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Review Article: Indoor Biological Contaminants in the Built Environment

Nur Baitul Izati Rasli1 * , Nor Azam Ramli1 and Mohd Rodzi Ismail2

Corresponding author Email: nurbaitulizati@gmail.com

DOI: http://dx.doi.org/10.12944/CWE.16.1.05

Occupants of buildings spent most of their time indoors and posed themselves to the indoor biological contaminants (i.e. bacteria and fungi) in the built environment. However, the factors that influenced the prevalence of suspended bacteria and fungi in the air of the built environment are not well recognised. Authorities must take the growth of biological contaminants seriously to prevent serious health effects among occupants of buildings. This review summarises the factors (i.e. outdoor air, dust, ventilation problems, humidity/moisture surface problems and human occupancy) of indoor biological contaminants and their species in buildings that could worsen the indoor air quality. Bacteria species could exist in various indoor buildings (i.e. schools, cafeterias, mosques, faculties, child day-care centres, hospitals, dwellings, educational buildings, homes, elderly care centres, libraries, restaurants, and factories).  The dominant bacteria were Bacillus spp. (24.1 %), Staphylococcus spp. (20.7 %), and Micrococcus spp. (20.7 %) whereas for fungi species were Penicillium spp. (25 %), Cladosporium spp. (21.9 %), and Aspergillus spp. (21.9 %).

Bacteria; Building; Dust; Fungi; Health Effect; Human Occupancy; Moisture Problem; Outdoor Air; Sustainability; Ventilation Problem

Copy the following to cite this article:

Rasli N. B. I, Ramli N. A, Ismail M. R. Review Article: Indoor Biological Contaminants in the Built Environment. Curr World Environ 2021;16(1). DOI:http://dx.doi.org/10.12944/CWE.16.1.05

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Rasli N. B. I, Ramli N. A, Ismail M. R. Review Article: Indoor Biological Contaminants in the Built Environment. Curr World Environ 2021;16(1). Available From : https://bit.ly/32bidB4


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Article Publishing History

Received: 27-11-2020
Accepted: 12-04-2021
Reviewed by: Orcid Orcid Dr Vikram Pratap Singh
Second Review by: Orcid Orcid Pablo Evelson
Final Approval by: Dr. M. Rafatullah


Introduction

In the last few decades, the problems of airborne bacteria and fungi in indoor environments have significantly increased worldwide1. The quality of the living spaces and occupants' health and well-being can be influenced directly or indirectly by microbes in buildings2-6. The problems of indoor microbes in the built environment have been taken seriously into account by biologists in collaboration with building designers7, 8. Kembel et al. summarised the three essential concerns associated with indoor microbes. Firstly, indoor bacteria and fungi interact with one another and with the environment in the complex ecosystem of the built environment10-12. Secondly, people in the built environment have significant potential contact with indoor bacteria and fungi13,14. Thirdly, many cases show that indoor bacteria and fungi affect human health15-17.

Numerous studies on airborne bacteria and fungi in the built environment conducted in different countries, including Korea, China, Ethiopia, Iran, Italy, Portugal, Jordan, France, Egypt, Malaysia, Pakistan, Greece and Finland with varying indoor locations15,17-28. Table 1 provides the details (i.e. country, location, finding, and genera) of the studies on indoor airborne conducted worldwide. Micrococcus, Staphylococcus, Bacillus and Pseudomonas are the most common bacteria found indoors5.

Table 1: Details of Studies on Indoor Airborne Conducted Worldwide.

No.

Country

Location

Finding

Dominant Genera

References

1.

Finland

School buildings

Fungal was influenced by hidden excess moisture and mould growth of other fungi

Fungal: Trichoderma species (i.e. Mycoparasitic and mycotrophic T. atroviride)

28

2.

Greece

Primary school

Green Roof System tend to improve indoor air quality, hence enhanced the students' comfort and performance.

Fungal: Penicillium, Cladosporium, and Aspergillus

17

3.

Pakistan

Cafeterias of a university campus

The outdoor fungal and bacterial concentrations were higher than that in indoor

 

- Fungal: 46% of Cladosporium spp., 8.6% of Geotrichium spp., 8.5% of Ulocladium spp., 7.9% of Alterneria spp., 6.6% of Fusarium spp., 3% of Curvularia spp., 2.4% of Aspergillus spp. and 1.3% of Penicillium spp.

- Bacterial: Staphylococcus spp., Kocuria spp., Bacillus spp. and Micrococcus spp.

27

4.

Malaysia

Mosques

The bacterial and fungal counts and the average of PM10 concentrations were higher in

air conditioning mosques compared to non-air conditioning mosques

Bacterial: Staphylococcus spp.,

Bacillus spp. and Micrococci spp.

Fungal: Aspergillus

niger.

26

5.

Egypt

Public buildings: libraries, faculties, schools, child

daycare centres and hospitals

- The microbes contaminate the hospitals' operation

- Temperature has no significance in bacterial growth

- Particulate matter and relative humidity influential in fungal growth

- Bacterial: Bacillus subtilis and Bacillus atrophaeus

- Fungal: Aspergillus, Alternaria, Penicillium, and Cladosporium

25

6.

France

Hospitals

The bacterial growth has no relationship with the sampling sites.

- Fungal: Penicillium, Alternaria, Cladosporium

- Bacterial: Staphylococcus

Aureus, Escherichia coli

24

7.

Jordan

Dwellings and educational

building

The PAHs metabolite, which is active and carcinogenic products could influence the human

- Bacterial: Gram-positive bacteria, Gram-negative bacteria, Fungal: Penicillium/Aspergillus spp.

23

8.

Portugal

Homes,

child day-care centres, primary schools, and elderly care centres

- The cause of the highest indoor bacterial and fungal concentrations in the user activities and density and the lack of ventilation.

Fungal: Penicillium and Cladosporium

22

9.

Italy

Library

The white efflorescence appeared in the book caused by the lack of ventilation system, a dusting programme, air-conditioning, and the hygroscopic behaviour of materials used in the book.

Fungal: Eurotium halophilicum behaved as a pioneer species

21

10.

Iran

Hospital

The outdoor bioaerosol influenced indoor hospital air quality

- Bacterial: Bacillus spp., Micrococcus spp., Streptomyces spp., and Staphylococcus spp. were the dominant bacteria indoors and outdoors on regular and dust event days.

20

11.

Ethiopia

Library university

Most bacterial and fungal isolated could cause sick building syndromes with significant allergy, rhinitis, asthma, and conjunctivitis.

- Bacteria: Micrococcus sp., Staphylococcus aureus, Streptococcus pyogenes, Bacillus sp., and Neisseria sp.

- Fungal: Cladosporium sp., Alternaria sp., Penicillium sp., and Aspergillus sp.

15

12.

Hong Kong, China

Restaurants located on the hillside

at The Chinese University of Hong Kong

Researcher’s identified the bacteria species in the skin and respiratory tract of humans and from the soil.

Bacterial: Gram-positive bacteria in which Micrococcus and Bacillus species were the most abundant

19

13.

Korea

Factories

- The environmental factors have a significantly positive relationship with the vitality of indoor airborne microorganisms.

- Bacterial: Staphylococcus spp., Micrococcus spp., Corynebacterium spp. and Bacillus spp.

- Fungal: Cladosporium spp., Penicillium spp. and Aspergillus spp.

18

 

Certain bacteria and fungi species tend to dominate various indoor spaces in buildings. These include schools, cafeterias, mosques, faculties, child day-care centres, hospitals, dwellings, educational buildings, homes, elderly care centres, libraries, restaurants, and factories.  The bacteria species were Bacillus spp. (24.1 %), Staphylococcus spp. (20.7 %), and Micrococcus spp. (20.7 %), Gram-positive bacteria (6.9 %), Kocuria spp. (3.4 %), Aureus (3.4 %), Escherichia coli (3.4 %), Gram-negative bacteria (3.4 %), Streptomyces spp. (3.4 %), Escherichia coli (3.4 %), Gram-negative bacteria (3.4 %), Streptococcus pyogenes (3.4 %), Neisseria spp. (3.4 %), and Corynebacterium spp. (3.4 %).  Meanwhile, fungi species were Penicillium spp. (25 %), Cladosporium spp. (21.9 %), Aspergillus spp. (21.9 %), Alterneria spp. (12.5 %), Trichoderma spp. (3.1 %), Ulocladium spp. (3.1 %), Geotrichium spp. (3.1 %), Fusarium spp. (3.1 %), Curvularia spp. (3.1 %), and Eurotium halophilicum (3.1 %).

Factors of Indoor Biological Contaminants in Buildings

Dispersal of Airborne Bacteria and Fungi by Outdoor Air


Outdoor air has become one of the main factors contributing to the complex system of indoor biological contaminants within a building25, 29, 30. Air exchange in the built environment is the replacement of fresh outdoor air with indoor air.  A high air exchange rate from the outdoor environment with comfortable climate conditions can improve indoor air quality by reducing indoor air contaminants30. Outdoor air can be exchanged with indoor air through infiltration (i.e. particle penetration through the leakage paths of the wall’s building), natural ventilation (i.e. doors, windows and other openings) and mechanical ventilation (i.e. fans) 30, 31. Figure 1 shows the building air exchange31. However, indoor airborne bacteria and fungi accumulated from the dispersal from the outdoors that grew and resuspended in the built environment29 can potentially influence the microbial community structure9.  Table 2 lists the study cases on outdoor air with microbial problems.

Figure 1: Air Exchange in Buildings through Infiltration, Natural Ventilation, and Mechanical Ventilation Adapted from Chen and Zhao31.

Click here to view Figure



Table 2: Studies on Outdoor Air Dispersed into Indoor Buildings with Indoor Microbial Problems.

No.

Dispersion of Outdoor Air with Indoor Microbial Problems in the Built Environment

Dominant Genera

References

1.

From the ecological approach, fungi could be dispersed from the outdoors into the built environment when the building type is held constant.

The 100% sequence similarity of fungi in indoor air and outdoor air shows that Epicoccum sp., Aureobasidum pullulans, Cladosporium sp., Cryptococcus carnescens and Epicoccum sp. are the dominant genera.

29

2.

Outdoor bioaerosol can contribute to the lower indoor air quality in hospitals.

The dominant bacteria indoors and outdoors were Bacillus spp., Micrococcus spp., Streptomyces spp. and Staphylococcus spp.

20

3.

The indoor/outdoor (I/O) ratios of airborne microorganisms at old and new book libraries are less than one, indicating no microbial sources from indoor.

The dominant indoor bacteria from outdoors are Bacillus pseudomycoides and B. subtilis, whereas the prevalent outdoor bacteria are B. subtilis and Staphylococcus aspergillus and Penicillium.

30



Dust Present in Indoor Air

The accumulated dust (i.e. particulate matter) is one factor supporting airborne bacterial and fungal culturability in an indoor environment 25. Indoor airborne particles sizes in the aerodynamic diameter range of 0.1–10 µm (i.e. coarse particles ≥ 7 µm and fine particles < 2.5 µm)30. Figure 2 shows the airborne particles that can penetrate the human respiratory system from stage 0 to stage 7 with their respective particle size distribution33. Pyrri et al.17 found that Aspergillus concentration is positively correlated with the coarse fraction of PM10 concentration indoors.  Besides, the bacterial and fungal components have contributed to the adverse health effects (i.e. inflammatory lung diseases (neutrophilic inflammation), chronic lung diseases (asthma, chronic obstructive pulmonary disorder (COPD), and lung cancer)) and environmental determinants (i.e. settled dust, floor dust, mattress dust, and from hoover dust collection bag)34,35. Table 3 lists the study cases on dust particles with microbial problems.
Figure 2: Sizes of Airborne Particles that can Penetrate the Human Respiratory System Adapted from Andrade-Lima et al.33.

Click here ot view Figure


Table 3: Studies on Dust Particles with Indoor Microbial Problems.

No.

Dust Particles Causing Indoor Microbial Problems in the Built Environment

Dominant Genera

References

1.

Concentrations of bacteria and fungi within hospital buildings are high on dusty days.

The dominant indoors and outdoors bacteria on regular and dusty days are Bacillus spp., Micrococcus spp., Streptomyces spp. and Staphylococcus spp gram-positive bacteria exhibiting higher concentrations than gram-negative bacteria.

20

2.

Polycyclic aromatic hydrocarbons (PAHs) are active and carcinogenic products that have positive correlations with floor dust which contains bacteria and fungi.

Phenanthrene in PAHs has a moderate positive correlation with gram-positive bacteria, whereas fluoranthene and pyrene have significant positive correlations with gram-negative bacteria.

23

3.

Crawling infants tend to be exposed to floor dust resuspended from carpeted flooring, which produces a concentrated and localised cloud of microbial content.

Carpet flooring has concentrations of Proteobacteria and lower concentrations of Firmicutes.

36



Ventilation Problem

Indoor microorganism is also associated with the lack of ventilation systems, especially in air-conditioned buildings. Improperly designed or operated air-conditioning system within a building can contribute to many microorganisms in the air, which can worsen the indoor environment and threaten occupants’ health37,38.  Lee et al.39 stated that microorganisms could be transferred into the indoor environment due to the air-conditioning system's faulty operation during the maintenance period and the temporary malfunction of the air-conditioning system. Table 4 provides the study cases on the inefficient ventilation system with indoor microbial problems.

Table 4: Studies on Inefficient Ventilation Systems with Indoor Microbial Problems.

No.

Inefficient Ventilation Systems as the Cause of Indoor Microbial Problems in the Built Environment

Dominant Genera

References

1.

Concentrations of bacteria are usually associated with indoor CO2 concentrations, which might be due to human occupancy and lack of a ventilation system.

The dominant indoor fungi are Penicillium and Cladosporium.

22

2.

The growth of fungi on library materials indoors is due to improper dusting, defective air-conditioning system and lack of a ventilation system.

The dominant indoor fungi on the library materials are Eurotium halophilicum.

21

3.

Microbial communities found in the Heating, Ventilation and Air Conditioning (HVAC) filter dust samples are the same in residences’ surface dust.

The amount of Proteobacteria and Gram-positive bacteria present on the HVAC filter dust samples occupied residences, respectively.

40



Humidity/Moisture Surface Problems

Dampness or moisture problems are associated with the growth of indoor microorganisms (i.e. mould exposures) in buildings, with the estimates ranging from 18% to 50%, and these affect human health30,41-45. The relative humidity is one of the environmental factors contributing to airborne microorganisms' vitality with higher bacteria and fungi18. However, humidity with a lower percentage is the limiting factor for indoor microorganisms46,47. The low-moisture condition in the air affects the germination and growth conditions of some fungi rather than bacteria47-49. Dannemiller et al.50 found that bacteria tend to grow at 100% of relative humidity. By contrast, fungi grow at ≥80% in home carpet dust, and this surrounding condition results in a significant increase in microbes’ concentration. Haines et al.51 also reported that fungi could grow at high relative humidity even at short periods. To prevent mould growth, the home relative humidity level must remain below 60%, and proper building maintenance is needed to save occupants’ health51,52.
Besides, microbial growth due to indoor dampness is always associated with building materials. Building materials with high porosity and rough surface (i.e. plasterboard and mortar) and moisture in building materials are favourable to the proliferation and growth of indoor microorganisms. They may cause high exposure to spores, spore fragments, secondary metabolites and cellular microbe components53,54. Generally, fungal growth always gives off an unpleasant odour indoors. Table 5 provides details on how humidity/moisture surface problems influence indoor airborne.

Table 5: Studies on Humidity/Moisture Surface with Indoor Microbial Problems.

No.

Humidity/Moisture Surface Problems causing Indoor Microbial Issues in the Built Environment

Dominant Genera

References

1.

The airflow with moisture intrusion in the wall cavities

The fungal spores are dominated by Aspergillus versicolor, Cladosporium cladosporioides and Penicillium melinii.

30

2.

The increase of respiratory symptoms, asthma and rhinitis and decrease of remission caused by the dampness and mould at home and workplace building

Not available

55



Human Occupancy and Activities

Human occupants are also a prominent source of indoor biological contaminants in the built environment14,22,30,56-59.  Al-Hunaiti et al.23 stated that bacterial and fungal concentrations are lower in the dwelling with a fewer number of occupants and the most recently built.  Noris et al.40 reported a high proportion of gram-positive bacteria in a high group of occupants. Indoor biological contaminants can spread in the built environment through natural shedding, which includes particles directly coming from human bodies (i.e. skin, respiratory tract, hair and nostrils) and clothing2,19,58,60,61 and through resuspension of spores from the room surfaces, whereby the microbial materials that previously settled onto or colonised indoor materials are disturbed by occupants’ movements58,62.  Meadow et al.14 also found that microbes' transmission to indoor surfaces possibly occurs through direct and indirect contact.  Cao et al.63 found that the high indoor biological contaminants in the high occupancy (30 %) compared to low occupancy (10 %) of the older building as shown in Figure 3. Table 6 describes how human occupancy and activities influence indoor microbial problems.
Figure 3: The Higher Indoor Biological Contaminants in the Higher Levels of Human Occupancy in the Older Building Adapted from Cao et al.63.

Click here to view Figure


Table 6: Studies on Human Occupancy and Activities with Indoor Microbial Problems.

No.

Human Occupancy and Activities Causing Indoor Microbial Problems in the Built Environment

Dominant Genera

References

1.

High human occupancy in diverse space types (i.e. classroom) is associated with several bacterial taxa, the human microbiome. By contrast, low human occupancy in various space types influenced by outdoor environments.

Lactobacillus and Staphylococcus are the dominant indoor bacteria, whereas methylobacterium is the dominant outdoor bacterium.

9

2.

The potential interactions between high occupancy and occupant activity with microbial communities in a hospital environment.

Not available

59

3.

Occupancy increases the total aerosol mass and bacterial genome concentration in the particulate matter.

All bacteria in samples of indoor air (17%), floor dust (20%) and ventilation duct supply air (17.5%) are associated with human taxa, which Proprionibacterineae, Staphylococcus, Streptococcus, dominate Enterobacteriaceae and Corynebacterineae.

2



Conclusion

The potential factors that can contribute to the growth of bacteria and fungi (i.e. outdoor air, dust, ventilation problems, humidity/moisture surface problems and human occupancy) should be observed clearly in a building’s characteristics and environment.  The dominant bacteria species found worldwide in various indoor buildings (i.e. schools, cafeterias, mosques, faculties, child day-care centres, hospitals, dwellings, educational buildings, homes, elderly care centres, libraries, restaurants, and factories) was Bacillus spp. (24.1 %), Staphylococcus spp. (20.7 %), and Micrococcus spp. (20.7 %) whereas for fungi species were Penicillium spp. (25.0 %), Cladosporium spp. (21.9 %), and Aspergillus spp. (21.9 %).  Buildings free from bacteria and fungi issues can contribute to a safe environment and protect occupants from poor indoor air quality.

Acknowledgement

The personal EACAR has supported this research to carry out this work.

Funding Source

There is no funding or financial support for this research work.

Conflict of Interest

The authors agree that this research was conducted in the absence of any self-benefits, commercial or financial conflicts and declare absence of conflicting interests with the funders.

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