Kevin Forton

Effects of body position on exercise capacity and pulmonary vascular pressure-flow relationships

There has been revival of interest in exercise testing of the pulmonary circulation for the diagnosis of pulmonary vascular disease, but there still is uncertainty about body position and the most relevant measurements. Doppler echocardiography pulmonary hemodynamic measurements were performed at progressively increased workloads in 26 healthy adult volunteers in supine, semirecumbent, and upright positions that were randomly assigned at 24-h intervals. Mean pulmonary artery pressure (mPAP) was estimated from the maximum tricuspid regurgitation jet velocity. Cardiac output was calculated from the left ventricular outflow velocity-time integral. Pulmonary vascular distensibility α-index, the percent change of vessel diameter per millimeter mercury of mPAP, was calculated from multipoint mPAP-cardiac output plots. Body position did not affect maximum oxygen uptake (Vo2max), maximum respiratory exchange ratio, ventilatory equivalent for carbon dioxide, or slope of mPAP-cardiac output relationships, which was on average of 1.5 ± 0.4 mmHg·l-1·min-1 Maximum mPAP, cardiac output, and total pulmonary vascular resistance were, respectively, 34 ± 4 mmHg, 18 ± 3 l/min, and 1.9 ± 0.3 Wood units. However, the semirecumbent position was associated with a 10% decrease in maximum workload. Furthermore, cardiac output-workload or cardiac output-Vo2 relationships were nonlinear and variable. These results suggest that body position does not affect maximum exercise testing of the pulmonary circulation when results are expressed as mPAP-cardiac output or maximum total pulmonary vascular resistance. Maximum workload is decreased in semirecumbent compared with upright exercise. Workload or Vo2 cannot reliably be used as surrogates for cardiac output.

Pulmonary vascular function and exercise capacity in black sub-Saharan Africans.

Sex and age affect the pulmonary circulation. Whether there may be racial differences in pulmonary vascular function is unknown. Thirty white European Caucasian subjects (15 women) and age and body-size matched 30 black sub-Saharan African subjects (15 women) underwent a cardiopulmonary exercise test and exercise stress echocardiography with measurements of pulmonary artery pressure (PAP) and cardiac output (CO). A pulmonary vascular distensibility coefficient α was mathematically determined from the natural curvilinearity of multipoint mean PAP (mPAP)-CO plots. Maximum oxygen uptake (V̇o2max) and workload were higher in the whites, while maximum respiratory exchange ratio and ventilatory equivalents for CO2 were the same. Pulmonary hemodynamics were not different at rest. Exercise was associated with a higher maximum total pulmonary vascular resistance, steeper mPAP-CO relationships, and lower α-coefficients in the blacks. These differences were entirely driven by higher slopes of mPAP-CO relationships (2.5 ± 0.7 vs. 1.4 ± 0.7 mmHg·l(-1)·min; P < 0.001) and lower α-coefficients (0.85 ± 0.33 vs. 1.35 ± 0.51%/mmHg; P < 0.01) in black men compared with white men. There were no differences in any of the hemodynamic variables between black and white women. In men only, the slopes of mPAP-CO relationships were inversely correlated to V̇o2max (P < 0.01). Thus the pulmonary circulation is intrinsically less distensible in black sub-Saharan African men compared with white Caucasian Europeans men, and this is associated with a lower exercise capacity. This study did not identify racial differences in pulmonary vascular function in women.

Resistive or dynamic exercise stress testing of the pulmonary circulation and the right heart

There has been recent revival of interest in exercise stress testing of the pulmonary circulation and the right ventricle (RV) for the differential diagnosis of dyspnoea or latent pre- or post-capillary pulmonary hypertension [1–3]. However, guidelines remain cautious because of persistent uncertainties about protocols and the limits of normal [4]. In fact, exercise protocols still vary, with either cycling [3, 6–8], weight lifting [5, 6] or even handgrip [9] modalities, with invasive [3, 5–7, 9] or non-invasive [7, 8, 10] measurements either during [3, 6–10] or after [5] the exercise stress. Furthermore, pulmonary artery pressure (PAP) has been reported either alone [5, 8] or as a function of either cardiac output (CO) [1–3, 7, 10], workload [7, 11] or oxygen uptake (V′O2) [12]. In the meantime, flow-corrected PAP during exercise emerges as the measurement of choice for pulmonary vascular function [1–3], and body position may not matter provided a sufficient number of exercise pressure-flow coordinates is generated to smoothen out higher baseline pulmonary vascular resistance (PVR) in the upright position [10], but there remains uncertainty about the most relevant measurements of RV function [7, 13, 14]. Although there is a rationale in favour of incremental dynamic exercise, there is currently no consensus about the optimal exercise modality. We therefore compared the cardiovascular and gas exchange effects of resistive (handgrip), mixed resistive/dynamic (weight lifting) or dynamic (cycling) exercise on the pulmonary circulation and the RV in healthy volunteers. Exercise stress testing of the pulmonary circulation and the right heart should be dynamic, not resistive http://ow.ly/ZEyF30c9RlP

Lung diffusing capacity in sub-Saharan Africans versus European Caucasians

Single breath measurements of lung diffusing capacity (DL) for carbon monoxide (CO) and nitric oxide (NO) were performed in age-, sex-, weight- and height-matched 32 sub-Saharan Africans (13 women) and 32 Caucasian Europeans, and repeated in 14 of each group at 80% of maximum exercise capacity. In Africans versus Caucasians respectively, DLNO was 153±31 vs 176±38ml/mmHg/min at rest (P<0.001) and 210±48 vs 241±52ml/mmHg/min at exercise (P<0.01) while hemoglobin-adjusted DLCO was 29±6 vs 34±6ml/mmHg/min at rest (P<0.001), and 46±11 vs 51±13ml/mmHg/min at exercise (P<0.01). However there were no differences in DLCO/alveolar volume(VA) (KCO) and DLNO/VA(KNO). The sitting-to-standing height ratio was lower in the Africans. Differences in lung volume with respect to body height explain lower DLNO and DLCO in sub-Saharan Africans as compared to Caucasian Europeans.

Right ventricular dyssynchrony during hypoxic breathing but not during exercise in healthy subjects: a speckle tracking echocardiography study

What is the central question of this study? Right ventricular dyssynchrony in severe pulmonary hypertension is associated with a poor prognosis. However, it has recently been observed in patients with lung or connective tissue disease and pulmonary artery pressure at the upper limits of normal. The mechanisms of right ventricular dyssynchrony in pulmonary hypertension remain uncertain. What is the main finding and its importance? Acute hypoxic breathing, but not normoxic exercise, induces an increase in right ventricular dyssynchrony detected by speckle tracking echocardiography in healthy subjects. These results add new insights into the determinants of right ventricular dyssynchrony, suggesting a role for systemic factors added to afterload in the pathophysiology of right ventricular inhomogeneity of contraction.