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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 (F_IO₂) in 4–6 steps in order to obtain arterial oxygen saturations (S_aO₂) in the range from 90–100%. This procedure allows plotting a F_IO₂/S_aO₂ or F_EO₂/S_aO₂ 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 F_IO₂ 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; shunt^invasive vs shunt^non-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.

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Wandrup JH (1995) Quantifying pulmonary oxygen transfer deficits in critically ill patients. Acta Anaesthesiol Scand 39:37–44CrossRef

Andreassen S, Rees SE, Kjaergaard S, Thorgaard P, Winter SM, Morgan CJ, Alstrup P, Toft E (1999) Hypoxemia after coronary bypass surgery modeled by resistance to oxygen diffusion. Crit Care Med 27:2445–2453CrossRef

Petros AJ, Doré CJ, Nunn JF (1994) Modification of iso-shunt lines for low inspired oxygen fractions. Br J Anaesth 72:5–15CrossRef

Riley RL, Cournand A (1951) Analysis of factors affecting partial pressure of oxygen and carbon dioxide in gas and blood of the lungs: theory. J Appl Physiol 4:77–101CrossRef

Riley RL, Cournand A (1951) Analysis of factors affecting partial pressure of oxygen and carbon dioxide in gas and blood of the lungs: method. J Appl Physiol 4:102–120CrossRef

Sapsford DJ, Jones JG (1995) The PIO2 vs SpO2 diagram: a non-invasive measure of pulmonary oxygen exchange. Eur J Anaesthesiol 12:375–386PubMed

de Gray L, Rush EM, Jones JG (1997) A noninvasive method for evaluating the effect of thoracotomy on shunt and ventilation perfusion inequality. Anaesthesia 52:630–635CrossRef

Kjaergaard S, Rees SE, Nielsen JA, Freundlich M, Thorgaard P, Andreassen S (2001) Modelling of hypoxaemia after gynecological laparotomy. Acta Anaesthesiol Scand 45:349–356CrossRef

Roe PG, Gadelrab R, Sapsford D, Jones JG (1997) Intra-operative gas exchange and post-operative hypoxaemia. Eur J Anaesthesiol 14:203–210CrossRef

10.

Rees SE, Kjaergaard S, Thorgaard P, Malczynski J, Toft E, Andreassen S (2002) The Automatic Lung Parameter Estimator (ALPE) system: non-invasive estimation of pulmonary gas exchange parameters in 10–15 min. J Clin Monit 17:43–52CrossRef

11.

Malczynski J, Korup E, Rees SE, Andreassen S, Thorgaard P, Toft E (1999) The lung alveolar- lung capillary oxygen pressure drop as a new measure of lung problems in left sided heart failure—a new approach to estimate cardial decompensation. Proc Nordic Congress in Cardiology, Reykjavik

12.

Nunn JF (1993) Nunn's applied respiratory physiology. Butterworth-Heinemann, Oxford, UK

13.

Lentner C (1990) Geigy scientific tables, vol. 5. Heart and circulation. CIBA-GEIGY, Basel, Switzerland

14.

Benumof JL (1990) Respiratory physiology and respiratory function during anesthesia. In: Miller RD (ed) Anesthesia. Churchill Livingstone, New York, USA, p 523

15.

King TKC, Weber B, Okinaka A, Friedman SA, Smith JP, Briscoe WA (1974) Oxygen transfer in catastrophic respiratory failure. Chest 65:40S-44SCrossRef

16.

Wagner PD, Saltzman HA, West JB (1974) Measurement of continuous distributions of ventilation-perfusion ratios: theory. J Appl Physiol 36:588–599CrossRef

17.

Møller JT, Wittrup M, Johansen SH (1990) Hypoxemia in the post anesthesia care unit—an observer study. Anesthesiology 73:890–895CrossRef

18.

Catley DM, Thornton C, Jordan C, Lehane JR, Royston D (1985) Pronounced, episodic oxygen desaturation in the postoperative period: its association with ventilatory pattern and analgesic regime. Anesthesiology 63:20–28CrossRef

19.

Rosenberg J, Ullstad T, Rasmussen J, Hjorne FP, Poulsen NJ, Goldman MD (1994) Time course of postoperative hypoxaemia. Eur J Surg 160:137–143PubMed

20.

Jones JG, Sapsford DJ, Wheatley RG (1990) Postoperative hypoxaemia: mechanisms and time course. Anaesthesia 45:566–573CrossRef

Titel: 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
Publikationsdatum: 01.05.2003
Verlag: Springer Berlin Heidelberg
Erschienen in: Intensive Care Medicine / Ausgabe 5/2003
Print ISSN: 0342-4642
Elektronische ISSN: 1432-1238
DOI: https://doi.org/10.1007/s00134-003-1708-0

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Non-invasive estimation of shunt and ventilation-perfusion mismatch