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Journal of Clinical Monitoring and Computing

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Open Access 01-04-2018 | Original Research

Performance of a capnodynamic method estimating effective pulmonary blood flow during transient and sustained hypercapnia

Authors: Thorir Svavar Sigmundsson, Tomas Öhman, Magnus Hallbäck, Eider Redondo, Fernando Suarez Sipmann, Mats Wallin, Anders Oldner, Caroline Hällsjö Sander, Håkan Björne

Published in: Journal of Clinical Monitoring and Computing | Issue 2/2018

Abstract

The capnodynamic method is a minimally invasive method continuously calculating effective pulmonary blood flow (CO_EPBF), equivalent to cardiac output when intra pulmonary shunt flow is low. The capnodynamic equation joined with a ventilator pattern containing cyclic reoccurring expiratory holds, provides breath to breath hemodynamic monitoring in the anesthetized patient. Its performance however, might be affected by changes in the mixed venous content of carbon dioxide (C_vCO₂). The aim of the current study was to evaluate CO_EPBF during rapid measurable changes in mixed venous carbon dioxide partial pressure (P_vCO₂) following ischemia–reperfusion and during sustained hypercapnia in a porcine model. Sixteen pigs were submitted to either ischemia–reperfusion (n = 8) after the release of an aortic balloon inflated during 30 min or to prolonged hypercapnia (n = 8) induced by adding an instrumental dead space. Reference cardiac output (CO) was measured by an ultrasonic flow probe placed around the pulmonary artery trunk (CO_TS). Hemodynamic measurements were obtained at baseline, end of ischemia and during the first 5 min of reperfusion as well as during prolonged hypercapnia at high and low CO states. Ischemia–reperfusion resulted in large changes in P_vCO₂, hemodynamics and lactate. Bias (limits of agreement) was 0.7 (−0.4 to 1.8) L/min with a mean error of 28% at baseline. CO_EPBF was impaired during reperfusion but agreement was restored within 5 min. During prolonged hypercapnia, agreement remained good during changes in CO. The mean polar angle was −4.19° (−8.8° to 0.42°). Capnodynamic CO_EPBF is affected but recovers rapidly after transient large changes in P_vCO₂ and preserves good agreement and trending ability during states of prolonged hypercapnia at different levels of CO.

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Title: Performance of a capnodynamic method estimating effective pulmonary blood flow during transient and sustained hypercapnia
Authors: Thorir Svavar Sigmundsson
Tomas Öhman
Magnus Hallbäck
Eider Redondo
Fernando Suarez Sipmann
Mats Wallin
Anders Oldner
Caroline Hällsjö Sander
Håkan Björne
Publication date: 01-04-2018
Publisher: Springer Netherlands
Published in: Journal of Clinical Monitoring and Computing / Issue 2/2018
Print ISSN: 1387-1307
Electronic ISSN: 1573-2614
DOI: https://doi.org/10.1007/s10877-017-0021-3

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Performance of a capnodynamic method estimating effective pulmonary blood flow during transient and sustained hypercapnia

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