Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital

The main purpose was to validate the use of outdoor-indoor volumetric impaction sampler with Hirst-type spore traps (HTSTs) to continuously monitor fungal load in order to prevent invasive fungal infections during major structural work in hospital settings. For 4 weeks, outdoor fungal loads were qua...

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Autores principales: Dananché, Cédric, Gustin, Marie-Paule, Cassier, Pierre, Loeffert, Sophie Tiphaine, Thibaudon, Michel, Bénet, Thomas, Vanhems, Philippe
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2017
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5423681/
https://www.ncbi.nlm.nih.gov/pubmed/28486534
http://dx.doi.org/10.1371/journal.pone.0177263
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author Dananché, Cédric
Gustin, Marie-Paule
Cassier, Pierre
Loeffert, Sophie Tiphaine
Thibaudon, Michel
Bénet, Thomas
Vanhems, Philippe
author_facet Dananché, Cédric
Gustin, Marie-Paule
Cassier, Pierre
Loeffert, Sophie Tiphaine
Thibaudon, Michel
Bénet, Thomas
Vanhems, Philippe
author_sort Dananché, Cédric
collection PubMed
description The main purpose was to validate the use of outdoor-indoor volumetric impaction sampler with Hirst-type spore traps (HTSTs) to continuously monitor fungal load in order to prevent invasive fungal infections during major structural work in hospital settings. For 4 weeks, outdoor fungal loads were quantified continuously by 3 HTSTs. Indoor air was sampled by both HTST and viable impaction sampler. Results were expressed as particles/m(3) (HTST) or colony-forming units (CFU)/m(3) (biocollector). Paired comparisons by day were made with Wilcoxon’s paired signed-rank test or paired Student’s t-test as appropriate. Paired airborne spore levels were correlated 2 by 2, after log-transformation with Pearson’s cross-correlation. Concordance was calculated with kappa coefficient (κ). Median total fungal loads (TFLs) sampled by the 3 outdoor HTSTs were 3,025.0, 3,287.5 and 3,625.0 particles/m(3) (P = 0.6, 0.6 and 0.3).—Concordance between Aspergillaceae fungal loads (AFLs, including Aspergillus spp. + Penicillium spp.) was low (κ = 0.2). A low positive correlation was found between TFLs sampled with outdoor HTST and indoor HTST with applying a 4-hour time lag, r = 0.30, 95% CI (0.23–0.43), P<0.001. In indoor air, Aspergillus spp. were detected by the viable impaction sampler on 63.1% of the samples, whereas AFLs were found by HTST-I on only 3.6% of the samples. Concordance between Aspergillus spp. loads and AFLs sampled with the 2 methods was very low (κ = 0.1). This study showed a 4-hour time lag between increase of outdoor and indoor TFLs, possibly due to insulation and aeraulic flow of the building. Outdoor HTSTs may permit to quickly identify (after 48 hours) time periods with high outdoor fungal loads. An identified drawback is that a too low sample area read did not seem to enable detection of Aspergillaceae spores efficiently. Indoor HTSTs may not be recommended at this time, and outdoor HTSTs need further study. Air sampling by viable impaction sampler remains the reference tool for quantifying fungal contamination of indoor air in hospitals.
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spelling pubmed-54236812017-05-15 Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital Dananché, Cédric Gustin, Marie-Paule Cassier, Pierre Loeffert, Sophie Tiphaine Thibaudon, Michel Bénet, Thomas Vanhems, Philippe PLoS One Research Article The main purpose was to validate the use of outdoor-indoor volumetric impaction sampler with Hirst-type spore traps (HTSTs) to continuously monitor fungal load in order to prevent invasive fungal infections during major structural work in hospital settings. For 4 weeks, outdoor fungal loads were quantified continuously by 3 HTSTs. Indoor air was sampled by both HTST and viable impaction sampler. Results were expressed as particles/m(3) (HTST) or colony-forming units (CFU)/m(3) (biocollector). Paired comparisons by day were made with Wilcoxon’s paired signed-rank test or paired Student’s t-test as appropriate. Paired airborne spore levels were correlated 2 by 2, after log-transformation with Pearson’s cross-correlation. Concordance was calculated with kappa coefficient (κ). Median total fungal loads (TFLs) sampled by the 3 outdoor HTSTs were 3,025.0, 3,287.5 and 3,625.0 particles/m(3) (P = 0.6, 0.6 and 0.3).—Concordance between Aspergillaceae fungal loads (AFLs, including Aspergillus spp. + Penicillium spp.) was low (κ = 0.2). A low positive correlation was found between TFLs sampled with outdoor HTST and indoor HTST with applying a 4-hour time lag, r = 0.30, 95% CI (0.23–0.43), P<0.001. In indoor air, Aspergillus spp. were detected by the viable impaction sampler on 63.1% of the samples, whereas AFLs were found by HTST-I on only 3.6% of the samples. Concordance between Aspergillus spp. loads and AFLs sampled with the 2 methods was very low (κ = 0.1). This study showed a 4-hour time lag between increase of outdoor and indoor TFLs, possibly due to insulation and aeraulic flow of the building. Outdoor HTSTs may permit to quickly identify (after 48 hours) time periods with high outdoor fungal loads. An identified drawback is that a too low sample area read did not seem to enable detection of Aspergillaceae spores efficiently. Indoor HTSTs may not be recommended at this time, and outdoor HTSTs need further study. Air sampling by viable impaction sampler remains the reference tool for quantifying fungal contamination of indoor air in hospitals. Public Library of Science 2017-05-09 /pmc/articles/PMC5423681/ /pubmed/28486534 http://dx.doi.org/10.1371/journal.pone.0177263 Text en © 2017 Dananché et al http://creativecommons.org/licenses/by/4.0/ This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Dananché, Cédric
Gustin, Marie-Paule
Cassier, Pierre
Loeffert, Sophie Tiphaine
Thibaudon, Michel
Bénet, Thomas
Vanhems, Philippe
Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital
title Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital
title_full Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital
title_fullStr Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital
title_full_unstemmed Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital
title_short Evaluation of hirst-type spore trap to monitor environmental fungal load in hospital
title_sort evaluation of hirst-type spore trap to monitor environmental fungal load in hospital
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5423681/
https://www.ncbi.nlm.nih.gov/pubmed/28486534
http://dx.doi.org/10.1371/journal.pone.0177263
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