Distribution characteristics and analysis of fungal aerosol concentration and particle size in air-conditioned wards in Wuhan, China

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RESEARCH PAPER

Distribution characteristics and analysis of fungal aerosol concentration and particle size in air-conditioned wards in Wuhan, China

Zhe Song ¹

,

Lijuan Deng ²

,

Xinyu Liu ³

,

Hongfu Zhou ³

,

Xinyi Wu ³

,

Yutong Han ¹

,

Wan Liu ¹

,

Xuelian Wu ¹

,

Chenxi Wang ¹

,

Xuefei He ¹

,

Siyuan Yu ¹

,

Dingyu Lu ¹

,

Huamin Li ²

,

Huihong Gong ¹

1

School of Biomedical Engineering and Imaging, Hubei University of Science and Technology, Hubei, China

2

Xianning Central Blood Station, China

3

School of Stomatology and Ophthalmology, Hubei University of Science and Technology, Hubei, China

These authors had equal contribution to this work

Corresponding author

Huihong Gong

School of Biomedical Engineering and Imaging, Hubei University of Science and Technology, Hubei, China

DOI: https://doi.org/10.26444/aaem/193292

References (25)

KEYWORDS

dominant genera

distribution characteristics

TOPICS

Biological agents posing occupational risk in agriculture, forestry, food industry and wood industry and diseases caused by these agents (zoonoses, allergic and immunotoxic diseases)

ABSTRACT

Fungal contamination in the air of hospital wards can affect the health of medical staff, patients, and caregivers. Through systematic analysis of the concentration, types, and particle size distribution characteristics of fungi in the air of wards in Wuhan, China, in 2023, it was found that there was no significant correlation between the concentration of fungi in the air of wards and the disease type and personnel density. The main influencing factors were temperature, humidity, and seasonal changes. The distribution characteristics of fungal particle size in the wards of various departments in winter and summer showed a roughly normal distribution, with the percentage of particle size gradually increasing from stage I to stage III. The proportion from stage III to stage V was generally the highest, while the proportion from stage V to stage VI gradually decreased. There was no significant difference in the median diameter of airborne fungal conidia between different departments in winter and summer, and the median diameter of fungal conidia was less than 3.19 μm. The dominant fungal genus in the wards during winter and summer were basically the same, and there was no significant difference compared to wards in other inpatient buildings. The current study indicates that more attentions should be paid to the increasing of filtration efficiency of fungal conidia particle sized from 1.1~4.7 μm, and appropriate antifungal and sterilization drugs, equipments and methods should be selected in the maintenance of daily hygiene, including the operation and management of the air conditioning systems in the inpatient wards.

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