Erschienen in:
01.05.2003 | Original
Non-invasive estimation of shunt and ventilation-perfusion mismatch
verfasst von:
Søren Kjaergaard, Stephen Rees, Jerzy Malczynski, Jørgen Ahrenkiel Nielsen, Per Thorgaard, Egon Toft, Steen Andreassen
Erschienen in:
Intensive Care Medicine
|
Ausgabe 5/2003
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Abstract
Objective
To investigate whether parameters describing pulmonary gas exchange (shunt and ventilation-perfusion mismatch) can be estimated consistently by the use of non-invasive data as input to a mathematical model of oxygen transport.
Design
Prospective study.
Setting
Investigations were carried out in the post-anaesthesia care unit, coronary care unit, and intensive care unit.
Patients
Data from ninety-five patients and six normal subjects were included for the comparison. The clinical situations differed, ranging from healthy subjects to patients with acute respiratory failure in the intensive care unit.
Measurements
The experimental procedure involved changing the inspired oxygen fraction (FIO2) in 4–6 steps in order to obtain arterial oxygen saturations (SaO2) in the range from 90–100%. This procedure allows plotting a FIO2/SaO2 or FEO2/SaO2 curve, the shape and position of which was quantified using the mathematical model estimating pulmonary shunt and a measure of ventilation-perfusion mismatch (ΔPO2). This procedure was performed using either arterial blood samples at each FIO2 level (invasive approach) or using values from the pulse oximeter (non-invasive approach).
Main results
The model provided good fit to data using both the invasive and non-invasive experimental approach. The parameter estimates were linearly correlated with highly significant correlation coefficients; shuntinvasive vs shuntnon-invasive, r
2 = 0.74, P <0.01, and ΔPO2
invasive vs ΔPO2
non-invasive, r
2 = 0.97, P <0.001.
Conclusions
Pulmonary gas exchange can be described equally well using non-invasive data. The simplicity of the non-invasive approach makes the method suitable for large-scale clinical use.