Priming cardiac function with voluntary respiratory maneuvers and effect on early exercise oxygen uptake.

Abstract

Oxygen uptake (V̇o2) at exercise onset is determined in part by acceleration of pulmonary blood flow ([Formula: see text]). Impairments in the [Formula: see text] response can decrease exercise tolerance. Prior research has shown that voluntary respiratory maneuvers can augment venous return, but the corollary impacts on cardiac function, [Formula: see text] and early-exercise V̇o2 remain uncertain. We examined 1) the cardiovascular effects of three distinct respiratory maneuvers (abdominal, AB; rib cage, RC; and deep breathing, DB) under resting conditions in healthy subjects (Protocol 1, n = 13), and 2) the impact of pre-exercise DB on pulmonary O2 transfer during initiation of moderate-intensity exercise (Protocol 2, n = 8). In Protocol 1, echocardiographic analysis showed increased right ventricular (RV) cardiac output and left ventricular (LV) cardiac output (RVCO and LVCO, respectively), following AB (by +23 ± 13 and +18 ± 15%, respectively, P < 0.05), RC (+23 ± 16; +14 ± 15%, P < 0.05), and DB (+27 ± 21; +23 ± 14%, P < 0.05). In Protocol 2, DB performed for 12 breaths produced a pre-exercise increase in V̇o2 (+801 ± 254 mL·min-1 over ∼6 s), presumably from increased [Formula: see text], followed by a reduction in pulmonary O2 transfer during early phase exercise (first 20 s) compared with the control condition (149 ± 51 vs. 233 ± 65 mL, P < 0.05). We conclude that 1) respiratory maneuvers enhance RVCO and LVCO in healthy subjects under resting conditions, 2) AB, RC, and DB have similar effects on RVCO and LVCO, and 3) DB can increase [Formula: see text] before exercise onset. These findings suggest that pre-exercise respiratory maneuvers may represent a promising strategy to prime V̇o2 kinetics and thereby to potentially improve exercise tolerance in patients with impaired cardiac function.NEW & NOTEWORTHY We demonstrate that different breathing maneuvers can augment both right and left-sided cardiac output in healthy subjects. These maneuvers, when performed immediately before exercise, result in a pre-exercise "cardiodynamic" increase in oxygen uptake (V̇o2) associated with a subsequent reduction in the "cardiodynamic" V̇o2 normally seen during early exercise. We conclude that pre-exercise breathing maneuvers are a plausible tool worthy of additional study to prime V̇o2 kinetics and improve exercise tolerance in patients with cardiovascular disease.