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Journal of Clinical Monitoring and Computing

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01-12-2016 | Original Research

Capnodynamic assessment of effective lung volume during cardiac output manipulations in a porcine model

Authors: Caroline Hällsjö Sander, Per-Arne Lönnqvist, Magnus Hallbäck, Fernando Suarez Sipmann, Mats Wallin, Anders Oldner, Håkan Björne

Published in: Journal of Clinical Monitoring and Computing | Issue 6/2016

Abstract

A capnodynamic calculation of effective pulmonary blood flow includes a lung volume factor (ELV) that has to be estimated to solve the mathematical equation. In previous studies ELV correlated to reference methods for functional residual capacity (FRC). The aim was to evaluate the stability of ELV during significant manipulations of cardiac output (CO) and assess the agreement for absolute values and trending capacity during PEEP changes at different lung conditions. Ten pigs were included. Alterations of alveolar carbon dioxide were induced by cyclic reoccurring inspiratory holds. The Sulphur hexafluoride technique for FRC measurements was used as reference. Cardiac output was altered by preload reduction and inotropic stimulation at PEEP 5 and 12 cmH₂O both in normal lung conditions and after repeated lung lavages. ELV at baseline PEEP 5 was [mean (SD)], 810 (163) mL and decreased to 400 (42) mL after lavage. ELV was not significantly affected by CO alterations within the same PEEP level. In relation to FRC the overall bias (limits of agreement) was −35 (−271 to 201) mL, and percentage error 36 %. A small difference between ELV and FRC was seen at PEEP 5 cmH₂O before lavage and at PEEP 12 cmH₂O after lavage. ELV trending capability between PEEP steps, showed a concordance rate of 100 %. ELV was closely related to FRC and remained stable during significant changes in CO. The trending capability was excellent both before and after surfactant depletion.

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Title: Capnodynamic assessment of effective lung volume during cardiac output manipulations in a porcine model
Authors: Caroline Hällsjö Sander
Per-Arne Lönnqvist
Magnus Hallbäck
Fernando Suarez Sipmann
Mats Wallin
Anders Oldner
Håkan Björne
Publication date: 01-12-2016
Publisher: Springer Netherlands
Published in: Journal of Clinical Monitoring and Computing / Issue 6/2016
Print ISSN: 1387-1307
Electronic ISSN: 1573-2614
DOI: https://doi.org/10.1007/s10877-015-9767-7

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Capnodynamic assessment of effective lung volume during cardiac output manipulations in a porcine model

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