Hemodynamic and cardiorespiratory responses to submaximal and maximal exercise in adults with Down syndrome

Introduction: The genetic disorder causing Down syndrome (DS) affects the cardiorespiratory and hemodynamic parameters. When exercising, sufficient blood flow is necessary for active muscles. Cardiac output (Q) must be proportional to the peripheral requirements. In case the stroke volume (SV) is lo...

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Published in:Frontiers in physiology 2022-08, Vol.13, p.905795-905795
Main Authors: Oviedo, Guillermo R., Carbó-Carreté, María, Guerra-Balic, Myriam, Tamulevicius, Nauris, Esquius, Laura, Guàrdia-Olmos, Joan, Javierre, Casimiro
Format: Article
Language:English
Subjects:
blood preasure
cardiorespirarory fitness
down syndrome
exercice
hemodymamics
Physiology
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Summary:Introduction: The genetic disorder causing Down syndrome (DS) affects the cardiorespiratory and hemodynamic parameters. When exercising, sufficient blood flow is necessary for active muscles. Cardiac output (Q) must be proportional to the peripheral requirements. In case the stroke volume (SV) is lower, the heart rate (HR) will increase further in order to maintain an adequate blood flow in the active territories (HR compensatory response). People with DS have a lower HR response to maximal exercise. Nevertheless, the response of the hemodynamic and cardiorespiratory parameters during the submaximal phases of maximal exercise was not well studied. Objective: to evaluate cardiorespiratory and hemodynamic parameters 1) during submaximal and 2) maximal metabolic treadmill test in individuals with and without DS. Methods: fifteen adults with DS (age = 27.33 ± 4.98 years old; n = 12 males/3 females) and 15 adults without disabilities, matched by age and sex, participated in this cross-sectional study. Peak and submaximal cardiorespiratory and hemodynamic parameters were measured during a treadmill test. Linear mixed-effects models were used to analyse interactions between the variables. Post-hoc analyses were employed to assess within and between-group differences. Results: The DS group showed lower peak values for ventilation (VE), respiratory exchange ratio (RER), tidal volume (V T ), ventilatory equivalent for O 2 (VEqO 2 ), end-tidal partial pressure for O 2 (P ET O 2 ), O 2 uptake (VO 2 ) and CO 2 production (all p < 0 .050), Q, SV, systolic and diastolic blood pressure (SBP, DBP), and HR (all p < 0 .050). There were group-by-time interactions (all p < 0 .050) for all ventilatory submaximal values. Significant group and time differences were observed for VE; RER; respiratory rate (RR); VEqO 2 ; P ET O 2 ; VO 2, and V T (all p < 0 .050). There were also group-by-time interactions (all p < 0 .050) and group and time differences for SBP, mean arterial blood pressure (MAP) and HR (all p < 0.010). Conclusion: During submaximal exercise, we verified a compensatory response of HR, and greater VE and VO 2 in the individuals with DS. In addition, we were able to observe that the DS group had a reduced SBP and MAP response to submaximal exercise. On the other hand, we found that adults with DS have lower peak hemodynamic and cardiorespiratory values, and a lower cardiac reserve. Further research is warranted to investigate the effects of these results on the general
ISSN:1664-042X
1664-042X
DOI:10.3389/fphys.2022.905795