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Abstract

Background

Heart rate recovery delay is a marker of cardiac autonomic dysfunction. In chronic obstructive pulmonary disease patients, the ventilatory response to exercise during incremental cardiopulmonary exercise test may add information about dynamic hyperinflation by low values of inspiratory capacity/total lung capacity ratio (at peak) and excess ventilation by the slope of minute ventilation to carbon dioxide output ratio (V_E/V_{CO2 slope}). We aimed to assess if the ventilatory response to exercise might be a determinant for heart rate recovery delay.

Design

An observational, prospective study.

Methods

Anthropometric characteristics, lung function and cardiopulmonary exercise test data were recorded in chronic obstructive pulmonary disease outpatients. A cut-off of heart rate recovery of 12 or more beats was used to define heart rate recovery delay.

Results

Of 254 patients enrolled, 156 (61%) showed heart rate recovery delay. As compared to patients with normal heart rate recovery, patients with delay were older, with a worse lung function and with lower values of peak oxygen uptake, maximal workload, oxygen pulse at rest and at peak, and inspiratory capacity/total lung capacity at peak. Conversely, V_E/V_{CO2 slope} and dyspnoea and leg fatigue perception at peak were higher in patients with heart rate recovery delay. In the multivariate regression model adjusted for age, sex, fat-free mass, heart rate at rest and use of β-blockers, we found that inspiratory capacity/total lung capacity at peak (<0.25) (odds ratio 2.61; P = 0.007) and V_E/V_{CO2 slope} (>32) (odds ratio 2.26; P = 0.018) predict the risk of heart rate recovery delay.

Conclusions

In chronic obstructive pulmonary disease outpatients, heart rate recovery is associated with dynamic hyperinflation and excess ventilation during exercise.

Keywords

Heart rate recovery delay chronic obstructive pulmonary disease dynamic hyperinflation ventilatory response to exercise incremental cardiopulmonary exercise test

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Heart rate recovery is associated with ventilatory constraints and excess ventilation during exercise in patients with chronic obstructive pulmonary disease

Abstract

Background

Design

Methods

Results

Conclusions

Keywords

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References

Supplementary Material