Your search keyword '"Bioaerosol"' showing total 6 results

1. A super sandstorm altered the abundance and composition of airborne bacteria in Beijing.

Author

Xia, Fanxuan, Chen, Zhuo, Tian, Enze, and Mo, Jinhan

Subjects

*SANDSTORMS, *BUILT environment, *MICROBIOLOGICAL aerosols, *PARTICULATE matter, *POLYMERASE chain reaction, *AIR sampling, *ENVIRONMENTAL quality, *NUCLEOTIDE sequencing

Abstract

• In Beijing's super sandstorm 2021, 5700 amplicon sequence variants were detected. • Airborne bacteria in sandstorms were compared with the after-storm and haze days. • The sandstorm newly brought 10 pathogenic bacterial genera to the atmosphere. • Small bioaerosols (0.65–1.1 µm) were still suspended after the sandstorm subsided. Sandstorm, which injects generous newly emerging microbes into the atmosphere covering cities, adversely affects the air quality in built environments. However, few studies have examined the change of airborne bacteria during severe sandstorm events. In this work, we analyzed the airborne bacteria during one of the strongest sandstorms in East Asia on March 15th, 2021, which affected large areas of China and Mongolia. The characteristics of the sandstorm were compared with those of the subsequent clean and haze days. The composition of the bacterial community of air samples was investigated using quantitative polymerase chain reaction (qPCR) and high-throughput sequencing technology. During the sandstorm, the particulate matter (PM) concentration and bacterial richness were extremely high (PM 2.5 : 207 µg/m3; PM 10 : 1630 µg/m3; 5700 amplicon sequence variants/m3). In addition, the sandstorm brought 10 pathogenic bacterial genera to the atmosphere, posing a grave hazard to human health. As the sandstorm subsided, small bioaerosols (0.65–1.1 µm) with a similar bacterial community remained suspended in the atmosphere, bringing possible long-lasting health risks. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

2. Characteristics of biological particulate matters at urban and rural sites in the North China Plain.

Author

Shen, Fangxia, Zheng, Yunhao, Niu, Mutong, Zhou, Feng, Wu, Yan, Wang, Junxia, Zhu, Tong, Wu, Yusheng, Wu, Zhijun, Hu, Min, and Zhu, Tianle

Subjects

ENDOTOXINS, PARTICULATE matter, CITY dwellers, AIR pollution, BACTERIAL communities, CITIES & towns

Abstract

Depending on their concentrations, sizes, and types, particulate matters of biological origins (bioPM) significantly affect human health. However, for different air environments, they are not well characterized and can vary considerably. As an example, we investigated the bioPM differences at an urban (Beijing) site and a rural (Wangdu) site in the North China Plain (NCP) using an online monitoring instrument, an ultraviolet aerodynamic particle sizer (UV-APS), the limulus amebocyte lysate (LAL) assay, and a high-throughput sequencing method. Generally, lower concentrations of viable bioPM (hourly mean: 1.3 × 103 ± 1.6 × 103 m−3) and endotoxin (0.66 ± 0.16 EU/m3) in Beijing were observed compared to viable bioPM (0.79 × 105 ± 1.4 × 105 m−3) and endotoxin (15.1 ± 23.96 EU/m3) at the Wangdu site. The percentage of viable bioPM number concentration in the total PM was 3.1% in Beijing and 6.4% in Wangdu. Approximately 80% of viable bioPM was found to be in the range from 1 to 2.5 μm. Nevertheless, the size distribution patterns for viable bioPM at the Beijing and Wangdu sites differed and were affected by PM pollution, leading to distinct lung deposition profiles. Moreover, the distinct diurnal variations in viable bioPM on clean days were dimmed by the PM pollution at both sites. Distinct bacterial community structures were found in the air from the Beijing and Wangdu sites. The bacterial community in urban Beijing was dominated by genus Lactococcus (49.5%) and Pseudomonas (15.1%), while the rural Wangdu site was dominated by Enterococcus (65%) and Paenibacillus (10%). Human-derived genera, including Myroides , Streptococcus , Propionibacterium , Dietzia , Helcococcus , and Facklamia , were higher in Beijing, suggesting bacterial emission from humans in the urban air environment. Our results show that different air harbors different biological species, and people residing in different environments thus could have very different biological particle exposure. Image 1 • The PM of biological origins (bioPM) in urban Beijing and rural Wangdu were compared. • Viable bioPM in Beijing peaked around ∼2 μm, while below 2 μm in Wangdu. • Particulate air pollution dimmed the diurnal variation of viable bioPM. • The airborne bacterial communities showed large disparities between Beijing and Wangdu. • Human-derived bacterial genera contributed more to the air of urban Beijing. Urban and rural populations are exposed to distinct ambient bioPM communities. Humans themselves play a role in shaping the structure of bioPM in densely populated urban areas. [ABSTRACT FROM AUTHOR]

Published

2019

3. The characterization and quantification of viable and dead airborne biological particles using flow cytometry and double fluorescent staining.

Author

Liang, Linlin, Wu, Leixiang, Xu, Wanyun, Liu, Chang, Liu, Xuyan, Cheng, Hongbing, Liu, Yusi, Zhang, Gen, Che, Huizheng, Sun, Junying, and Zhang, Xiaoye

Subjects

*GRANULAR flow, *FLOW cytometry, *AIR pollutants, *ATMOSPHERIC chemistry, *ATMOSPHERIC physics, *PARTICULATE matter, *ATMOSPHERE, *WINTER

Abstract

Primary biological aerosol particles (PBAPs) are important air pollutants because they are ubiquitous in the atmosphere; influence human health, air quality, atmospheric chemistry and physics; and play important roles in regulating atmospheric processes. In investigations of the effects of PBAPs in ambient environments, it is necessary to distinguish them from other particles. In this study, flow cytometry (FCM) was utilized in combination with permeant (SYBR Green dyes) and impermeant (Propidium Iodide, PI) nucleic acid fluorescent stains, to characterize and quantify the viable and dead airborne PBAPs in ambient aerosol in Beijing, China. The number concentrations of viable and dead PBAPs showed a consistent trend and correlated well with one another (R 2 = 0.72, p < 0.01). However, no relationship was found between the number concentration of PBAPs and non-biological particles. The mean number concentrations of total particulate matter, dead PBAPs and viable PBAPs were 5.78 × 106 m−3, 1.11 × 106 m−3 and 7.09 × 105 m−3, respectively. The median PBAPs number concentrations (the sum of dead and viable) exhibited a seasonal cycle, i.e., highest in summer and autumn, lowest during winter and spring. Despite a lower median PBAPs number concentration during winter compared with other seasons, the viability peaked during winter, coinciding with the winter flu season. Stable synoptic conditions, polluted southwesterly air mass and long-range transported dust from the northwest desert region all contributed to the occurrence of explosive fluorescent PBAP episodes in Beijing, China. • Flow cytometry can rapidly detect viable and dead primary biological aerosol particles (PBAPs). • Dead and viable PBAPs correlated well and exhibited similar seasonal cycles. • The viability of PBAPs peaked in winter. • Stable synoptic conditions and dust transport contributed to high PBAP events. [ABSTRACT FROM AUTHOR]

Published

2022

4. Concentration and size distribution of viable bioaerosols during non-haze and haze days in Beijing.

Author

Gao, Min, Jia, Ruizhi, Wang, Xuming, Qiu, Tianlei, Han, Meilin, and Song, Yuan

Subjects

MICROBIOLOGICAL aerosols, PARTICULATE matter, AIR pollutants, AIR quality, GAUSSIAN distribution

Abstract

Accumulation of airborne particulate matter (PM) has profoundly affected the atmospheric environment of Beijing, China. Although studies on health risks have increased, characterization of specific factors that contribute to increased health risks remains an area of needed exploration. Chemical composition studies on PM can readily be found in the literature but researches on biological composition are still limited. In this study, the concentration and size distribution of viable airborne bacteria and fungi were determined in the atmosphere from May to July 2013 in Beijing, China. Samples were collected during non-haze days and haze days based on the value of air quality index (AQI) PM2.5. Multiple linear regression results indicated that concentrations of viable bioaerosol exhibited a negative correlation with PM2.5 (AQI) ranging from 14 to 452. There was a little difference in size distribution of bioaerosol between non-haze and haze days that all airborne bacteria showed skewed trends toward larger sizes and airborne fungi followed a Gaussian distribution. Spearman's correlation analysis showed that a fraction of bioaerosol with fine and coarse particles had negative and positive relations with PM2.5 (AQI), respectively. Moreover, the temporal variation of d (aerodynamic diameter) of bioaerosol with PM2.5 (AQI) fluctuated from 9:00 to 21:00, which suggested that their deposition pattern would vary during a day. The primary research in this study implied that aerodynamic size variation should be considered in assessing the bioaerosol exposure during haze weather. [ABSTRACT FROM AUTHOR]

Published

2015

5. Characteristics of airborne bacterial communities across different PM2.5 levels in Beijing during winter and spring.

Author

Zhang, Yangyang, Guo, Chongjing, Ma, Ke, Tang, Aohan, Goulding, Keith, and Liu, Xuejun

Subjects

*EMISSIONS (Air pollution), *CONDITIONED response, *ECOSYSTEM health, *ECOSYSTEMS, *ENVIRONMENTAL health, *ENVIRONMENTAL risk, *AIR pollution, *BACTERIAL communities

Abstract

Airborne bacteria are important components of fine particulate matter (PM 2.5), and have received increasing attention because of their impacts on public health and ecological systems. However, the relationships between the bacterial community and PM 2.5 pollution are poorly understood. The properties of bacterial communities in Beijing at low, medium and high PM 2.5 levels were analyzed during winter (December 2015–January 2016; January 2017) and spring (March 2016–May 2016; April 2017–May 2017). Variations in bacterial concentrations, Shannon and Simpson indices and relative abundance were significantly related to the seasons. In winter, there were no significant differences in bacterial communities among three PM 2.5 pollution levels. In contrast, significant correlations between bacterial abundance and PM 2.5 levels were observed in spring, and the bacterial concentrations, community richness and diversity indices were significantly higher on heavily polluted days compared to other pollution levels. Correlation results showed that relative humidity (RH), wind speed (WS), and O 3 were most closely associated with microbial community structure in winter (P < 0.05), but temperature (T), NO 2 , SO 2 , and CO in spring, while CO, NO 2 , O 3 , RH, and WS had significant relationships (|r| = 0.360–0.553, P < 0.05) with bacterial concentrations in winter, but PM 2.5 , O 3 , T, and RH (|r| = 0.281–0.527, P < 0.05) in spring. Chemical composition, especially that of secondary aerosol particles, which were mainly produced from anthropogenic sources (e.g. fossil fuel combustion, road traffic and industrial emissions), exerted the most control of bacterial community structure of PM 2.5. The effects of PM 2.5 levels on the bacterial community were modified by environmental conditions, heavy metal and nutrient contents of the PM 2.5. The relationships described provide a foundation for further research into the environmental and PM 2.5 chemical composition controls on the bacterial community and related health risk from air pollution. [Display omitted] • Conditional responses of bacterial communities to PM 2.5 pollution. • Stable bacterial communities across different PM 2.5 levels in winter. • Significant changes of bacterial communities to PM 2.5 levels in spring. • Secondary aerosol particles exerted the most control of bacterial community structure. [ABSTRACT FROM AUTHOR]

Published

2022

6. Impact of outdoor air on indoor airborne microbiome under hazy air pollution: A case study in winter Beijing.

Author

Zhou, Feng, Niu, Mutong, Zheng, Yunhao, Sun, Ye, Wu, Yan, Zhu, Tianle, and Shen, Fangxia

Subjects

*MICROBIOLOGICAL aerosols, *INDOOR air pollution, *AIR pollution, *FUNGAL communities, *POLYMERASE chain reaction, *BACTERIAL communities, *WINTER

Abstract

Exposure to indoor airborne microbiomes (bioaerosols) is closely associated with human health. However, knowledge regarding the characteristics of indoor bioaerosols in areas affected by serious ambient air pollution is still limited. In this study, indoor bioaerosols were characterized in winter Beijing via quantitative polymerase chain reaction (qPCR) and amplicon sequencing, and compared to outdoor bioaerosols. Concentrations of indoor bioaerosol were significantly lower than those of the adjacent outdoor bioaerosol, and were not significantly affected by outdoor air pollution. Community structures of indoor bioaerosol were distinct from those of outdoor environment, and were differentially affected by ambient air pollution. Specifically, significant change was observed in indoor fungal community impacted by hazy air pollution, while not in bacteria and archaea. Compared to outdoor air, indoor air was preferentially enriched with fungi (~10%) in winter. Besides, about 40% of the bacteria indoors were likely contributed by outdoor bacteria. The results provide useful information regarding the impact of ambient air pollution on indoor bioaerosols, and furtherly highlight the distinction between indoor and outdoor bioaerosol assemblies. [Display omitted] • Impact of winter haze pollution on indoor airborne bacteria, fungi and archaea was delineated. • The abundance and diversity of indoor bioaerosols were lower than those outdoors. • The percentage of fungi in bioaerosols indoors was higher that outdoors. • Nearly 40% of indoor bacterial communities were contributed by outdoor air. • Ambient haze pollution differentially affected the indoor and outdoor fungal aerosols. [ABSTRACT FROM AUTHOR]

Published

2021