segregated according to their occurrence in inspiration or expiration using a flow signal from a pneumotachograph.Combined inspiratory and expiratory resistance produced pulsus paradoxus and changes in esophageal pressure that were similar to those during asthma and significantly greater than those during quiet breathing. These changes were accompanied by decreases in left ventricular diastolic volume and stroke volume during inspiration, and increases in these variables during expiration; right ventricular volume and stroke volume demonstrated changes reciprocal to those seen in the left ventricle. These data indicate that during periods of increase in airway resistance, abnormal pulsus paradoxus results from an exaggeration in the normal inspiratory-expiratory difference in stroke volume mediated primarily by the effects of intrathoracic pressure on ventricular preload

Baroreflex responsiveness during ventilatory acclimatization in humans

We tested the hypothesis that the decline in muscle sympathetic activity during and after 8 h of poikilocapnic hypoxia (Hx) was associated with a greater sympathetic baroreflex-mediated responsiveness. In 10 healthy men and women (n = 2), we measured beat-to-beat blood pressure (Portapres), carotid artery distension (ultrasonography), heart period, and muscle sympathetic nerve activity (SNA; microneurography) during two baroreflex perturbations using the modified Oxford technique before, during, and after 8 h of hypoxia (84% arterial oxygen saturation). The integrated baroreflex response [change of SNA (ΔSNA)/change of diastolic blood pressure (ΔDBP)], mechanical (Δdiastolic diameter/ΔDBP), and neural (ΔSNA/Δdiastolic diameter) components were estimated at each time point. Sympathetic baroreflex responsiveness declined throughout the hypoxic exposure and further declined upon return to normoxia [pre-Hx, −8.3 ± 1.2; 1-h Hx, −7.2 ± 1.0; 7-h Hx, −4.9 ± 1.0; and post-Hx: −4.1 ± 0.9 arbitrary integrated units (AIU)·min−1·mmHg−1; P < 0.05 vs. previous time point for 1-h, 7-h, and post-Hx values]. This blunting of baroreflex-mediated efferent outflow was not due to a change in the mechanical transduction of arterial pressure into barosensory stretch. Rather, the neural component declined in a similar pattern to that of the integrated reflex response (pre-Hx, −2.70 ± 0.53; 1-h Hx, −2.59 ± 0.53; 7-h Hx, −1.60 ± 0.34; and post-Hx, −1.34 ± 0.27 AIU·min−1·μm−1; P < 0.05 vs. pre-Hx for 7-h and post-Hx values). Thus it does not appear as if enhanced baroreflex function is primarily responsible for the reduced muscle SNA observed during intermediate duration hypoxia. However, the central transduction of baroreceptor afferent neural activity into efferent neural activity appears to be reduced during the initial stages of peripheral chemoreceptor acclimatization