Reliability and Physiological Interpretation of Pulmonary Gas Exchange by "Circulatory Equivalents" in Chronic Heart Failure

Chunting Tan; Harry B Rossiter; Janos Porszasz; T Scott Bowen; Klaus K Witte; William W Stringer; Richard Casaburi; James E Hansen

doi:10.1161/JAHA.117.008072

Reliability and Physiological Interpretation of Pulmonary Gas Exchange by "Circulatory Equivalents" in Chronic Heart Failure

J Am Heart Assoc. 2018 Mar 27;7(7):e008072. doi: 10.1161/JAHA.117.008072.

Authors

Chunting Tan^{1

2}, Harry B Rossiter^{3

4}, Janos Porszasz², T Scott Bowen⁴, Klaus K Witte⁵, William W Stringer², Richard Casaburi², James E Hansen²

Affiliations

¹ Department of Respiratory Medicine, Beijing Friendship Hospital Capital Medical University, Beijing, China.
² Division of Respiratory and Critical Care Physiology and Medicine, Rehabilitation Clinical Trials Center, Los Angeles Biomedical Research Institute at Harbor-UCLA Medical Center, Torrance, CA.
³ Division of Respiratory and Critical Care Physiology and Medicine, Rehabilitation Clinical Trials Center, Los Angeles Biomedical Research Institute at Harbor-UCLA Medical Center, Torrance, CA [email protected].
⁴ Faculty of Biological Sciences, University of Leeds, United Kingdom.
⁵ Faculty of Medicine, University of Leeds, United Kingdom.

Abstract

Background: Peak ratios of pulmonary gas-exchange to ventilation during exercise (V˙O2/V˙E and V˙CO2/V˙E, termed "circulatory equivalents") are sensitive to heart failure (HF) severity, likely reflecting low and/or poorly distributed pulmonary perfusion. We tested whether peak V˙O2/V˙E and V˙CO2/V˙E would: (1) distinguish HF patients from controls; (2) be independent of incremental exercise protocol; and (3) correlate with lactate threshold (LT) and ventilatory compensation point (VCP), respectively.

Methods and results: Twenty-four HF patients (61±11 years) with reduced ejection fraction (31±8%) and 11 controls (63±7 years) performed ramp-incremental cycle ergometry. Eighteen HF patients also performed slow (5±1 W/min), medium (9±4 W/min), and fast (19±6 W/min) ramps. Peak V˙O2/V˙E and V˙CO2/V˙E from X-Y plot, and LT and VCP from 9-panel plot, were determined by 2 independent, blinded, assessors. Peak V˙O2/V˙E (31.2±4.4 versus 41.8±4.8 mL/L; P<0.0001) and V˙CO2/V˙E (29.3±3.0 versus 36.9±4.0 mL/L; P<0.0001) were lower in HF than controls. Within individuals, there was no difference across 3 ramp rates in peak V˙O2/V˙E (P=0.62) or V˙CO2/V˙E (P=0.97). Coefficient of variation (CV) in peak V˙O2/V˙E was lower than for LT (5.1±2.1% versus 8.2±3.7%; P=0.014), and coefficient of variation in peak V˙CO2/V˙E was lower than for VCP (3.3±1.8% versus 8.7±4.2%; P<0.001). In all participants, peak V˙O2/V˙E was correlated with, but occurred earlier than, LT (r²=0.94; mean bias, -0.11 L/min), and peak V˙CO2/V˙E was correlated with, but occurred earlier than, VCP (r²=0.98; mean bias -0.08 L/min).

Conclusions: Peak circulatory equivalents during exercise are strongly associated with (but not identical to) LT and VCP. Peak circulatory equivalents are reliable, objective, effort-independent indices of gas-exchange abnormality in HF.

Keywords: cycle ergometry; heart failure; incremental exercise; lactate threshold; ventilatory compensation.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Aged
Anaerobic Threshold
Bicycling
Breath Tests
Chronic Disease
Exercise Test / methods
Exercise Tolerance*
Female
Heart Failure / diagnosis
Heart Failure / physiopathology*
Humans
Lung / blood supply*
Lung / physiopathology*
Male
Middle Aged
Pulmonary Circulation*
Pulmonary Gas Exchange*
Pulmonary Ventilation*
Retrospective Studies
Time Factors

Grants and funding

NIHR-CS-012-032/DH_/Department of Health/United Kingdom