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Intensive Care Medicine
Published in: Intensive Care Medicine 8/2005

01-08-2005 | Pediatric Original

Effect of the Y-piece of the ventilation circuit on ventilation requirements in extremely low birth weight infants

Authors: M. Wald, Valerie Jeitler, Karin Lawrenz, M. Weninger, Lieselotte Kirchner

Published in: Intensive Care Medicine | Issue 8/2005

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Abstract

Objective

Volutrauma caused by high tidal volumes contributes considerably to the development of bronchopulmonary dysplasia. Yet high tidal volumes are required to overcome dead space. In an experimental arrangement we tested whether reduction of dead space might reduce ventilation requirements and thus reduce volutrauma in preterm infants.

Materials and methods

The time required to eliminate CO2 by standardized mechanical ventilation from a preterm infant’s test lung flooded with CO2 was measured. Four different Y-pieces and flow sensor combinations were tested with and without a device for closed suction: Y-piece without flow sensor; integrated flow sensor; small dead-space flow sensor; and a new dead-space free-flow sensor for preterm infants. CO2 concentrations were measured by a capnograph. Mean CO2 elimination times (±SD) were compared.

Results

Mean CO2 elimination time was 37.5 s (±1.18 s) with and 37.4 s (±0.97 s) without closed suction device for the Y-piece without flow sensor, 47.7 s (±0.82 s) and 45.5 s (±1.18 s) for the integrated flow sensor, 42.5 s (±1.27 s) and 41.1 s (±0.99 s) for the small dead-space flow sensor and 38.3 s (±1.16 s) and 36.8 s (±0.79 s) for the dead-space free-flow sensor.

Conclusion

CO2 elimination time with and without closed suction device was nearly identical for the Y-piece without flow sensor and for the dead-space free-flow sensor. With both systems, ventilation requirements were significantly lower than for the integrated flow sensor and for the small dead-space flow sensor (integrated flow sensor vs dead-space free-flow sensor 23.6 and 24.5%, respectively, small dead-space flow sensor vs dead-space free flow sensor 11.7 and 10.9%, respectively); thus, we think that introduction of the innovative dead-space free-flow sensor into clinical practice might reduce incidence and severity of bronchopulmonary dysplasia by reduction of volutrauma.
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Metadata
Title
Effect of the Y-piece of the ventilation circuit on ventilation requirements in extremely low birth weight infants
Authors
M. Wald
Valerie Jeitler
Karin Lawrenz
M. Weninger
Lieselotte Kirchner
Publication date
01-08-2005
Publisher
Springer-Verlag
Published in
Intensive Care Medicine / Issue 8/2005
Print ISSN: 0342-4642
Electronic ISSN: 1432-1238
DOI
https://doi.org/10.1007/s00134-005-2711-4

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