Performance of breathing filters under wet conditions: a laboratory evaluation

doi:10.1093/bja/aei091

BJA Advance Access originally published online on February 25, 2005
British Journal of Anaesthesia 2005 94(5):675-682; doi:10.1093/bja/aei091

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Performance of breathing filters under wet conditions: a laboratory evaluation

D. Turnbull¹^,*, P. C. Fisher², G. H. Mills¹ and N. J. Morgan-Hughes³

¹ University of Sheffield, Academic Anaesthetic Unit, Sheffield, South Yorkshire, UK. ² Royal Hallamshire Hospital, Anaesthetic Department, Sheffield, South Yorkshire, UK. ³ Northern General Hospital, Anaesthetic Department, Sheffield, South Yorkshire, UK

^* Corresponding author. E-mail: cahillturnbull{at}doctors.org.uk

Introduction. Heat and moisture exchangers in combination witha bacterial and viral filter (HMEF) are widely used during generalanaesthesia. Excess patient secretions occluding the HMEF havebeen responsible for previous case reports of airway obstruction.A previous study suggested that differences in HMEF design mightcontribute to filter obstruction under wet conditions.

Methods. We tested 14 types of HMEF under wet conditions toestablish which design features contributed to HMEF obstruction.Incremental amounts of saline were added to each filter. Thepressure across the filter was measured with an air flow of60 litre min^–1.

Results. We observed that saline added to the filter was oftennot easily visible to the casual observer. This concealmentvolume varied between filters. Ceramic hydrophobic pleated-membranefilters did not absorb saline and their resistance did not change.The composite filter where the moisture exchange component waseither polyurethane foam or cellulose absorbed saline and contributedto a rise in resistance of 70–480% with the higher valuemore typical of the cellulose-paper-based HMEF.

Conclusion. The ideal HMEF for use during general anaesthesiashould prevent the passage of viral, bacterial and prion material,should provide this filtration performance even under wet conditions,should supplement humidification of the inspired air and anaestheticgases and should not increase respiratory work. We have identifiedlarge variations in HMEF performance under wet conditions. Usersshould be aware of performance variation in HMEFs and use afilter suited to the intended application.

Presented in part to the European Society of Anaesthesia, Glasgow,May 2003.

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