Indoor bioaerosol is bioaerosol in an indoor environment. Bioaerosols are natural or artificial

particle In the physical sciences, a particle (or corpuscule in older texts) is a small localized object which can be described by several physical or chemical properties, such as volume, density, or mass. They vary greatly in size or quantity, from ...

s of biological ( microbial, plant, or animal) origin suspended in the air. These particles are also referred to as organic dust. Bioaerosols may consist of

bacteria Bacteria (; singular: bacterium) are ubiquitous, mostly free-living organisms often consisting of one Cell (biology), biological cell. They constitute a large domain (biology), domain of prokaryotic microorganisms. Typically a few micrometr ...

fungi A fungus ( : fungi or funguses) is any member of the group of eukaryotic organisms that includes microorganisms such as yeasts and molds, as well as the more familiar mushrooms. These organisms are classified as a kingdom, separately from ...

(and spores and cell fragments of fungi),

virus A virus is a submicroscopic infectious agent that replicates only inside the living cells of an organism. Viruses infect all life forms, from animals and plants to microorganisms, including bacteria and archaea. Since Dmitri Ivanovsk ...

es, microbial toxins, pollen,

plant fiber Fiber crops are field crops grown for their fibers, which are traditionally used to make paper, cloth, or rope. Fiber crops are characterized by having a large concentration of cellulose, which is what gives them their strength. The fibers may b ...

s, etc.Douwes, J., et al., Bioaerosol health effects and exposure assessment: Progress and prospects. Annals of Occupational Hygiene, 2003. 47(3): p. 187-200. Size of bioaerosol particles varies from below 1 µm to 100 µm in aerodynamic diameter;Sanchez-Monedero, M.A., et al., Effect of the aeration system on the levels of airborne microorganisms generated at wastewater treatment plants. Water Research, 2008. 42(14): p. 3739-3744. viable bioaerosol particles can be suspended in air as single cells or aggregates of

microorganism A microorganism, or microbe,, ''mikros'', "small") and ''organism'' from the el, ὀργανισμός, ''organismós'', "organism"). It is usually written as a single word but is sometimes hyphenated (''micro-organism''), especially in olde ...

as small as 1–10 µm in size.Pastuszka, J.S., et al., Bacterial and fungal aerosol in indoor environment in Upper Silesia, Poland. Atmospheric Environment, 2000. 34(22): p. 3833-3842. Since bioaerosols are potentially related to various human health effectsChao, H.J., et al., Populations and determinants of airborne fungi in large office buildings. Environmental Health Perspectives, 2002. 110(8): p. 777-782.Peccia, J., et al., A role for environmental engineering and science in preventing bioaerosol-related disease. Environmental Science & Technology, 2008. 42(13): p. 4631-4637.Wouters, I.M., et al., Increased levels of markers of microbial exposure in homes with indoor storage of organic household waste. Applied and Environmental Microbiology, 2000. 66(2): p. 627-631.Burge, H., Bioaerosol - prevalence and health effects in the indoor environment. Journal of Allergy and Clinical Immunology, 1990. 86(5): p. 687-701. and the indoor environment provides a unique exposure situation, concerns about indoor bioaerosols have increased over the last decade.

Sources and influencing factors

Sources for indoor environments

Indoor bioaerosols may originate from outdoor air and indoor reservoirs. Although outdoor bioaerosols cannot easily migrate into large buildings with complex ventilation systems, certain categories of outdoor bioaerosols (i.e., fungal spores) do serve as major sources for indoor bioaerosols in naturally ventilated buildings at specific periods of time (i.e., growing seasons for fungi). Major indoor sources for bioaerosols at residential homes include human occupants,

pet A pet, or companion animal, is an animal kept primarily for a person's company or entertainment rather than as a working animal, livestock, or a laboratory animal. Popular pets are often considered to have attractive appearances, intelligence ...

s, house dust,

organic waste Biodegradable waste includes any organic matter in waste which can be broken down into carbon dioxide, water, methane or simple organic molecules by micro-organisms and other living things by composting, aerobic digestion, anaerobic digesti ...

, as well as the heating, ventilation and air-conditioning ( HVAC) system.Chen, Q. and L.M. Hildemann, The Effects of Human Activities on Exposure to Particulate Matter and Bioaerosols in Residential Homes. Environmental Science & Technology, 2009. 43(13): p. 4641-4646.Park, J.H., et al., Predictors of airborne endotoxin in the home. Environmental Health Perspectives, 2001. 109(8): p. 859-864. Several studies have identified human activities as an important source for indoor bioaerosols.Kalogerakis, N., et al., Indoor air quality - bioaerosol measurements in domestic and office premises. Journal of Aerosol Science, 2005. 36(5-6): p. 751-761.Li, C.S. and P.A. Hou, Bioaerosol characteristics in hospital clean rooms. Science of the Total Environment, 2003. 305(1-3): p. 169-176. Human bodies can generate bioaerosols directly through activities like talking, sneezing, and coughing, while other residential activities (i.e., washing, flushing toilet, sweeping floor) can generate bioaerosols indirectly. Since microorganisms can accumulate and grow on

dust Dust is made of fine particles of solid matter. On Earth, it generally consists of particles in the atmosphere that come from various sources such as soil lifted by wind (an aeolian process), volcanic eruptions, and pollution. Dust in ho ...

particles, house dust is a potential source of bioaerosols. In a study by Wouters ''et al''., they investigated the effects of indoor storage of organic household waste on microbial contamination among 99 households in the Netherlands in the summer of 1997, and indicated that “increased microbial contaminant levels in homes are associated with indoor storage of separated organic waste”, which might elevate “the risk of bioaerosol-related respiratory symptoms in susceptible people”. However, the analysis by Wouters ''et al''. was based on the collected samples of settled house dust, which might not serve as a strong indicator for bioaerosols suspended in the air. Other materials in residential buildings, such as food stuffs, house plants,

textile Textile is an umbrella term that includes various fiber-based materials, including fibers, yarns, filaments, threads, different fabric types, etc. At first, the word "textiles" only referred to woven fabrics. However, weaving is not the ...

s, wood material and furniture stuffing can also become bioaerosol sources when water content is appropriate for microorganisms to grow. For non-residential buildings, some specific indoor environments, such as hospitals, wastewater treatment plants, composting facilities, certain biotechnical laboratories, have been revealed to have bioaerosol sources related to their particular environmental characteristics.Sanchez-Monedero, M.A., E.I. Stentiford, and C. Mondini, Biofiltration at composting facilities: Effectiveness for bioaerosol control. Environmental Science & Technology, 2003. 37(18): p. 4299-4303.Bauer, H., et al., Bacteria and fungi in aerosols generated by two different types of wastewater treatment plants. Water Research, 2002. 36(16): p. 3965-3970.

Factors influencing indoor bioaerosol generation

According to previous studies,Verreault, D., S. Moineau, and C. Duchaine, Methods for sampling of airborne viruses. Microbiology and Molecular Biology Reviews, 2008. 72(3): p. 413-444.Dekoster, J.A. and P.S. Thorne, Bioaerosol concentrations in noncomplaint, complaint, and intervention homes in the Midwest. American Industrial Hygiene Association Journal, 1995. 56(6): p. 573-580.Law, A.K.Y., C.K. Chau, and G.Y.S. Chan, Characteristics of bioaerosol profile in office buildings in Hong Kong. Building and Environment, 2001. 36(4): p. 527-541. major indoor environmental factors influencing bioaerosol concentration include relative

humidity Humidity is the concentration of water vapor present in the air. Water vapor, the gaseous state of water, is generally invisible to the human eye. Humidity indicates the likelihood for precipitation, dew, or fog to be present. Humidity dep ...

, characteristics of air ventilation systems,

seasonal variation In time series data, seasonality is the presence of variations that occur at specific regular intervals less than a year, such as weekly, monthly, or quarterly. Seasonality may be caused by various factors, such as weather, vacation, and holidays a ...

, temperature, and chemical composition of the air. Other factors, such as the type of home,

building material Building material is material used for construction. Many naturally occurring substances, such as clay, rocks, sand, wood, and even twigs and leaves, have been used to construct buildings. Apart from naturally occurring materials, many man-ma ...

, geographical factors, do not seem to have significant impacts on respirable fungi and bacteria (important constituents of bioaerosols). Relative humidity is one of the most widely studied influencing factors for indoor bioaerosols. Concentrations of two categories of bioaerosols, endotoxin and airborne fungi, are both positively related to indoor relative humidity (higher concentration associated with higher relative humidity). Relative humidity also affects the

infectivity In epidemiology, infectivity is the ability of a pathogen to establish an infection. More specifically, infectivity is a pathogen's capacity for horizontal transmission — that is, how frequently it spreads among hosts that are not in a parent ...

of airborne viruses. Regarding the characterisation of air ventilation system, increased use of central air conditioning is found to be associated with lower fungal bioaerosol concentration.

Human health effects

Adverse health effects/diseases related to indoor bioaerosol exposure can be divided into two categories: those confirmed to be associated with bioaerosol and those suspected but not confirmed to be associated with bioaerosol. Bioaerosols have been revealed to cause certain human diseases, such as

tuberculosis Tuberculosis (TB) is an infectious disease usually caused by '' Mycobacterium tuberculosis'' (MTB) bacteria. Tuberculosis generally affects the lungs, but it can also affect other parts of the body. Most infections show no symptoms, i ...

, Legionnaires' disease and different forms of

bacterial pneumonia Bacterial pneumonia is a type of pneumonia caused by bacterial infection. Types Gram-positive '' Streptococcus pneumoniae'' () is the most common bacterial cause of pneumonia in all age groups except newborn infants. ''Streptococcus pneumonia ...

coccidioidomycosis Coccidioidomycosis (, ), commonly known as cocci, Valley fever, as well as California fever, desert rheumatism, or San Joaquin Valley fever, is a mammalian fungal disease caused by '' Coccidioides immitis'' or ''Coccidioides posadasii''. Coccid ...

, influenza, measles, and

gastrointestinal illness Gastrointestinal diseases (abbrev. GI diseases or GI illnesses) refer to diseases involving the gastrointestinal tract, namely the oesophagus, stomach, small intestine, large intestine and rectum, and the accessory organs of digestion, the liver, ...

.Peccia, J. and M. Hernandez, Incorporating polymerase chain reaction-based identification, population characterization, and quantification of microorganisms into aerosol science: A review. Atmospheric Environment, 2006. 40(21): p. 3941-3961. Bioaerosols are also associated with some noninfectious airway diseases, such as allergies and asthma. As a known component of indoor bioaerosol, β(1→3)-glucan (cell wall components of most fungi) is proposed to be the

causative agent In biology, a pathogen ( el, πάθος, "suffering", "passion" and , "producer of") in the oldest and broadest sense, is any organism or agent that can produce disease. A pathogen may also be referred to as an infectious agent, or simply a ge ...

mold A mold () or mould () is one of the structures certain fungi can form. The dust-like, colored appearance of molds is due to the formation of spores containing fungal secondary metabolites. The spores are the dispersal units of the fungi. Not ...

-induced nonallergic inflammatory reactions. It is reported that 25%-30% of allergenic

asthma Asthma is a long-term inflammatory disease of the airways of the lungs. It is characterized by variable and recurring symptoms, reversible airflow obstruction, and easily triggered bronchospasms. Symptoms include episodes of wheezing, co ...

cases in industrialised countries are induced by fungi, which has been the focus of concerns about human exposure to airborne microorganisms in recent years.Vanhee, L.M.E., H.J. Nelis, and T. Coenye, Rapid Detection and Quantification of Aspergillus fumigatus in Environmental Air Samples Using Solid-Phase Cytometry. Environmental Science & Technology, 2009. 43(9): p. 3233-3239. Some other human diseases and symptoms have been proposed to be associated with indoor bioaerosol, but no deterministic conclusions could be drawn due to the insufficiency of evidence. One example is the well-known sick building syndrome (SBS). SBS refers to non-specific complaints, such as upper-respiratory irritative symptoms, headaches, fatigue, and

rash A rash is a change of the human skin which affects its color, appearance, or texture. A rash may be localized in one part of the body, or affect all the skin. Rashes may cause the skin to change color, itch, become warm, bumpy, chapped, dry, c ...

, which cannot be related to an identifiable cause but are building related.Redlich, C.A., J. Sparer, and M.R. Cullen, Sick-building syndrome. Lancet, 1997. 349(9057): p. 1013-1016. Over the last two decades, there have been many studies indicating association of indoor bioaerosol with sick building syndrome.Cooley, J.D., et al., Correlation between the prevalence of certain fungi and sick building syndrome. Occupational and Environmental Medicine, 1998. 55(9): p. 579-584.Gyntelberg, F., et al., Dust and the sick building syndrome. Indoor Air-International Journal of Indoor Air Quality and Climate, 1994. 4(4): p. 223-238.Teeuw, K.B., C. Vandenbrouckegrauls, and J. Verhoef, Airborne gram-negative bacteria and endotoxin in sick building syndrome - a study in Dutch governmental office buildings. Archives of Internal Medicine, 1994. 154(20): p. 2339-2345.Li, C.S., C.W. Hsu, and M.L. Tai, Indoor pollution and sick building syndrome symptoms among workers in day-care centers. Archives of Environmental Health, 1997. 52(3): p. 200-207. However, most of the related studies based their conclusions on statistical correlation between concentrations of certain types of bioaerosols and incidence of complaints, which has various drawbacks methodologically. For example, some studies have a small sample size, which critically undermines the validity of speculations based on the statistical results. Also, many studies were not able to exclude the influences of other factors beside bioaerosol in their analysis, which makes the statistical correlation theoretically inappropriate to support association of SBS with bioaerosols. Additional studies revealed that bioaerosol is unlikely to be the cause of SBS.Burge, P.S., Sick building syndrome. Occupational and Environmental Medicine, 2004. 61(2): p. 185-190.Harrison, J., et al., An investigation of the relationship between microbial and particulate indoor

air pollution Air pollution is the contamination of air due to the presence of substances in the atmosphere that are harmful to the health of humans and other living beings, or cause damage to the climate or to materials. There are many different typ ...

and the sick building syndrome. Respiratory Medicine, 1992. 86(3): p. 225-235. Recent epidemiological and toxicological studies continued to suggest a possible link between bioaerosol exposure and sick building syndrome, but methodological limitations remained in these studies.Laumbach, R.J. and H.M. Kipen, Bioaerosols and sick building syndrome: particles,

inflammation Inflammation (from la, inflammatio) is part of the complex biological response of body tissues to harmful stimuli, such as pathogens, damaged cells, or irritants, and is a protective response involving immune cells, blood vessels, and molec ...

, and

allergy Allergies, also known as allergic diseases, refer a number of conditions caused by the hypersensitivity of the immune system to typically harmless substances in the environment. These diseases include hay fever, food allergies, atopic derm ...

. Current Opinion in Allergy and Clinical Immunology, 2005. 5(2): p. 135-139. The ability of bioaerosols to cause human

disease A disease is a particular abnormal condition that negatively affects the structure or function of all or part of an organism, and that is not immediately due to any external injury. Diseases are often known to be medical conditions that a ...

depend not only on their chemical composition and biological characteristics, but also on the quantity of bioaerosol inhaled and their size distribution, which determines the site of bioaerosol deposition to human

respiratory system The respiratory system (also respiratory apparatus, ventilatory system) is a biological system consisting of specific organs and structures used for gas exchange in animals and plants. The anatomy and physiology that make this happen varies ...

s. Bioaerosols larger than 10 µm in aerodynamic diameter are generally blocked by the nasal region of the respiratory tract, those between 5-10 µm mainly deposit in the upper respiratory system and usually induce symptoms like allergic

rhinitis Rhinitis, also known as coryza, is irritation and inflammation of the mucous membrane inside the nose. Common symptoms are a stuffy nose, runny nose, sneezing, and post-nasal drip. The inflammation is caused by viruses, bacteria, irrita ...

, and particles with aerodynamic diameter less than 5 µm can reach the alveoli and hence lead to serious illnesses such as allergic alveolitis. Because of the confirmed and potential adverse health effects associated with indoor bioaerosol, some concentration limits for total number of bioaerosol particles are recommended by different agencies and organisations as follow: 1000 CFUs/m³ (

National Institute for Occupational Safety and Health The National Institute for Occupational Safety and Health (NIOSH, ) is the United States federal agency responsible for conducting research and making recommendations for the prevention of work-related injury and illness. NIOSH is part of the C ...

(NIOSH)), 1000 CFUs/m³ (

American Conference of Governmental Industrial Hygienists The American Conference of Governmental Industrial Hygienists (ACGIH) is a professional association of industrial hygienists and practitioners of related professions, with headquarters in Cincinnati, Ohio. One of its goals is to advance worker pr ...

(ACGIH)) with the culturable count for total bacteria not exceeding 500 CFUs/m³. Note that for most types of indoor bioaerosols, the establishment of specific concentration limits or acceptance levels presents multiple challenges (e.g., differences on sampling and analysis method, irrelevance of sampling units to human exposure measurement; multiplicity and variability of composition, etc.).

Sampling and detection methods

Bioaerosol sampling techniques

To enable subsequent identification and quantification, bioaerosols need to be captured from the air first. Different air sampling techniques have been used to realise the goal of capturing indoor bioaerosols.. Important characteristics of bioaerosol sampling include: representativeness of sampling, sampler performance, and compatibility with subsequent analysis.Pasanen, A.L., A review: Fungal exposure assessment in indoor environments. Indoor Air, 2001. 11(2): p. 87-98. Long-term sampler theoretically has a better representativeness of sampling than short-term sampler, but may not have a good temporary resolution. Performance of samplers (i.e., limit of detection and upper limit of range) has a significant impact on the reliability of results. Different characterisations of samplers can also limit the possibilities for further analysis (identification and quantification). Major bioaerosol sampler types and their possible subsequent analysis are summarised in Table 1. A frequently used sampler in previous studies is the Andersen impactor.Gorny, R.L. and J. Dutkiewicz, Bacterial and fungal aerosols in indoor environment in Central and Eastern European countries. Annals of Agricultural and Environmental Medicine, 2002. 9(1): p. 17-23. Certain limitations exist for commonly used bioaerosol samplers. For most of the samplers, nonbiological environmental particles such as dust must be separated from bioaerosols prior to detection.Moon, H.S., et al., Dielectrophoretic Separation of Airborne Microbes and Dust Particles Using a Microfluidic Channel for Real-Time Bioaerosol Monitoring. Environmental Science & Technology, 2009. 43(15): p. 5857-5863. The diluted nature of bioaerosol in the air also poses challenges to samplers. While total microorganism concentrations are on the order of 10⁶/cm³ or greater, bioaerosol concentrations are commonly less than 1/cm³, and often less than 1/m³ in the case of infectious aerosols. Moreover, many commercially available bioaerosol samplers haven not been investigated on their collection efficiencies for particles with different aerodynamic diameters, which makes it impossible to get the size-resolved bioaerosol information.

Identification and quantification methods

In previous research on indoor bioaerosol in residential environments, microorganisms have been quantified by conventional culture-based techniques, in which colony forming units (CFU) on selective media are counted.Li, C.S. and T.Y. Huang, Fluorochrome in monitoring indoor bioaerosols. Aerosol Science and Technology, 2006. 40(4): p. 237-241. Cultivating methods have several disadvantages. Culture-based methods are known to underestimate environmental microbial diversity, based on the fact that only a small percentage of microbes can be cultivated in the laboratory. This underestimation is likely to be signified for the quantification of bioaerosol, since colony counts of airborne microbes are typically quite different from direct counts.Fierer, N., et al., Short-term temporal variability in airborne bacterial and fungal populations. Applied and Environmental Microbiology, 2008. 74(1): p. 200-207. Culture-based methods also need relatively long incubation times (over 24 hours) and are labor-intensive. Consequently, culture-based methods are no longer suitable for effective and rapid identification and quantification of bioaerosol, and non-culture based methods, such as immunoassays, molecular biological tests, and optical, and electrical methods, have been developing over the past few decades. Major culture-independent identification/quantification methods adopted in previous bioaerosol studies include polymerase chain reaction (PCR), quantitative polymerase chain reaction (qPCR),An, H.R., G. Mainelis, and L. White, Development and calibration of real-time PCR for quantification of airborne microorganisms in air samples. Atmospheric Environment, 2006. 40(40): p. 7924-7939. microarray (PhyloChip),Brodie, E.L., et al., Urban aerosols harbor diverse and dynamic bacterial populations. Proceedings of the National Academy of Sciences of the United States of America, 2007. 104(1): p. 299-304. fluorescent in situ hybridisation (FISH),Lange, J.L., P.S. Thorne, and N. Lynch, Application of flow cytometry and fluorescent in situ hybridisation for assessment of exposures to airborne bacteria. Applied and Environmental Microbiology, 1997. 63(4): p. 1557-1563. flow cytometry and solid-phase cytometry, immunoassay (i.e., enzyme-linked immunosorbent assay (ELISA)). The well-known PCR is a powerful tool in identifying and even quantifying the biological origin of bioaerosols. PCR alone cannot accomplish all the tasks related to bioaerosol detection; instead it usually serves as the preparation tool for subsequent processes like DNA sequencing, microarray, and community fingerprinting techniques. A typical procedure for PCR-based bioaerosol analysis is shown in Figure 1. Molecular biological methods for bioaerosol are significantly faster and more sensitive than conventional culture-based methods, and they are also able to reveal a larger diversity of microbes. Targeting the variation in the 16S rRNA gene, a microarray (PhyloChip) was used to conduct comprehensive identification of both bacterial and archaeal organisms in bioaerosols. New U.S. EPA methods have been developed to utilise qPCR to characterise indoor environment for fungal spores. In a study by Lange ''et al''., FISH method successfully identified eubacteria in samples of complex native bioaerosols in swine barns. Nonetheless, molecular biological tools have limitations. Since PCR methods target DNA, viability of cells could not be confirmed in some cases. When qPCR technique is used for bioaerosol detection, standard curves need to be developed to calibrate final results. One study indicated that “curves used for quantification by qPCR needs to be prepared using the same environmental matrix and procedures as handling of the environmental sample in question” and that “reliance on the standard curves generated with cultured bacterial suspension (a traditional approach) may lead to substantial underestimation of microorganism quantities in environmental samples”. Microarray techniques also face the challenge of natural sequence diversity and potential cross-hybridisation in complex environmental bioaerosols).

Concentration levels in different geographical regions

Concentration levels of indoor bioaerosols in different regions of the world recorded in published literatures are summarised as Table 2.

Approaches to control indoor bioaerosols

Based on the sources and the influencing factors for indoor bioaerosols, corresponding remedial actions can be taken to control related contamination. Potentially effective strategies include: 1) limiting entrance of outdoor aerosols; 2) keeping the relative humidity level below high levels (<60%); 3) installing appropriate filtration devices to air ventilation system to inlet filtered outdoor air into indoor environment; 4) reducing/removing contaminant sources (i.e., indoor organic waste). As in the U.S., due to the increase in tuberculosis in the mid-1980s, indoor air treatment has developed substantially during the past two decades. Current or developing indoor air purification technologies include filtration, aerosol ultraviolet irradiation, electrostatic precipitation, unipolar ion emission, and photocatalytic oxidation.

References

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