Repeated maximal exercise significantly reduced cardiorespiratory coordination, evidenced by a decrease in the eigenvalues of the first principal component (d = 1.08, p = 0.01).
Does repeated maximal exercise alter cardiorespiratory coordination in participants?
Repeated maximal exercise reduces cardiorespiratory coordination despite no significant differences in conventional maximal performance and physiological variables, highlighting the utility of CRC evaluation.
Standardized Mean Difference: 1.08
Absolute Event Rate: 3.86% vs 4.2%
p-value: p=0.01
Increases in cardiorespiratory coordination (CRC) after training with no differences in performance and physiological variables have recently been reported using a principal component analysis approach. However, no research has yet evaluated the short-term effects of exercise on CRC. The aim of this study was to delineate the behaviour of CRC under different physiological initial conditions produced by repeated maximal exercises. Fifteen participants performed 2 consecutive graded and maximal cycling tests. Test 1 was performed without any previous exercise, and Test 2 six min after Test 1. Both tests started at 0W and the workload was increased by 25 W/min in males and 20 W/min in females, until they were not able to maintain the prescribed cycling frequency of 70 rpm for more than 5 consecutive seconds. A principal component (PC) analysis of selected cardiovascular and cardiorespiratory variables (expired fraction of O2, expired fraction of CO2, ventilation, systolic blood pressure, diastolic blood pressure, and heart rate) was performed to evaluate the CRC defined by the number of PCs in both tests. In order to quantify the degree of coordination, the information entropy was calculated and the. eigenvalues of the first PC (PC1) were compared between tests. Although no significant differences were found between the tests with respect to the performed maximal workload (Wmax), maximal oxygen consumption (VO2max), or ventilatory threshold (VT), an increase in the number of PCs and/or a decrease of eigenvalues of PC1 (t = 2.95; p = .01; d = 1.08) was found in Test 2 compared to Test 1. Moreover, entropy was significantly higher (Z = 2.33; p = .02; d = 1.43) in the last test. In conclusion, despite the fact that no significant differences were observed in the conventionally explored maximal performance and physiological variables (Wmax, VO2max, and VT) between tests, a reduction of CRC was observed in Test 2. These results emphasize the interest of CRC evaluation in the assessment and interpretation of cardiorespiratory exercise testing.
García‐Retortillo et al. (Wed,) conducted a other in Healthy adults (n=15). Repeated maximal exercise vs. Initial maximal exercise (Test 1) was evaluated on Eigenvalues of the first principal component (PC1) (d = 1.08, p=0.01). Repeated maximal exercise significantly reduced cardiorespiratory coordination, evidenced by a decrease in the eigenvalues of the first principal component (d = 1.08, p = 0.01).