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Intensive Care Medicine

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01-12-2003 | Experimental

Fluorocarbons facilitate lung recruitment

Authors: Peter N. Cox, Helena Frndova, Ove Karlsson, Stephanie Holowka, Charles A. Bryan

Published in: Intensive Care Medicine | Issue 12/2003

Abstract

Objective

"Open the lung and keep it open" is increasingly accepted as a fundamental principle for mechanical ventilation. However, it is sometimes very difficult, or impossible, to recruit the diseased lung. We questioned whether one could facilitate recruitment by using a low dose of fluorocarbon in a model previously shown to be non-recruitable by conventional sustained inflation maneuvers.

Design and setting

Experimental prospective study in a university laboratory.

Animals and interventions

Nine saline-lavaged rabbits subjected to prolonged large tidal volume mechanical ventilation to establish significant lung injury were randomly allocated to two groups: control [High Frequency Oscillation (HFO) alone: n=4] or 1 ml/kg fluorocarbon (FC) treated (HFO/FC: n=5) for 2+1 h (experiment 1). An additional four similarly prepared animals were treated by single-lung instillation of 0.5 ml/kg dose of fluorocarbon and underwent serial computerized tomography scans at a series of predetermined step-wise pressure increase in both lungs (experiment 2).

Measurements and results

In experiment 1 there was a very significant improvement in oxygenation in HFO/FC group (PaO₂ increased from 108 mmHg to 424±81 mmHg; P<0.05) while there was no significant change in the control group. In experiment 2 lung volumes were determined using three-dimensional reconstruction. The lung having fluorocarbon showed a 2.4-fold increase in lung volume at inflation pressure of 15 cmH₂O compared to the lung without fluorocarbon.

Conclusions

We propose that the low equilibrium surface tension and positive spreading coefficient of fluorocarbon facilitates lung recruitment by ungluing adherent surfaces in this model of lung injury.

Available only for authorised users

Suzuki H, Papazoglou K, Bryan AC (1992) Relationship between PaO₂ and lung volume during high frequency oscillatory ventilation. Acta Paediatr Jpn 34:494–500CrossRef

McCulloch PR, Forkert PG, Froese AB (1988) Lung volume maintenance prevents lung injury during high frequency oscillatory ventilation in surfactant-deficient rabbits. Am Rev Respir Dis 137:1185–1192CrossRef

Hamilton PP, Onayemi A, Smyth JA, Gillan JE, Cutz E, Froese AB, Bryan AC (1983) Comparison of conventional and high-frequency ventilation: oxygenation and lung pathology. J Appl Physiol 55:131–138CrossRef

Curtis SE, Peek JT, Kelly DR (1993) Partial liquid breathing with perflubron improves arterial oxygenation in acute canine lung injury. J Appl Physiol 75:2696–2702CrossRef

Hirschl RB, Parent A, Tooley R, McCracken M, Johnston K, Schaffer TH, Wolfson MR, Bartlett RH (1995) Liquid ventilation improves pulmonary function, gas exchange, and lung injury in a model of respiratory failure. Ann Surg 221:79–88CrossRef

Tütüncü AS, Faithfull NS, Lachmann B (1993) Comparison of ventilatory support with intratracheal perfluorocarbon administration and conventional mechanical ventilation in animals with acute respiratory failure. Am Rev Respir Dis 148:785–792CrossRef

Fuhrman BP, Paczan PR, DeFrancisis M (1991) Perfluorocarbon-associated gas exchange. Crit Care Med 19:712–722CrossRef

Cox PN, Frndova H, Tan P, Nakamura T, Middleton W, Maser D, Bryan AC (1997) Concealed air leak associated with large tidal volumes in partial liquid ventilation. Am J Respir Crit Care Med 156:992–997CrossRef

Baden HP, Mellema JD, Bratton SL, O'Rourke PP, Jackson JC (1997) High-frequency oscillatory ventilation with partial liquid ventilation in a model of acute respiratory failure. Crit Care Med 25:299–302CrossRef

10.

Sanderson RJ, Paul GW, Vatter AE, Filley GF (1976) Morphological and physical basis for lung surfactant action. Respir Physiol 27:379–392CrossRef

11.

Patel MM, Patel MK, Szanto P, Alrenga DP, Long DM (1971) Ventilation with synthetic fluids. Surg Clin North Am 51:25–36CrossRef

12.

Lachmann B, Robertson B, Vogel J (1980) In vivo lung lavage as an experimental model of the respiratory distress syndrome. Acta Anaesthesiol Scand 24:231–236CrossRef

13.

Hubler M, Souders JE, Shade ED, Polissar NL, Bleyl JU, Hlastala MP (2002) Effects of perfluorohexane vapor on relative blood flow distribution in an animal model of surfactant-depleted lung injury. Crit Care Med 30:422–427CrossRef

14.

Morris KP, Cox PN, Mazer CD, Frndova H, McKerlie C, Wolfe R (2000) Distribution of pulmonary blood flow in the perfluorocarbon-filled lung. Intensive Care Med 26:756–763CrossRef

15.

Schurch S (1982) Surface tension at low lung volumes: dependence on time and alveolar size. Respir Physiol 48:339–355CrossRef

16.

Clements JA, Hustead RF, Johnson RP, Gribetz I (1961) Pulmonary surface tension and alveolar stability. J Appl Physiol 16:444–450CrossRef

17.

Mead J, Takishima T, Leith D (1970) Stress distribution in lungs: a model of pulmonary elasticity. J Appl Physiol 28:596–608CrossRef

18.

Bachofen H, Schurch S (2001) Alveolar surface forces and lung architecture. Comp Biochem Physiol A Mol Integr Physiol 129:183–193CrossRef

19.

Gil J, Bachofen H, Gehr P, Weibel ER (1979) Alveolar volume-surface area relation in air- and saline-filled lungs fixed by vascular perfusion. J Appl Physiol 47:990–1001CrossRef

20.

Gil J, Weibel ER (1972) Morphological study of pressure-volume hysteresis in rat lungs fixed by vascular perfusion. Respir Physiol 15:190–213CrossRef

21.

Weibel ER, Bachofen H (1987) How to stabilize the pulmonary alveoli: surfactant or fibers. NIPS 2:72–75

22.

Gladstone IM, Ray AO, Salafia CM, Perez-Fontan J, Mercurio MR, Jacobs HC (1990) Effect of artificial surfactant on pulmonary function in preterm and full-term lambs. J Appl Physiol 69:465–472CrossRef

23.

Mercurio MR, Fiascone JM, Lima DM, Jacobs HC (1989) Surface tension and pulmonary compliance in premature rabbits. J Appl Physiol 66:2039–2044CrossRef

24.

Daniels CB, Orgeig S (2001) The comparative biology of pulmonary surfactant: past, present and future. Comp Biochem Physiol A Mol Integr Physiol 129:9–36CrossRef

25.

Rimensberger PC, Cox PN, Frndova H, Bryan AC (1999) The open lung during small tidal volume ventilation: concepts of recruitment and "optimal" positive end-expiratory pressure. Crit Care Med 27:1946–1952CrossRef

26.

Rimensberger PC, Pache JC, McKerlie C, Frndova H, Cox PN (2000) Lung recruitment and lung volume maintenance: a strategy for improving oxygenation and preventing lung injury during both conventional mechanical ventilation and high-frequency oscillation [in process citation]. Intensive Care Med 26:745–755CrossRef

Title: Fluorocarbons facilitate lung recruitment
Authors: Peter N. Cox
Helena Frndova
Ove Karlsson
Stephanie Holowka
Charles A. Bryan
Publication date: 01-12-2003
Publisher: Springer Berlin Heidelberg
Published in: Intensive Care Medicine / Issue 12/2003
Print ISSN: 0342-4642
Electronic ISSN: 1432-1238
DOI: https://doi.org/10.1007/s00134-003-1881-1

At a glance: The STEP trials

Springer Medicine

Fluorocarbons facilitate lung recruitment

Abstract

Objective

Design and setting

Animals and interventions

Measurements and results

Conclusions

At a glance: The STEP trials

Springer Medicine

Abstract

Objective

Design and setting

Animals and interventions

Measurements and results

Conclusions

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