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Bioaerosol

April 26, 2024

Bioaerosols (short for biological aerosols) are a subcategory of particles released from terrestrial and marine ecosystems into the atmosphere. They consist of both living and non-living components, such as fungi, pollen, bacteria and viruses.[1] Common sources of bioaerosols include soil, water, and sewage.

Bioaerosols are typically introduced into the air via wind turbulence over a surface. Once in the atmosphere, they can be transported locally or globally: common wind patterns/strengths are responsible for local dispersal, while tropical storms and dust plumes can move bioaerosols between continents.[2] Over ocean surfaces, bioaerosols are generated via sea spray and bubbles.

Bioaerosols can transmit microbial pathogens, endotoxins, and allergens to which humans are sensitive. A well-known case was the meningococcal meningitis outbreak in sub-Saharan Africa, which was linked to dust storms during dry seasons. Other outbreaks linked to dust events including Mycoplasma pneumonia and tuberculosis.[2]

Another instance was an increase in human respiratory problems in the Caribbean that may have been caused by traces of heavy metals, microorganism bioaerosols, and pesticides transported via dust clouds passing over the Atlantic Ocean.

Common bioaerosol isolated from indoor environments

Background edit

Charles Darwin was the first to observe the transport of dust particles[3] but Louis Pasteur was the first to research microbes and their activity within the air. Prior to Pasteur’s work, laboratory cultures were used to grow and isolate different bioaerosols.

Since not all microbes can be cultured, many were undetected before the development of DNA-based tools. Pasteur also developed experimental procedures for sampling bioaerosols and showed that more microbial activity occurred at lower altitudes and decreased at higher altitudes.[2]

Types of bioaerosols edit

Bioaerosols include fungi, bacteria, viruses, and pollen. Their concentrations are greatest in the planetary boundary layer (PBL) and decrease with altitude. Survival rate of bioaerosols depends on a number of biotic and abiotic factors which include climatic conditions, ultraviolet (UV) light, temperature and humidity, as well as resources present within dust or clouds.[4]

Bioaerosols found over marine environments primarily consist of bacteria, while those found over terrestrial environments are rich in bacteria, fungi and pollen.[5] The dominance of particular bacteria and their nutrient sources are subject to change according to time and location.[2]

Bioaerosols can range in size from 10 nanometer virus particles to 100 micrometers pollen grains.[6] Pollen grains are the largest bioaerosols and are less likely to remain suspended in the air over a long period of time due to their weight.[1]

Consequently, pollen particle concentration decreases more rapidly with height than smaller bioaerosols such as bacteria, fungi and possibly viruses, which may be able to survive in the upper troposphere. At present, there is little research on the specific altitude tolerance of different bioaerosols. However, scientists believe that atmospheric turbulence impacts where different bioaerosols may be found.[5]

Fungi edit

Fungal cells usually die when they travel through the atmosphere due to the desiccating effects of higher altitudes. However, some particularly resilient fungal bioaerosols have been shown to survive in atmospheric transport despite exposure to severe UV light conditions.[7] Although bioaerosol levels of fungal spores increase in higher humidity conditions, they can also be active in low humidity conditions and in most temperature ranges. Certain fungal bioaerosols even increase at relatively low levels of humidity.[citation needed]

Bacteria edit

Unlike other bioaerosols, bacteria are able to complete full reproductive cycles within the days or weeks that they survive in the atmosphere, making them a major component of the air biota ecosystem. These reproductive cycles support a currently unproven theory that bacteria bioaerosols form communities in an atmospheric ecosystem.[2] The survival of bacteria depends on water droplets from fog and clouds that provide bacteria with nutrients and protection from UV light.[5] The four known bacterial groupings that are abundant in aeromicrobial environments around the world include Bacillota, Actinomycetota, Pseudomonadota, and Bacteroidota.[8]

Viruses edit

The air transports viruses and other pathogens. Since viruses are smaller than other bioaerosols, they have the potential to travel further distances. In one simulation, a virus and a fungal spore were simultaneously released from the top of a building; the spore traveled only 150 meters while the virus traveled almost 200,000 horizontal kilometers.[5]

In one study, aerosols (<5 μm) containing SARS-CoV-1 and SARS-CoV-2 were generated by an atomizer and fed into a Goldberg drum to create an aerosolized environment. The inoculum yielded cycle thresholds between 20 and 22, similar to those observed in human upper and lower respiratory tract samples. SARS-CoV-2 remained viable in aerosols for 3 hours, with a decrease in infection titre similar to SARS-CoV-1. The half-life of both viruses in aerosols was 1.1 to 1.2 hours on average. The results suggest that the transmission of both viruses by aerosols is plausible, as they can remain viable and infectious in suspended aerosols for hours and on surfaces for up to days.[9]

Pollen edit

Despite being larger and heavier than other bioaerosols, some studies show that pollen can be transported thousands of kilometers.[5] They are a major source of wind-dispersed allergens, coming particularly from seasonal releases from grasses and trees.[1] Tracking distance, transport, resources, and deposition of pollen to terrestrial and marine environments are useful for interpreting pollen records.[1]

Collection edit

The main tools used to collect bioaerosols are collection plates, electrostatic collectors, mass spectrometers, and impactors, other methods are used but are more experimental in nature.[8] Polycarbonate (PC) filters have had the most accurate bacterial sampling success when compared to other PC filter options.[10]

Single-stage impactors edit

To collect bioaerosols falling within a specific size range, impactors can be stacked to capture the variation of particulate matter (PM). For example, a PM10 filter lets smaller sizes pass through. This is similar to the size of a human hair. Particulates are deposited onto the slides, agar plates, or tape at the base of the impactor. The Hirst spore trap samples at 10 liters/minute (LPM) and has a wind vane to always sample in the direction of wind flow. Collected particles are impacted onto a vertical glass slide greased with petroleum.

Variations such as the 7-day recording volumetric spore trap have been designed for continuous sampling using a slowly rotating drum that deposits impacted material onto a coated plastic tape.[11] The airborne bacteria sampler can sample at rates up to 700 LPM, allowing for large samples to be collected in a short sampling time. Biological material is impacted and deposited onto an agar lined Petri dish, allowing cultures to develop.[12]

Cascade impactors edit

Similar to single-stage impactors in collection methods, cascade impactors have multiple size cuts (PM10, PM2.5), allowing for bioaerosols to separate according to size. Separating biological material by aerodynamic diameter is useful due to size ranges being dominated by specific types of organisms (bacteria exist range from 1–20 micrometers and pollen from 10–100 micrometers). The Andersen line of cascade impactors are most widely used to test air particles.[13]

Cyclones edit

A cyclone sampler consists of a circular chamber with the aerosol stream entering through one or more tangential nozzles. Like an impactor, a cyclone sampler depends upon the inertia of the particle to cause it to deposit on the sampler wall as the air stream curves around inside the chamber. Also like an impactor, the collection efficiency depends upon the flow rate. Cyclones are less prone to particle bounce than impactors and can collect larger quantities of material. They also may provide a more gentle collection than impactors, which can improve the recovery of viable microorganisms. However, cyclones tend to have collection efficiency curves that are less sharp than impactors, and it is simpler to design a compact cascade impactor compared to a cascade of cyclone samplers.[14]

Impingers edit

Instead of collecting onto a greased substrate or agar plate, impingers have been developed to impact bioaerosols into liquids, such as deionized water or phosphate buffer solution. Collection efficiencies of impingers are shown by Ehrlich et al. (1966) to be generally higher than similar single stage impactor designs. Commercially available impingers include the AGI-30 (Ace Glass Inc.) and Biosampler (SKC, Inc).

Electrostatic precipitators edit

Electrostatic precipitators, ESPs, have recently gained renewed interest[15] for bioaerosol sampling due to their highly efficient particle removal efficiencies and gentler sampling method as compared with impinging. ESPs charge and remove incoming aerosol particles from an air stream by employing a non-uniform electrostatic field between two electrodes, and a high field strength. This creates a region of high density ions, a corona discharge, which charges incoming aerosol droplets, and the electric field deposits the charges particles onto a collection surface.

Since biological particles are typically analysed using liquid-based assays (PCR, immunoassays, viability assay) it is preferable to sample directly into a liquid volume for downstream analysis. For example, Pardon et al.[16] show sampling of aerosols down to a microfluidic air-liquid interface, and Ladhani et al.,[17] show sampling of airborne Influenza down to a small liquid droplet. The use of low-volume liquids is ideal for minimising sample dilution, and has the potential to be couple to lab-on-chip technologies for rapid point-of-care analysis.

Filters edit

Filters are often used to collect bioaerosols because of their simplicity and low cost. Filter collection is especially useful for personal bioaerosol sampling since they are light and unobtrusive. Filters can be preceded by a size-selective inlet, such as a cyclone or impactor, to remove larger particles and provide size-classification of the bioaerosol particles.[14] Aerosol filters are often described using the term "pore size" or "equivalent pore diameter". Note that the filter pore size does NOT indicate the minimum particle size that will be collected by the filter; in fact, aerosol filters generally will collect particles much smaller than the nominal pore size.[18]

Transport mechanisms edit

Ejection of bioaerosols into the atmosphere edit

Bioaerosols are typically introduced into the air via wind turbulence over a surface. Once airborne they typically remain in the planetary boundary layer (PBL), but in some cases reach the upper troposphere and stratosphere.[19] Once in the atmosphere, they can be transported locally or globally: common wind patterns/strengths are responsible for local dispersal, while tropical storms and dust plumes can move bioaerosols between continents.[2] Over ocean surfaces, bioaerosols are generated via sea spray and bubbles.[5]

Small scale transport via clouds edit

Knowledge of bioaerosols has shaped our understanding of microorganisms and the differentiation between microbes, including airborne pathogens. In the 1970s, a breakthrough occurred in atmospheric physics and microbiology when ice nucleating bacteria were identified.[20]

The highest concentration of bioaerosols is near the Earth’s surface in the PBL. Here wind turbulence causes vertical mixing, bringing particles from the ground into the atmosphere. Bioaerosols introduced to the atmosphere can form clouds, which are then blown to other geographic locations and precipitate out as rain, hail, or snow.[2] Increased levels of bioaerosols have been observed in rain forests during and after rain events. Bacteria and phytoplankton from marine environments have been linked to cloud formation.[1]

However, for this same reason, bioaerosols cannot be transported long distances in the PBL since the clouds will eventually precipitate them out. Furthermore, it would take additional turbulence or convection at the upper limits of the PBL to inject bioaerosols into the troposphere where they may transported larger distances as part of tropospheric flow. This limits the concentration of bioaerosols at these altitudes.[1]

Cloud droplets, ice crystals, and precipitation use bioaerosols as a nucleus where water or crystals can form or hold onto their surface. These interactions show that air particles can change the hydrological cycle, weather conditions, and weathering around the world. Those changes can lead to effects such as desertification which is magnified by climate shifts. Bioaerosols also intermix when pristine air and smog meet, changing visibility and/or air quality.

Large scale transport via dust plumes edit

Satellite images show that storms over Australian, African, and Asian deserts create dust plumes which can carry dust to altitudes of over 5 kilometers above the Earth's surface. This mechanism transports the material thousands of kilometers away, even moving it between continents. Multiple studies have supported the theory that bioaerosols can be carried along with dust.[21][22] One study concluded that a type of airborne bacteria present in a particular desert dust was found at a site 1,000 kilometers downwind.[2]

Possible global scale highways for bioaerosols in dust include:

  • Storms over Northern Africa picking up dust, which can then be blown across the Atlantic to the Americas, or north to Europe. For transatlantic transport, there is a seasonal shift in the destination of the dust: North America during the summer, and South America during the winter.
  • Dust from the Gobi and Taklamakan deserts is transported to North America, mainly during the Northern Hemisphere spring.
  • Dust from Australia is carried out into the Pacific Ocean, with the possibility of being deposited in New Zealand.[22]

Community dispersal edit

Bioaerosol transport and distribution is not consistent around the globe. While bioaerosols may travel thousands of kilometers before deposition, their ultimate distance of travel and direction is dependent on meteorological, physical, and chemical factors. The branch of biology that studies the dispersal of these particles is called Aerobiology. One study generated an airborne bacteria/fungi map of the United States from observational measurements, resulting community profiles of these bioaerosols were connected to soil pH, mean annual precipitation, net primary productivity, and mean annual temperature, among other factors.[23]

Biogeochemical impacts edit

Bioaerosols impact a variety of biogeochemical systems on earth including, but not limited to atmospheric, terrestrial, and marine ecosystems. As long-standing as these relationships are, the topic of bioaerosols is not very well-known.[24][25] Bioaerosols can affect organisms in a multitude of ways including influencing the health of living organisms through allergies, disorders, and disease. Additionally, the distribution of pollen and spore bioaerosols contribute to the genetic diversity of organisms across multiple habitats.[1]

Cloud formation edit

A variety of bioaerosols may contribute to cloud condensation nuclei or cloud ice nuclei, possible bioaerosol components are living or dead cells, cell fragments, hyphae, pollen, or spores.[1] Cloud formation and precipitation are key features of many hydrologic cycles to which ecosystems are tied. In addition, global cloud cover is a significant factor in the overall radiation budget and therefore, temperature of the Earth.

Bioaerosols make up a small fraction of the total cloud condensation nuclei in the atmosphere (between 0.001% and 0.01%) so their global impact (i.e. radiation budget) is questionable. However, there are specific cases where bioaerosols may form a significant fraction of the clouds in an area. These include:

  • Areas where there is cloud formation at temperatures over -15 °C since some bacteria have developed proteins which allow them to nucleate ice at higher temperatures.
  • Areas over vegetated regions or under remote conditions where the air is less impacted by anthropogenic activity.
  • Near surface air in remote marine regions like the Southern Ocean where sea spray may be more prevalent than dust transported from continents.[1]

The collection of bioaerosol particles on a surface is called deposition. The removal of these particles from the atmosphere affects human health in regard to air quality and respiratory systems.[1]

Alpine lakes in Spain edit

Alpine lakes located in the Central Pyrenees region of northeast Spain are unaffected by anthropogenic factors making these oligotrophic lakes ideal indicators for sediment input and environmental change. Dissolved organic matter and nutrients from dust transport can aid bacteria with growth and production in low nutrient waters. Within the collected samples of one study, a high diversity of airborne microorganisms were detected and had strong similarities to Mauritian soils despite Saharan dust storms occurring at the time of detection.[26]

Affected ocean species edit

The types and sizes of bioaerosols vary in marine environments and occur largely because of wet-discharges caused by changes in osmotic pressure or surface tension. Some types of marine originated bioaerosols excrete dry-discharges of fungal spores that are transported by the wind.[1]

One instance of impact on marine species was the 1983 die off of Caribbean sea fans and sea urchins that correlated with dust storms originating in Africa. This correlation was determined by the work of microbiologists and a Total Ozone Mapping Spectrometer, which identified bacteria, viral, and fungal bioaerosols in the dust clouds that were tracked over the Atlantic Ocean.[27] Another instance in of this occurred in 1997 when El Niño possibly impacted seasonal trade wind patterns from Africa to Barbados, resulting in similar die offs. Modeling instances like these can contribute to more accurate predictions of future events.[28]

Spread of diseases edit

The aerosolization of bacteria in dust contributes heavily to the transport of bacterial pathogens. A well-known case of disease outbreak by bioaerosol was the meningococcal meningitis outbreak in sub-Saharan Africa, which was linked to dust storms during dry seasons.

Other outbreaks have been reportedly linked to dust events including Mycoplasma pneumonia and tuberculosis.[2] Another instance of bioaerosol-spread health issues was an increase in human respiratory problems for Caribbean-region residents that may have been caused by traces of heavy metals, microorganism bioaerosols, and pesticides transported via dust clouds passing over the Atlantic Ocean.[27][29]

Common sources of bioaerosols include soil, water, and sewage. Bioaerosols can transmit microbial pathogens, endotoxins, and allergens[30] and can excrete both endotoxins and exotoxins. Exotoxins can be particularly dangerous when transported through the air and distribute pathogens to which humans are sensitive. Cyanobacteria are particularly prolific in their pathogen distribution and are abundant in both terrestrial and aquatic environments.[1]

Future research edit

The potential role of bioaerosols in climate change offers an abundance of research opportunities. Specific areas of study include monitoring bioaerosol impacts on different ecosystems and using meteorological data to forecast ecosystem changes.[5] Determining global interactions is possible through methods like collecting air samples, DNA extraction from bioaerosols, and PCR amplification.[21]

Developing more efficient modelling systems will reduce the spread of human disease and benefit economic and ecologic factors.[2] An atmospheric modeling tool called the Atmospheric Dispersion Modelling System (ADMS 3) is currently in use for this purpose. The ADMS 3 uses computational fluid dynamics (CFD) to locate potential problem areas, minimizing the spread of harmful bioaerosol pathogens include tracking occurrences.[2]

Agroecosystems have an array of potential future research avenues within bioaerosols. Identification of deteriorated soils may identify sources of plant or animal pathogens.

See also edit

References edit

  1. ^ a b c d e f g h i j k l Fröhlich-Nowoisky, Janine; Kampf, Christopher J.; Weber, Bettina; Huffman, J. Alex; Pöhlker, Christopher; Andreae, Meinrat O.; Lang-Yona, Naama; Burrows, Susannah M.; Gunthe, Sachin S. (2016-12-15). "Bioaerosols in the Earth system: Climate, health, and ecosystem interactions". Atmospheric Research. 182: 346–376. Bibcode:2016AtmRe.182..346F. doi:10.1016/j.atmosres.2016.07.018.
  2. ^ a b c d e f g h i j k Smets, Wenke; Moretti, Serena; Denys, Siegfried; Lebeer, Sarah (2016). "Airborne bacteria in the atmosphere: Presence, purpose, and potential". Atmospheric Environment. 139: 214–221. Bibcode:2016AtmEn.139..214S. doi:10.1016/j.atmosenv.2016.05.038.
  3. ^ Darwin, Charles (June 4, 1845). "An account of the Fine Dust which often falls on Vessels in the Atlantic Ocean". Quarterly Journal of the Geological Society. 2 (1–2): 26–30. doi:10.1144/GSL.JGS.1846.002.01-02.09. ISSN 0370-291X. S2CID 131416813.
  4. ^ Acosta-Martínez, V.; Van Pelt, S.; Moore-Kucera, J.; Baddock, M.C.; Zobeck, T.M. (2015). "Microbiology of wind-eroded sediments: Current knowledge and future research directions" (PDF). Aeolian Research. 24 (4): 203. doi:10.1007/s10453-008-9099-x. S2CID 83705988.
  5. ^ a b c d e f g Núñez, Andrés; Amo de Paz, Guillermo; Rastrojo, Alberto; García, Ana M.; Alcamí, Antonio; Gutiérrez-Bustillo, A. Montserrat; Moreno, Diego A. (2016-03-01). "Monitoring of airborne biological particles in outdoor atmosphere. Part 1: Importance, variability and ratios". International Microbiology. 19 (1): 1–13. doi:10.2436/20.1501.01.258. ISSN 1139-6709. PMID 27762424.
  6. ^ Brandl, Helmut; et al. (2008). "Short-Term Dynamic Patterns of Bioaerosol Generation and Displacement in an Indoor Environment" (PDF). Aerobiologia. 24 (4): 203–209. doi:10.1007/s10453-008-9099-x. S2CID 83705988.
  7. ^ Tang, Julian W. (2009-12-06). "The effect of environmental parameters on the survival of airborne infectious agents". Journal of the Royal Society Interface. 6 (Suppl 6): S737–S746. doi:10.1098/rsif.2009.0227.focus. ISSN 1742-5689. PMC 2843949. PMID 19773291.
  8. ^ a b Dasgupta, Purnendu K.; Poruthoor, Simon K. (2002). "Chapter 6 Automated measurement of atmospheric particle composition". Comprehensive Analytical Chemistry. 37: 161–218. doi:10.1016/S0166-526X(02)80043-5. ISBN 978-0444505101 – via ScienceDirect (Elsevier B.V.).
  9. ^ Neeltjevan Doremalen, Dylan H.Morris, Myndi G.Holbrook et al.: Aerosol and Surface Stability of SARS-CoV-2 as Compared with SARS-CoV-1 The New England Journal of Medicine, April 2020.
  10. ^ Wang, Chi-Hsun; Chen, Bean T; Han, Bor-Cheng; Liu, Andrew Chi-Yeu; Hung, Po-Chen; Chen, Chih-Yong; Chao, Hsing Jasmine (2015). "Field evaluation of personal sampling methods for multiple bioaerosols". PLOS ONE. 10 (3): e0120308. Bibcode:2015PLoSO..1020308W. doi:10.1371/journal.pone.0120308. PMC 4370695. PMID 25799419.
  11. ^ . www.burkard.co.uk. Archived from the original on 2016-10-17. Retrieved 2017-03-15.
  12. ^ Vincent, James H. (2007). Aerosol Sampling: Science, Standards, Instrumentation and Applications. John Wiley & Sons. ISBN 978-0470060223.
  13. ^ "Andersen Cascade Impactor (ACI)". www.copleyscientific.com.
  14. ^ a b William G. Lindsley; Brett J. Green; Francoise M. Blachere; Stephen B. Martin; Brandon F. Law; Paul A. Jensen; Millie P. Schafer (March 2017). "Sampling and characterization of bioaerosols" (PDF). NIOSH Manual of Analytical Methods. Retrieved March 28, 2018.
  15. ^ Mainelis, Gediminas; Willeke, Klaus; Adhikari, Atin; Reponen, Tiina; Grinshpun, Sergey A. (2002-11-01). "Design and Collection Efficiency of a New Electrostatic Precipitator for Bioaerosol Collection". Aerosol Science and Technology. 36 (11): 1073–1085. Bibcode:2002AerST..36.1073M. doi:10.1080/02786820290092212. ISSN 0278-6826. S2CID 97556443.
  16. ^ Pardon, Gaspard; Ladhani, Laila; Sandström, Niklas; Ettori, Maxime; Lobov, Gleb; van der Wijngaart, Wouter (2015-06-01). "Aerosol sampling using an electrostatic precipitator integrated with a microfluidic interface". Sensors and Actuators B: Chemical. 212: 344–352. doi:10.1016/j.snb.2015.02.008.
  17. ^ Ladhani, Laila; Pardon, Gaspard; Meeuws, Hanne; Wesenbeeck, Liesbeth van; Schmidt, Kristiane; Stuyver, Lieven; Wijngaart, Wouter van der (2017-03-28). "Sampling and detection of airborne influenza virus towards point-of-care applications". PLOS ONE. 12 (3): e0174314. Bibcode:2017PLoSO..1274314L. doi:10.1371/journal.pone.0174314. ISSN 1932-6203. PMC 5369763. PMID 28350811.
  18. ^ "Filter pore size and aerosol sample collection" (PDF). NIOSH Manual of Analytical Methods. April 2016. Retrieved April 2, 2018.
  19. ^ Smith, David J.; Thakrar, Prital J.; Bharrat, Anthony E.; Dokos, Adam G.; Kinney, Teresa L.; James, Leandro M.; Lane, Michael A.; Khodadad, Christina L.; Maguire, Finlay (2014-12-31). "A Balloon-Based Payload for Exposing Microorganisms in the Stratosphere (E-MIST)". Gravitational and Space Research. 2 (2): 70–80. doi:10.2478/gsr-2014-0019. ISSN 2332-7774. S2CID 130076615.
  20. ^ Christner, Brent C. (2012). "Cloudy with a Chance of Microbes: Terrestrial microbes swept into clouds can catalyze the freezing of water and may influence precipitation on a global scale". Microbe.
  21. ^ a b Smith, David J.; Timonen, Hilkka J.; Jaffe, Daniel A.; Griffin, Dale W; Birmele, Michele N.; Perry, Kevin D; Ward, Peter D.; Roberts, Michael S. (2013). "Intercontinental Dispersal of Bacteria and Archaea by Transpacific Winds". Applied and Environmental Microbiology. 79 (4): 1134–1139. Bibcode:2013ApEnM..79.1134S. doi:10.1128/aem.03029-12. PMC 3568602. PMID 23220959.
  22. ^ a b Kellogg, Christina A.; Griffin, Dale W. (2006). "Aerobiology and the global transport of desert dust". Trends in Ecology & Evolution. 21 (11): 638–644. doi:10.1016/j.tree.2006.07.004. PMID 16843565.
  23. ^ Barberán, Albert; Ladau, Joshua; Leff, Jonathan W.; Pollard, Katherine S.; Menninger, Holly L.; Dunn, Robert R.; Fierer, Noah (2015-05-05). "Continental-scale distributions of dust-associated bacteria and fungi". Proceedings of the National Academy of Sciences of the United States of America. 112 (18): 5756–5761. Bibcode:2015PNAS..112.5756B. doi:10.1073/pnas.1420815112. ISSN 1091-6490. PMC 4426398. PMID 25902536.
  24. ^ Crutzen, Paul J.; Stoermer, Eugene F. (2000). "The "Anthropocene"". International Geosphere–Biosphere Programme Global Change Newsletter.
  25. ^ Crutzen, Paul J. (2002-01-03). "Geology of mankind". Nature. 415 (6867): 23. Bibcode:2002Natur.415...23C. doi:10.1038/415023a. ISSN 0028-0836. PMID 11780095. S2CID 9743349.
  26. ^ Barberán, Albert; Henley, Jessica; Fierer, Noah; Casamayor, Emilio O. (2014-07-15). "Structure, inter-annual recurrence, and global-scale connectivity of airborne microbial communities". Science of the Total Environment. 487: 187–195. Bibcode:2014ScTEn.487..187B. doi:10.1016/j.scitotenv.2014.04.030. PMID 24784743.
  27. ^ a b J., Schmidt, Laurie (2001-05-18). "When the Dust Settles : Feature Articles". earthobservatory.nasa.gov.{{cite web}}: CS1 maint: multiple names: authors list (link)
  28. ^ Prospero, Joseph M.; Blades, Edmund; Mathison, George; Naidu, Raana (2005). "Interhemispheric transport of viable fungi and bacteria from Africa to the Caribbean with soil dust" (PDF). Aerobiologia. 21: 1–19. doi:10.1007/s10453-004-5872-7. S2CID 16644704.
  29. ^ "African dust clouds worry Caribbean scientists". Jamaica Observer.
  30. ^ Pillai, Suresh D; Ricke, Steven C (2002). "Bioaerosols from municipal and animal wastes: background and contemporary issues". Canadian Journal of Microbiology. 48 (8): 681–696. doi:10.1139/w02-070. PMID 12381025.

External links edit

  • Aeromicrobiology, MicrobeWiki
  • Bioaerosols and OSH, OSHWIKI
  • Rutgers University Project
  • Sampling and characterization of bioaerosols, NIOSH Manual of Analytical Methods
  • Dunning, Brian (November 24, 2015). "Skeptoid #494: Black Mold: Peril or Prosaic?". Skeptoid.

April 26, 2024
bioaerosol, short, biological, aerosols, subcategory, particles, released, from, terrestrial, marine, ecosystems, into, atmosphere, they, consist, both, living, living, components, such, fungi, pollen, bacteria, viruses, common, sources, bioaerosols, include, . Bioaerosols short for biological aerosols are a subcategory of particles released from terrestrial and marine ecosystems into the atmosphere They consist of both living and non living components such as fungi pollen bacteria and viruses 1 Common sources of bioaerosols include soil water and sewage Bioaerosols are typically introduced into the air via wind turbulence over a surface Once in the atmosphere they can be transported locally or globally common wind patterns strengths are responsible for local dispersal while tropical storms and dust plumes can move bioaerosols between continents 2 Over ocean surfaces bioaerosols are generated via sea spray and bubbles Bioaerosols can transmit microbial pathogens endotoxins and allergens to which humans are sensitive A well known case was the meningococcal meningitis outbreak in sub Saharan Africa which was linked to dust storms during dry seasons Other outbreaks linked to dust events including Mycoplasma pneumonia and tuberculosis 2 Another instance was an increase in human respiratory problems in the Caribbean that may have been caused by traces of heavy metals microorganism bioaerosols and pesticides transported via dust clouds passing over the Atlantic Ocean Common bioaerosol isolated from indoor environments Contents 1 Background 2 Types of bioaerosols 2 1 Fungi 2 2 Bacteria 2 3 Viruses 2 4 Pollen 3 Collection 3 1 Single stage impactors 3 2 Cascade impactors 3 3 Cyclones 3 4 Impingers 3 5 Electrostatic precipitators 3 6 Filters 4 Transport mechanisms 4 1 Ejection of bioaerosols into the atmosphere 4 2 Small scale transport via clouds 4 3 Large scale transport via dust plumes 4 4 Community dispersal 5 Biogeochemical impacts 5 1 Cloud formation 5 2 Alpine lakes in Spain 5 3 Affected ocean species 6 Spread of diseases 7 Future research 8 See also 9 References 10 External linksBackground editCharles Darwin was the first to observe the transport of dust particles 3 but Louis Pasteur was the first to research microbes and their activity within the air Prior to Pasteur s work laboratory cultures were used to grow and isolate different bioaerosols Since not all microbes can be cultured many were undetected before the development of DNA based tools Pasteur also developed experimental procedures for sampling bioaerosols and showed that more microbial activity occurred at lower altitudes and decreased at higher altitudes 2 Types of bioaerosols editBioaerosols include fungi bacteria viruses and pollen Their concentrations are greatest in the planetary boundary layer PBL and decrease with altitude Survival rate of bioaerosols depends on a number of biotic and abiotic factors which include climatic conditions ultraviolet UV light temperature and humidity as well as resources present within dust or clouds 4 Bioaerosols found over marine environments primarily consist of bacteria while those found over terrestrial environments are rich in bacteria fungi and pollen 5 The dominance of particular bacteria and their nutrient sources are subject to change according to time and location 2 Bioaerosols can range in size from 10 nanometer virus particles to 100 micrometers pollen grains 6 Pollen grains are the largest bioaerosols and are less likely to remain suspended in the air over a long period of time due to their weight 1 Consequently pollen particle concentration decreases more rapidly with height than smaller bioaerosols such as bacteria fungi and possibly viruses which may be able to survive in the upper troposphere At present there is little research on the specific altitude tolerance of different bioaerosols However scientists believe that atmospheric turbulence impacts where different bioaerosols may be found 5 Fungi edit Fungal cells usually die when they travel through the atmosphere due to the desiccating effects of higher altitudes However some particularly resilient fungal bioaerosols have been shown to survive in atmospheric transport despite exposure to severe UV light conditions 7 Although bioaerosol levels of fungal spores increase in higher humidity conditions they can also be active in low humidity conditions and in most temperature ranges Certain fungal bioaerosols even increase at relatively low levels of humidity citation needed Bacteria edit Unlike other bioaerosols bacteria are able to complete full reproductive cycles within the days or weeks that they survive in the atmosphere making them a major component of the air biota ecosystem These reproductive cycles support a currently unproven theory that bacteria bioaerosols form communities in an atmospheric ecosystem 2 The survival of bacteria depends on water droplets from fog and clouds that provide bacteria with nutrients and protection from UV light 5 The four known bacterial groupings that are abundant in aeromicrobial environments around the world include Bacillota Actinomycetota Pseudomonadota and Bacteroidota 8 Viruses edit The air transports viruses and other pathogens Since viruses are smaller than other bioaerosols they have the potential to travel further distances In one simulation a virus and a fungal spore were simultaneously released from the top of a building the spore traveled only 150 meters while the virus traveled almost 200 000 horizontal kilometers 5 In one study aerosols lt 5 mm containing SARS CoV 1 and SARS CoV 2 were generated by an atomizer and fed into a Goldberg drum to create an aerosolized environment The inoculum yielded cycle thresholds between 20 and 22 similar to those observed in human upper and lower respiratory tract samples SARS CoV 2 remained viable in aerosols for 3 hours with a decrease in infection titre similar to SARS CoV 1 The half life of both viruses in aerosols was 1 1 to 1 2 hours on average The results suggest that the transmission of both viruses by aerosols is plausible as they can remain viable and infectious in suspended aerosols for hours and on surfaces for up to days 9 Pollen edit Despite being larger and heavier than other bioaerosols some studies show that pollen can be transported thousands of kilometers 5 They are a major source of wind dispersed allergens coming particularly from seasonal releases from grasses and trees 1 Tracking distance transport resources and deposition of pollen to terrestrial and marine environments are useful for interpreting pollen records 1 Collection editThe main tools used to collect bioaerosols are collection plates electrostatic collectors mass spectrometers and impactors other methods are used but are more experimental in nature 8 Polycarbonate PC filters have had the most accurate bacterial sampling success when compared to other PC filter options 10 Single stage impactors edit To collect bioaerosols falling within a specific size range impactors can be stacked to capture the variation of particulate matter PM For example a PM10 filter lets smaller sizes pass through This is similar to the size of a human hair Particulates are deposited onto the slides agar plates or tape at the base of the impactor The Hirst spore trap samples at 10 liters minute LPM and has a wind vane to always sample in the direction of wind flow Collected particles are impacted onto a vertical glass slide greased with petroleum Variations such as the 7 day recording volumetric spore trap have been designed for continuous sampling using a slowly rotating drum that deposits impacted material onto a coated plastic tape 11 The airborne bacteria sampler can sample at rates up to 700 LPM allowing for large samples to be collected in a short sampling time Biological material is impacted and deposited onto an agar lined Petri dish allowing cultures to develop 12 Cascade impactors edit Similar to single stage impactors in collection methods cascade impactors have multiple size cuts PM10 PM2 5 allowing for bioaerosols to separate according to size Separating biological material by aerodynamic diameter is useful due to size ranges being dominated by specific types of organisms bacteria exist range from 1 20 micrometers and pollen from 10 100 micrometers The Andersen line of cascade impactors are most widely used to test air particles 13 Cyclones edit A cyclone sampler consists of a circular chamber with the aerosol stream entering through one or more tangential nozzles Like an impactor a cyclone sampler depends upon the inertia of the particle to cause it to deposit on the sampler wall as the air stream curves around inside the chamber Also like an impactor the collection efficiency depends upon the flow rate Cyclones are less prone to particle bounce than impactors and can collect larger quantities of material They also may provide a more gentle collection than impactors which can improve the recovery of viable microorganisms However cyclones tend to have collection efficiency curves that are less sharp than impactors and it is simpler to design a compact cascade impactor compared to a cascade of cyclone samplers 14 Impingers edit Instead of collecting onto a greased substrate or agar plate impingers have been developed to impact bioaerosols into liquids such as deionized water or phosphate buffer solution Collection efficiencies of impingers are shown by Ehrlich et al 1966 to be generally higher than similar single stage impactor designs Commercially available impingers include the AGI 30 Ace Glass Inc and Biosampler SKC Inc Electrostatic precipitators edit Electrostatic precipitators ESPs have recently gained renewed interest 15 for bioaerosol sampling due to their highly efficient particle removal efficiencies and gentler sampling method as compared with impinging ESPs charge and remove incoming aerosol particles from an air stream by employing a non uniform electrostatic field between two electrodes and a high field strength This creates a region of high density ions a corona discharge which charges incoming aerosol droplets and the electric field deposits the charges particles onto a collection surface Since biological particles are typically analysed using liquid based assays PCR immunoassays viability assay it is preferable to sample directly into a liquid volume for downstream analysis For example Pardon et al 16 show sampling of aerosols down to a microfluidic air liquid interface and Ladhani et al 17 show sampling of airborne Influenza down to a small liquid droplet The use of low volume liquids is ideal for minimising sample dilution and has the potential to be couple to lab on chip technologies for rapid point of care analysis Filters edit Filters are often used to collect bioaerosols because of their simplicity and low cost Filter collection is especially useful for personal bioaerosol sampling since they are light and unobtrusive Filters can be preceded by a size selective inlet such as a cyclone or impactor to remove larger particles and provide size classification of the bioaerosol particles 14 Aerosol filters are often described using the term pore size or equivalent pore diameter Note that the filter pore size does NOT indicate the minimum particle size that will be collected by the filter in fact aerosol filters generally will collect particles much smaller than the nominal pore size 18 Transport mechanisms editEjection of bioaerosols into the atmosphere edit Bioaerosols are typically introduced into the air via wind turbulence over a surface Once airborne they typically remain in the planetary boundary layer PBL but in some cases reach the upper troposphere and stratosphere 19 Once in the atmosphere they can be transported locally or globally common wind patterns strengths are responsible for local dispersal while tropical storms and dust plumes can move bioaerosols between continents 2 Over ocean surfaces bioaerosols are generated via sea spray and bubbles 5 Small scale transport via clouds edit Knowledge of bioaerosols has shaped our understanding of microorganisms and the differentiation between microbes including airborne pathogens In the 1970s a breakthrough occurred in atmospheric physics and microbiology when ice nucleating bacteria were identified 20 The highest concentration of bioaerosols is near the Earth s surface in the PBL Here wind turbulence causes vertical mixing bringing particles from the ground into the atmosphere Bioaerosols introduced to the atmosphere can form clouds which are then blown to other geographic locations and precipitate out as rain hail or snow 2 Increased levels of bioaerosols have been observed in rain forests during and after rain events Bacteria and phytoplankton from marine environments have been linked to cloud formation 1 However for this same reason bioaerosols cannot be transported long distances in the PBL since the clouds will eventually precipitate them out Furthermore it would take additional turbulence or convection at the upper limits of the PBL to inject bioaerosols into the troposphere where they may transported larger distances as part of tropospheric flow This limits the concentration of bioaerosols at these altitudes 1 Cloud droplets ice crystals and precipitation use bioaerosols as a nucleus where water or crystals can form or hold onto their surface These interactions show that air particles can change the hydrological cycle weather conditions and weathering around the world Those changes can lead to effects such as desertification which is magnified by climate shifts Bioaerosols also intermix when pristine air and smog meet changing visibility and or air quality Large scale transport via dust plumes edit Satellite images show that storms over Australian African and Asian deserts create dust plumes which can carry dust to altitudes of over 5 kilometers above the Earth s surface This mechanism transports the material thousands of kilometers away even moving it between continents Multiple studies have supported the theory that bioaerosols can be carried along with dust 21 22 One study concluded that a type of airborne bacteria present in a particular desert dust was found at a site 1 000 kilometers downwind 2 Possible global scale highways for bioaerosols in dust include Storms over Northern Africa picking up dust which can then be blown across the Atlantic to the Americas or north to Europe For transatlantic transport there is a seasonal shift in the destination of the dust North America during the summer and South America during the winter Dust from the Gobi and Taklamakan deserts is transported to North America mainly during the Northern Hemisphere spring Dust from Australia is carried out into the Pacific Ocean with the possibility of being deposited in New Zealand 22 Community dispersal edit Bioaerosol transport and distribution is not consistent around the globe While bioaerosols may travel thousands of kilometers before deposition their ultimate distance of travel and direction is dependent on meteorological physical and chemical factors The branch of biology that studies the dispersal of these particles is called Aerobiology One study generated an airborne bacteria fungi map of the United States from observational measurements resulting community profiles of these bioaerosols were connected to soil pH mean annual precipitation net primary productivity and mean annual temperature among other factors 23 Biogeochemical impacts editBioaerosols impact a variety of biogeochemical systems on earth including but not limited to atmospheric terrestrial and marine ecosystems As long standing as these relationships are the topic of bioaerosols is not very well known 24 25 Bioaerosols can affect organisms in a multitude of ways including influencing the health of living organisms through allergies disorders and disease Additionally the distribution of pollen and spore bioaerosols contribute to the genetic diversity of organisms across multiple habitats 1 Cloud formation edit A variety of bioaerosols may contribute to cloud condensation nuclei or cloud ice nuclei possible bioaerosol components are living or dead cells cell fragments hyphae pollen or spores 1 Cloud formation and precipitation are key features of many hydrologic cycles to which ecosystems are tied In addition global cloud cover is a significant factor in the overall radiation budget and therefore temperature of the Earth Bioaerosols make up a small fraction of the total cloud condensation nuclei in the atmosphere between 0 001 and 0 01 so their global impact i e radiation budget is questionable However there are specific cases where bioaerosols may form a significant fraction of the clouds in an area These include Areas where there is cloud formation at temperatures over 15 C since some bacteria have developed proteins which allow them to nucleate ice at higher temperatures Areas over vegetated regions or under remote conditions where the air is less impacted by anthropogenic activity Near surface air in remote marine regions like the Southern Ocean where sea spray may be more prevalent than dust transported from continents 1 The collection of bioaerosol particles on a surface is called deposition The removal of these particles from the atmosphere affects human health in regard to air quality and respiratory systems 1 Alpine lakes in Spain edit Alpine lakes located in the Central Pyrenees region of northeast Spain are unaffected by anthropogenic factors making these oligotrophic lakes ideal indicators for sediment input and environmental change Dissolved organic matter and nutrients from dust transport can aid bacteria with growth and production in low nutrient waters Within the collected samples of one study a high diversity of airborne microorganisms were detected and had strong similarities to Mauritian soils despite Saharan dust storms occurring at the time of detection 26 Affected ocean species edit The types and sizes of bioaerosols vary in marine environments and occur largely because of wet discharges caused by changes in osmotic pressure or surface tension Some types of marine originated bioaerosols excrete dry discharges of fungal spores that are transported by the wind 1 One instance of impact on marine species was the 1983 die off of Caribbean sea fans and sea urchins that correlated with dust storms originating in Africa This correlation was determined by the work of microbiologists and a Total Ozone Mapping Spectrometer which identified bacteria viral and fungal bioaerosols in the dust clouds that were tracked over the Atlantic Ocean 27 Another instance in of this occurred in 1997 when El Nino possibly impacted seasonal trade wind patterns from Africa to Barbados resulting in similar die offs Modeling instances like these can contribute to more accurate predictions of future events 28 Spread of diseases editThe aerosolization of bacteria in dust contributes heavily to the transport of bacterial pathogens A well known case of disease outbreak by bioaerosol was the meningococcal meningitis outbreak in sub Saharan Africa which was linked to dust storms during dry seasons Other outbreaks have been reportedly linked to dust events including Mycoplasma pneumonia and tuberculosis 2 Another instance of bioaerosol spread health issues was an increase in human respiratory problems for Caribbean region residents that may have been caused by traces of heavy metals microorganism bioaerosols and pesticides transported via dust clouds passing over the Atlantic Ocean 27 29 Common sources of bioaerosols include soil water and sewage Bioaerosols can transmit microbial pathogens endotoxins and allergens 30 and can excrete both endotoxins and exotoxins Exotoxins can be particularly dangerous when transported through the air and distribute pathogens to which humans are sensitive Cyanobacteria are particularly prolific in their pathogen distribution and are abundant in both terrestrial and aquatic environments 1 Future research editThe potential role of bioaerosols in climate change offers an abundance of research opportunities Specific areas of study include monitoring bioaerosol impacts on different ecosystems and using meteorological data to forecast ecosystem changes 5 Determining global interactions is possible through methods like collecting air samples DNA extraction from bioaerosols and PCR amplification 21 Developing more efficient modelling systems will reduce the spread of human disease and benefit economic and ecologic factors 2 An atmospheric modeling tool called the Atmospheric Dispersion Modelling System ADMS 3 is currently in use for this purpose The ADMS 3 uses computational fluid dynamics CFD to locate potential problem areas minimizing the spread of harmful bioaerosol pathogens include tracking occurrences 2 Agroecosystems have an array of potential future research avenues within bioaerosols Identification of deteriorated soils may identify sources of plant or animal pathogens See also editMycotoxin Indoor air quality Indoor bioaerosol Mold growth assessment and remediation Mold health issues Sick building syndromeReferences edit a b c d e f g h i j k l Frohlich Nowoisky Janine Kampf Christopher J Weber Bettina Huffman J Alex Pohlker Christopher Andreae Meinrat O Lang Yona Naama Burrows Susannah M Gunthe Sachin S 2016 12 15 Bioaerosols in the Earth system Climate health and ecosystem interactions Atmospheric Research 182 346 376 Bibcode 2016AtmRe 182 346F doi 10 1016 j atmosres 2016 07 018 a b c d e f g h i j k Smets Wenke Moretti Serena Denys Siegfried Lebeer Sarah 2016 Airborne bacteria in the atmosphere Presence purpose and potential Atmospheric Environment 139 214 221 Bibcode 2016AtmEn 139 214S doi 10 1016 j atmosenv 2016 05 038 Darwin Charles June 4 1845 An account of the Fine Dust which often falls on Vessels in the Atlantic Ocean Quarterly Journal of the Geological Society 2 1 2 26 30 doi 10 1144 GSL JGS 1846 002 01 02 09 ISSN 0370 291X S2CID 131416813 Acosta Martinez V Van Pelt S Moore Kucera J Baddock M C Zobeck T M 2015 Microbiology of wind eroded sediments Current knowledge and future research directions PDF Aeolian Research 24 4 203 doi 10 1007 s10453 008 9099 x S2CID 83705988 a b c d e f g Nunez Andres Amo de Paz Guillermo Rastrojo Alberto Garcia Ana M Alcami Antonio Gutierrez Bustillo A Montserrat Moreno Diego A 2016 03 01 Monitoring of airborne biological particles in outdoor atmosphere Part 1 Importance variability and ratios International Microbiology 19 1 1 13 doi 10 2436 20 1501 01 258 ISSN 1139 6709 PMID 27762424 Brandl Helmut et al 2008 Short Term Dynamic Patterns of Bioaerosol Generation and Displacement in an Indoor Environment PDF Aerobiologia 24 4 203 209 doi 10 1007 s10453 008 9099 x S2CID 83705988 Tang Julian W 2009 12 06 The effect of environmental parameters on the survival of airborne infectious agents Journal of the Royal Society Interface 6 Suppl 6 S737 S746 doi 10 1098 rsif 2009 0227 focus ISSN 1742 5689 PMC 2843949 PMID 19773291 a b Dasgupta Purnendu K Poruthoor Simon K 2002 Chapter 6 Automated measurement of atmospheric particle composition Comprehensive Analytical Chemistry 37 161 218 doi 10 1016 S0166 526X 02 80043 5 ISBN 978 0444505101 via ScienceDirect Elsevier B V Neeltjevan Doremalen Dylan H Morris Myndi G Holbrook et al Aerosol and Surface Stability of SARS CoV 2 as Compared with SARS CoV 1 The New England Journal of Medicine April 2020 Wang Chi Hsun Chen Bean T Han Bor Cheng Liu Andrew Chi Yeu Hung Po Chen Chen Chih Yong Chao Hsing Jasmine 2015 Field evaluation of personal sampling methods for multiple bioaerosols PLOS ONE 10 3 e0120308 Bibcode 2015PLoSO 1020308W doi 10 1371 journal pone 0120308 PMC 4370695 PMID 25799419 Mycological Entomological Instruments and Apparatus www burkard co uk Archived from the original on 2016 10 17 Retrieved 2017 03 15 Vincent James H 2007 Aerosol Sampling Science Standards Instrumentation and Applications John Wiley amp Sons ISBN 978 0470060223 Andersen Cascade Impactor ACI www copleyscientific com a b William G Lindsley Brett J Green Francoise M Blachere Stephen B Martin Brandon F Law Paul A Jensen Millie P Schafer March 2017 Sampling and characterization of bioaerosols PDF NIOSH Manual of Analytical Methods Retrieved March 28 2018 Mainelis Gediminas Willeke Klaus Adhikari Atin Reponen Tiina Grinshpun Sergey A 2002 11 01 Design and Collection Efficiency of a New Electrostatic Precipitator for Bioaerosol Collection Aerosol Science and Technology 36 11 1073 1085 Bibcode 2002AerST 36 1073M doi 10 1080 02786820290092212 ISSN 0278 6826 S2CID 97556443 Pardon Gaspard Ladhani Laila Sandstrom Niklas Ettori Maxime Lobov Gleb van der Wijngaart Wouter 2015 06 01 Aerosol sampling using an electrostatic precipitator integrated with a microfluidic interface Sensors and Actuators B Chemical 212 344 352 doi 10 1016 j snb 2015 02 008 Ladhani Laila Pardon Gaspard Meeuws Hanne Wesenbeeck Liesbeth van Schmidt Kristiane Stuyver Lieven Wijngaart Wouter van der 2017 03 28 Sampling and detection of airborne influenza virus towards point of care applications PLOS ONE 12 3 e0174314 Bibcode 2017PLoSO 1274314L doi 10 1371 journal pone 0174314 ISSN 1932 6203 PMC 5369763 PMID 28350811 Filter pore size and aerosol sample collection PDF NIOSH Manual of Analytical Methods April 2016 Retrieved April 2 2018 Smith David J Thakrar Prital J Bharrat Anthony E Dokos Adam G Kinney Teresa L James Leandro M Lane Michael A Khodadad Christina L Maguire Finlay 2014 12 31 A Balloon Based Payload for Exposing Microorganisms in the Stratosphere E MIST Gravitational and Space Research 2 2 70 80 doi 10 2478 gsr 2014 0019 ISSN 2332 7774 S2CID 130076615 Christner Brent C 2012 Cloudy with a Chance of Microbes Terrestrial microbes swept into clouds can catalyze the freezing of water and may influence precipitation on a global scale Microbe a b Smith David J Timonen Hilkka J Jaffe Daniel A Griffin Dale W Birmele Michele N Perry Kevin D Ward Peter D Roberts Michael S 2013 Intercontinental Dispersal of Bacteria and Archaea by Transpacific Winds Applied and Environmental Microbiology 79 4 1134 1139 Bibcode 2013ApEnM 79 1134S doi 10 1128 aem 03029 12 PMC 3568602 PMID 23220959 a b Kellogg Christina A Griffin Dale W 2006 Aerobiology and the global transport of desert dust Trends in Ecology amp Evolution 21 11 638 644 doi 10 1016 j tree 2006 07 004 PMID 16843565 Barberan Albert Ladau Joshua Leff Jonathan W Pollard Katherine S Menninger Holly L Dunn Robert R Fierer Noah 2015 05 05 Continental scale distributions of dust associated bacteria and fungi Proceedings of the National Academy of Sciences of the United States of America 112 18 5756 5761 Bibcode 2015PNAS 112 5756B doi 10 1073 pnas 1420815112 ISSN 1091 6490 PMC 4426398 PMID 25902536 Crutzen Paul J Stoermer Eugene F 2000 The Anthropocene International Geosphere Biosphere Programme Global Change Newsletter Crutzen Paul J 2002 01 03 Geology of mankind Nature 415 6867 23 Bibcode 2002Natur 415 23C doi 10 1038 415023a ISSN 0028 0836 PMID 11780095 S2CID 9743349 Barberan Albert Henley Jessica Fierer Noah Casamayor Emilio O 2014 07 15 Structure inter annual recurrence and global scale connectivity of airborne microbial communities Science of the Total Environment 487 187 195 Bibcode 2014ScTEn 487 187B doi 10 1016 j scitotenv 2014 04 030 PMID 24784743 a b J Schmidt Laurie 2001 05 18 When the Dust Settles Feature Articles earthobservatory nasa gov a href Template Cite web html title Template Cite web cite web a CS1 maint multiple names authors list link Prospero Joseph M Blades Edmund Mathison George Naidu Raana 2005 Interhemispheric transport of viable fungi and bacteria from Africa to the Caribbean with soil dust PDF Aerobiologia 21 1 19 doi 10 1007 s10453 004 5872 7 S2CID 16644704 African dust clouds worry Caribbean scientists Jamaica Observer Pillai Suresh D Ricke Steven C 2002 Bioaerosols from municipal and animal wastes background and contemporary issues Canadian Journal of Microbiology 48 8 681 696 doi 10 1139 w02 070 PMID 12381025 External links editAeromicrobiology MicrobeWiki Bioaerosols and OSH OSHWIKI Rutgers University Project Sampling and characterization of bioaerosols NIOSH Manual of Analytical Methods Dunning Brian November 24 2015 Skeptoid 494 Black Mold Peril or Prosaic Skeptoid Retrieved from https en wikipedia org w index php title Bioaerosol amp oldid 1215439566, wikipedia, wiki, book, books, library,

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