Agreement of concomitant cardiac output measurement by thoracic bio‐impedance and inert gas rebreathing in healthy subjects

Purpose Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies have compared the use of thoracic bioimpedance and inert gas rebreathing techniques for cardiac output (CO) assessment at rest and exer...

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Published in	Clinical physiology and functional imaging Vol. 45; no. 3; pp. e70005 - n/a
Main Authors	Filaire, Laura, Perrault, Hélène, Dauphin, Claire, Chalard, Aurélie, Pereira, Bruno, Costes, Frederic, Richard, Ruddy
Format	Journal Article
Language	English
Published	England Wiley Subscription Services, Inc 01.05.2025 John Wiley and Sons Inc
Subjects	Adult Aged Bicycling Blood flow Breath Tests - instrumentation Cardiac Output Cardiography, Impedance - instrumentation Correlation coefficients Cycles Electric Impedance Exercise Test Female healthy subjects Healthy Volunteers Heart Humans Male Middle Aged Noble Gases - administration & dosage noninvasive cardiac output Original Predictive Value of Tests pulmonary blood flow Rare gases Rebreathing Reproducibility of Results shunt effect Subgroups systemic blood flow Thorax pulmonary blood flow healthy subjects exercise test systemic blood flow noninvasive cardiac output shunt effect
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ISSN	1475-0961 1475-097X 1475-097X
DOI	10.1111/cpf.70005

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Abstract	Purpose Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies have compared the use of thoracic bioimpedance and inert gas rebreathing techniques for cardiac output (CO) assessment at rest and exercise. This manuscript reports on differences between Physioflow® and Innocor® CO measurements at rest and during cycling in a population of healthy subjects. Methods Fifty healthy subjects (52 ± 16 years) underwent an incremental cycle exercise testing (IET) during which standardized Physioflow® and Innocor® CO assessments were achieved. Measurements were completed in a subgroup of twelve subjects during two constant‐load 10‐min cycling bouts at moderate and high intensities. Results Mean difference between Physioflow® and Innocor® was of 0.002 ± 0.98 l/min at rest and 0.38 ± 1.31 l/min during IET without statistical difference. Correlation coefficient values were higher for exercise (r = 0.83) than resting (r = 0.40) measurements. Good reproducibility of the two devices was observed on different graded exercises with intraindividual variability lower than 6%, except for rest Innocor® CO measurements (CV = 18%). Conclusion Physioflow® and Innocor® can be easily used concomitantly for noninvasive measurement of CO. Despite finding a strong agreement between techniques for exercise CO, results should not be interpreted as being interchangeable as values are derived from different flow measurements: systemic blood flow for Physioflow® and pulmonary blood flow for Innocor®. However, the concomitant use of both techniques could be of value in clinical setting for noninvasive intrathoracic shunt quantification.
AbstractList	Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies have compared the use of thoracic bioimpedance and inert gas rebreathing techniques for cardiac output (CO) assessment at rest and exercise. This manuscript reports on differences between Physioflow® and Innocor® CO measurements at rest and during cycling in a population of healthy subjects. Fifty healthy subjects (52 ± 16 years) underwent an incremental cycle exercise testing (IET) during which standardized Physioflow® and Innocor® CO assessments were achieved. Measurements were completed in a subgroup of twelve subjects during two constant-load 10-min cycling bouts at moderate and high intensities. Mean difference between Physioflow® and Innocor® was of 0.002 ± 0.98 l/min at rest and 0.38 ± 1.31 l/min during IET without statistical difference. Correlation coefficient values were higher for exercise (r = 0.83) than resting (r = 0.40) measurements. Good reproducibility of the two devices was observed on different graded exercises with intraindividual variability lower than 6%, except for rest Innocor® CO measurements (CV = 18%). Physioflow® and Innocor® can be easily used concomitantly for noninvasive measurement of CO. Despite finding a strong agreement between techniques for exercise CO, results should not be interpreted as being interchangeable as values are derived from different flow measurements: systemic blood flow for Physioflow® and pulmonary blood flow for Innocor®. However, the concomitant use of both techniques could be of value in clinical setting for noninvasive intrathoracic shunt quantification. Purpose Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies have compared the use of thoracic bioimpedance and inert gas rebreathing techniques for cardiac output (CO) assessment at rest and exercise. This manuscript reports on differences between Physioflow® and Innocor® CO measurements at rest and during cycling in a population of healthy subjects. Methods Fifty healthy subjects (52 ± 16 years) underwent an incremental cycle exercise testing (IET) during which standardized Physioflow® and Innocor® CO assessments were achieved. Measurements were completed in a subgroup of twelve subjects during two constant‐load 10‐min cycling bouts at moderate and high intensities. Results Mean difference between Physioflow® and Innocor® was of 0.002 ± 0.98 l/min at rest and 0.38 ± 1.31 l/min during IET without statistical difference. Correlation coefficient values were higher for exercise (r = 0.83) than resting (r = 0.40) measurements. Good reproducibility of the two devices was observed on different graded exercises with intraindividual variability lower than 6%, except for rest Innocor® CO measurements (CV = 18%). Conclusion Physioflow® and Innocor® can be easily used concomitantly for noninvasive measurement of CO. Despite finding a strong agreement between techniques for exercise CO, results should not be interpreted as being interchangeable as values are derived from different flow measurements: systemic blood flow for Physioflow® and pulmonary blood flow for Innocor®. However, the concomitant use of both techniques could be of value in clinical setting for noninvasive intrathoracic shunt quantification. Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies have compared the use of thoracic bioimpedance and inert gas rebreathing techniques for cardiac output (CO) assessment at rest and exercise. This manuscript reports on differences between Physioflow® and Innocor® CO measurements at rest and during cycling in a population of healthy subjects.PURPOSEInasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies have compared the use of thoracic bioimpedance and inert gas rebreathing techniques for cardiac output (CO) assessment at rest and exercise. This manuscript reports on differences between Physioflow® and Innocor® CO measurements at rest and during cycling in a population of healthy subjects.Fifty healthy subjects (52 ± 16 years) underwent an incremental cycle exercise testing (IET) during which standardized Physioflow® and Innocor® CO assessments were achieved. Measurements were completed in a subgroup of twelve subjects during two constant-load 10-min cycling bouts at moderate and high intensities.METHODSFifty healthy subjects (52 ± 16 years) underwent an incremental cycle exercise testing (IET) during which standardized Physioflow® and Innocor® CO assessments were achieved. Measurements were completed in a subgroup of twelve subjects during two constant-load 10-min cycling bouts at moderate and high intensities.Mean difference between Physioflow® and Innocor® was of 0.002 ± 0.98 l/min at rest and 0.38 ± 1.31 l/min during IET without statistical difference. Correlation coefficient values were higher for exercise (r = 0.83) than resting (r = 0.40) measurements. Good reproducibility of the two devices was observed on different graded exercises with intraindividual variability lower than 6%, except for rest Innocor® CO measurements (CV = 18%).RESULTSMean difference between Physioflow® and Innocor® was of 0.002 ± 0.98 l/min at rest and 0.38 ± 1.31 l/min during IET without statistical difference. Correlation coefficient values were higher for exercise (r = 0.83) than resting (r = 0.40) measurements. Good reproducibility of the two devices was observed on different graded exercises with intraindividual variability lower than 6%, except for rest Innocor® CO measurements (CV = 18%).Physioflow® and Innocor® can be easily used concomitantly for noninvasive measurement of CO. Despite finding a strong agreement between techniques for exercise CO, results should not be interpreted as being interchangeable as values are derived from different flow measurements: systemic blood flow for Physioflow® and pulmonary blood flow for Innocor®. However, the concomitant use of both techniques could be of value in clinical setting for noninvasive intrathoracic shunt quantification.CONCLUSIONPhysioflow® and Innocor® can be easily used concomitantly for noninvasive measurement of CO. Despite finding a strong agreement between techniques for exercise CO, results should not be interpreted as being interchangeable as values are derived from different flow measurements: systemic blood flow for Physioflow® and pulmonary blood flow for Innocor®. However, the concomitant use of both techniques could be of value in clinical setting for noninvasive intrathoracic shunt quantification. Purpose Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies have compared the use of thoracic bioimpedance and inert gas rebreathing techniques for cardiac output (CO) assessment at rest and exercise. This manuscript reports on differences between Physioflow® and Innocor® CO measurements at rest and during cycling in a population of healthy subjects. Methods Fifty healthy subjects (52 ± 16 years) underwent an incremental cycle exercise testing (IET) during which standardized Physioflow® and Innocor® CO assessments were achieved. Measurements were completed in a subgroup of twelve subjects during two constant‐load 10‐min cycling bouts at moderate and high intensities. Results Mean difference between Physioflow® and Innocor® was of 0.002 ± 0.98 l/min at rest and 0.38 ± 1.31 l/min during IET without statistical difference. Correlation coefficient values were higher for exercise (r = 0.83) than resting (r = 0.40) measurements. Good reproducibility of the two devices was observed on different graded exercises with intraindividual variability lower than 6%, except for rest Innocor® CO measurements (CV = 18%). Conclusion Physioflow® and Innocor® can be easily used concomitantly for noninvasive measurement of CO. Despite finding a strong agreement between techniques for exercise CO, results should not be interpreted as being interchangeable as values are derived from different flow measurements: systemic blood flow for Physioflow® and pulmonary blood flow for Innocor®. However, the concomitant use of both techniques could be of value in clinical setting for noninvasive intrathoracic shunt quantification.
Author	Filaire, Laura Costes, Frederic Pereira, Bruno Richard, Ruddy Dauphin, Claire Chalard, Aurélie Perrault, Hélène
AuthorAffiliation	1 Thoracic and Endocrine Surgery, Centre Jean Perrin Clermont‐Ferrand France 4 Cardiology and Vascular department Hospital Gabriel‐Montpied Clermont‐Ferrand France 7 Department of sports Medicine and Functional explorations Hospital Gabriel‐Montpied Clermont‐Ferrand France 3 Respiratory and Epidemiology Clinical Research Unit Montreal Chest Institute – Mc Gill University Health center Montreal Quebec Canada 5 Biostatistics units (Direction de la Recherche Clinique) Clermont‐Ferrand University Hospital Clermont‐Ferrand France 6 INRA, UMR 1019, UNH, Université d'Auvergne, CRNH Auvergne Clermont‐Ferrand France 2 Faculty of Health Sciences University of Ottawa Ottawa Ontario Canada
AuthorAffiliation_xml	– name: 5 Biostatistics units (Direction de la Recherche Clinique) Clermont‐Ferrand University Hospital Clermont‐Ferrand France – name: 7 Department of sports Medicine and Functional explorations Hospital Gabriel‐Montpied Clermont‐Ferrand France – name: 4 Cardiology and Vascular department Hospital Gabriel‐Montpied Clermont‐Ferrand France – name: 6 INRA, UMR 1019, UNH, Université d'Auvergne, CRNH Auvergne Clermont‐Ferrand France – name: 1 Thoracic and Endocrine Surgery, Centre Jean Perrin Clermont‐Ferrand France – name: 2 Faculty of Health Sciences University of Ottawa Ottawa Ontario Canada – name: 3 Respiratory and Epidemiology Clinical Research Unit Montreal Chest Institute – Mc Gill University Health center Montreal Quebec Canada
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Cites_doi	10.1007/s004210000226 10.1111/cpf.12442 10.1097/ALN.0b013e3181ee3130 10.1007/s004210100458 10.1136/bmjopen-2018-024389 10.1016/j.jacc.2005.08.005 10.1053/j.jvca.2003.10.010 10.1007/s10877-011-9310-4 10.1111/j.1475-097X.2005.00602.x 10.1055/s-0029-1225340 10.1164/arrd.1984.129.2P2.S49 10.3109/15412555.2015.1043985 10.1007/s00421-009-1252-x 10.1152/jappl.1986.60.6.2020 10.1007/BF00422887 10.1152/japplphysiol.01106.2006 10.3109/00365513.2011.563790
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Snippet	Purpose Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few... Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few studies... Purpose Inasmuch as they are deemed valid, noninvasive measurement of cardiac output techniques present advantages of ease and safety for use in humans. Few...
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SubjectTerms	Adult Aged Bicycling Blood flow Breath Tests - instrumentation Cardiac Output Cardiography, Impedance - instrumentation Correlation coefficients Cycles Electric Impedance Exercise Test Female healthy subjects Healthy Volunteers Heart Humans Male Middle Aged Noble Gases - administration & dosage noninvasive cardiac output Original Predictive Value of Tests pulmonary blood flow Rare gases Rebreathing Reproducibility of Results shunt effect Subgroups systemic blood flow Thorax
Title	Agreement of concomitant cardiac output measurement by thoracic bio‐impedance and inert gas rebreathing in healthy subjects
URI	https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fcpf.70005 https://www.ncbi.nlm.nih.gov/pubmed/40152027 https://www.proquest.com/docview/3228939244 https://www.proquest.com/docview/3182484418 https://pubmed.ncbi.nlm.nih.gov/PMC12068889
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