Reference values for pulsed Doppler signals from the blood flow velocity on both sides of the pulmonary valve

Oort, A. Van; Knecht, S. De; Dam, I. Van; Heringa, A.; Boo, Theo de; Alsters, J.; Hopman, J.C.W.; Fast, J. H.; Werf, T. van der; Daniëls, Otto

doi:10.1093/oxfordjournals.eurheartj.a062515

Cited by 7 publications

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“…These data are in agreement with the modeling study by Barstow et al (6), who proposed that PhI duration would depend on "the rate of adjustment of blood flow" at exercise onset and the size of venous volume. Moreover, our finding of an age-induced reduction of the average pulmonary flow acceleration during phase I is in line with available data describing a decrease of resting pulmonary artery flow acceleration over age (56) in normal subjects, which finds its biological plausibility in the reduction of right ventricular systolic and diastolic function (33), increase of pulmonary arterial pressure and pulmonary vascular resistances (17,30), and augmentation of pulmonary artery stiffness (40) with increasing age. Also, the 60 -70 group showed a lean body mass significantly lower than that of the 20 -30 group; as a greater muscle mass has been shown to enhance venous emptying of the healthy subject's leg (31), a higher skeletal muscle pump-induced venous return during phase I may have played a contributing role in the youngest groups of our study population.…”

Section: Phi Duration Changes Over Agesupporting

confidence: 91%

Age-related prolongation of phase I of V̇o₂ on-kinetics in healthy humans

Mezzani¹,

Grassi

Giordano

et al. 2010

American Journal of Physiology-Regulatory, Integrative and Comp

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Data are lacking regarding age-related modifications of phase I (PhI) of pulmonary Vo(2) on-kinetics during moderate-intensity exercise. We studied three groups (aged 20-30, 40-50, and 60-70 years) of 10 normal subjects, who underwent one incremental and four below-gas exchange threshold constant-power cardiopulmonary exercise tests. Data from constant-power tests were time-aligned and averaged, and the PhI-phase II transition (PhI-IItr) determined when a sharp decrease from baseline of respiratory exchange ratio occurred. The Vo(2) phase II time constant (tau) was obtained by an exponential fitting starting 1) from PhI-IItr ("experimental" fitting strategy) and 2) after 20 s from exercise onset ("fixed-duration" fitting strategy). Assuming estimated arterial-venous O(2) concentration difference not to change with respect to resting value, cardiac output (CO) values at rest and PhI-IItr were obtained according to Fick's principle. Average pulmonary flow acceleration (AFA) during PhI was calculated as the ratio between CO increase during PhI and PhI duration. PhI duration was related to age (r = 0.74, P < 0.0001), increasing from 21 +/- 3 s to 27 +/- 3 s to 32 +/- 4 s in the 20-30, 40-50, and 60-70 age groups, respectively, and to AFA (r = -0.60, P < 0.001), but not to CO increase during PhI. With respect to the experimental fitting strategy, the fixed-duration strategy overestimated Vo(2) phase II tau the more the higher the subject's age, with a lower goodness of fit in the 60-70 group (SE 0.035 vs. 0.056, P < 0.01). In conclusion, PhI duration is related to age in healthy male humans and is linked to CO acceleration-rather than to increase-during PhI. A significant overestimation of phase II tau thus may occur in healthy elderly subjects and patients with a pathologically induced longer PhI duration when fitting data where the PhI-PhIItr was not experimentally determined but assumed to be a set value (i.e., 20 s).

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Section: Phi Duration Changes Over Agesupporting

confidence: 91%

Age-related prolongation of phase I of V̇o₂ on-kinetics in healthy humans

Mezzani¹,

Grassi

Giordano

et al. 2010

American Journal of Physiology-Regulatory, Integrative and Comp

View full text Add to dashboard Cite

show abstract

“…4 Briefly, any pulsed Doppler signal is characterized by a definite spectral width that reflects the broadening of instantaneous velocities recorded within the sample volume. 10,11 The larger is the envelope thickness, the more dispersed are the velocities. Assuming normality of velocity distribution at any instant, 12 a rough adjustment for spectral dispersion can be obtained by estimating the mean between the maximal and minimal velocity identified by the signal in that instant.…”

Section: Pulsed Td Analysismentioning

confidence: 99%