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Aerobiology (from Greek ἀήρ, aēr, "air"; βίος, bios, "life"; and -λογία, -logia) is a branch of biology that studies the passive transport of organic particles, such as bacteria, fungal spores, very small insects, pollen grains and viruses.[1] Aerobiologists have traditionally been involved in the measurement and reporting of airborne pollen and fungal spores as a service to those with allergies.[1] However, aerobiology is a varied field, relating to environmental science, plant science, meteorology, phenology, and climate change.[2]
Overview
The first mention of "aerobiology" was made by Fred Campbell Meier in the 1930s.[2] The particles, which can be described as Aeroplankton, generally range in size from nanometers to micrometers which makes them challenging to detect.[3]
Aerosolization is the process of a small and light particles becoming suspended in moving air. Now bioaerosols, these pollen and fungal spores can be transported across an ocean, or even travel around the globe.[4] Due to the high quantities of microbes and the ease of dispersion, Martinus Beijerinck once said "Everything is everywhere, the environment selects".[5] This means that aeroplankton are everywhere and have been everywhere, and it solely depends on environmental factors to determine which remain. Aeroplankton are found in significant quantities even in the Atmospheric boundary layer (ABL).[6] The effects on climate and cloud chemistry of these atmospheric populations is still under review.
NASA and other research agencies are studying how long these bioaerosols can remain afloat and how they can survive in such extreme climates. The conditions of the upper atmosphere are similar to the climate on Mars' surface, and the microbes found are helping redefine the conditions which can support life.[7]
Dispersal of particles
The process of dispersal of aerobiological particles has 3 steps: removal from source, dispersion through air, and deposition to rest.[8] The particle geometry and environment affect all three phases, however once it is aerosolized, its fate depends on the laws of physics governing the motion of the air.
Removal from Source
Pollen and spores can be blown from their surface or shaken loose. Generally the wind speed required for release is higher than average wind speed.[8] Rain splatter can also dislodge spores. Some fungi can even be triggered by environmental factors to actively eject spores.[8]
Dispersion through Air
Once released from rest, the aeroplankton is at the mercy of the wind and physics. The settling speed of spores and pollen vary and is a major factor in dispersion; the longer the particle is floating, the longer it can be caught by a turbulent wind gust. Wind speed and direction fluctuate with time and height, so the specific path of once neighboring particles can vary significantly.[8] The concentration of particles in the air decreases with distance from source, and the dispersion distance is most accurately modeled as a power function.[3]
Deposition to Rest
Deposition is a combination of gravity and inertia. The fall speed for small particles can be calculated by mass and geometry, but the complex shapes of pollen and spores often fall slower than their estimated speed modeled with simple shapes.[9] Spores can also be removed from the air from impact; the inertia of the particles will cause them to hit surfaces along their path, instead of flowing around them like air.[8]
Experimental methods
There have been many studies performed to understand real-life dispersal patterns of pollen and spores. To collect samples, studies often use a volumetric spore trap such as a Hirst-type sampler. Particles stick to a sampling strip and then can be inspected under a microscope.[2] Scientists have to count the particles under magnification, and then analyze sample DNA by Amplicon sequence variant (ASV) or another common method.[10]
A challenge repeatedly cited in literature is that because of differing testing or analysis methodologies, results are not always comparable across studies.[5] Therefore, extensive data collection must be performed in each study to get an accurate model. Unfortunately there is no database of aerobiological particle distribution to compare results to.[5]
Effects on human health
Allergic rhinitis is a type of inflammation in the nose that occurs when the immune system overreacts to allergens in the air.[11] It is typically triggered in humans by pollen and other bioaerosols. Between 10% and 30% of people in Western countries are affected.[12] Symptoms are usually worse during pollination periods, when there is significantly more pollen aerosolized in the air.[13] In these peak periods, staying indoors is one way to limit exposure. However, studies have shown that there are still significant levels of pollen indoors. In the winter, pollen levels indoors actually exceed outdoor levels.[13]
Up to date data on pollen levels is critical for humans that have allergies. A current limitation is that many spore traps require scientists to identify and count individual pollen grains under magnification.[10] This causes data to be delayed, sometimes by over a week. There are currently a number of fully automatic spore traps in development, and once they are fully functional they will improve the lives of people with allergies.[10]
Effects of climate change
Scientists have predicted that the meteorological results of climate change will weaken pollen and spore dispersal barriers, and lead to less biological uniqueness in different regions.[4] Precipitation increases richness (number of species) of biodiversity in regions because clouds formulate in the upper atmosphere where there is more varied biodiversity.[4] Specifically in the Arctic, climate change has dramatically increased precipitation, and scientists have seen new microbes in the area because of it.[4]
Rising summer temperatures and CO2 levels have shown to increase total amounts of pollen released by certain trees, as well as delay the start of pollen season.[14] However, more studies are needed to see long term effects of climate change.
References
- ^ a b "Spotlight on: Aerobiology". The Biologist. Royal Society of Biology. Retrieved 26 October 2017.
- ^ a b c Lancia, Andrea; Capone, Pasquale; Vonesch, Nicoletta; Pelliccioni, Armando; Grandi, Carlo; Magri, Donatella; D'Ovidio, Maria Concetta (January 2021). "Research Progress on Aerobiology in the Last 30 Years: A Focus on Methodology and Occupational Health". Sustainability. 13 (8): 4337. doi:10.3390/su13084337. hdl:11573/1540128. ISSN 2071-1050.
- ^ a b Hofmann, Frieder; Otto, Mathias; Wosniok, Werner (17 October 2014). "Maize pollen deposition in relation to distance from the nearest pollen source under common cultivation – results of 10 years of monitoring (2001 to 2010)". Environmental Sciences Europe. 26 (1): 24. doi:10.1186/s12302-014-0024-3. ISSN 2190-4715. S2CID 3924115.
- ^ a b c d Malard, Lucie A.; Avila-Jimenez, Maria-Luisa; Schmale, Julia; Cuthbertson, Lewis; Cockerton, Luke; Pearce, David A. (1 November 2022). "Aerobiology over the Southern Ocean – Implications for bacterial colonization of Antarctica". Environment International. 169: 107492. doi:10.1016/j.envint.2022.107492. ISSN 0160-4120. PMID 36174481.
- ^ a b c Kellogg, Christina A.; Griffin, Dale W. (1 November 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. ISSN 0169-5347. PMID 16843565.
- ^ Archer, Stephen D. J.; Lee, Kevin C.; Caruso, Tancredi; Alcami, Antonio; Araya, Jonathan G.; Cary, S. Craig; Cowan, Don A.; Etchebehere, Claudia; Gantsetseg, Batdelger; Gomez-Silva, Benito; Hartery, Sean; Hogg, Ian D.; Kansour, Mayada K.; Lawrence, Timothy; Lee, Charles K. (1 May 2023). "Contribution of soil bacteria to the atmosphere across biomes". Science of the Total Environment. 871: 162137. doi:10.1016/j.scitotenv.2023.162137. hdl:10486/707035. ISSN 0048-9697. PMID 36775167. S2CID 256776523.
- ^ Tabor, Abigail (19 November 2018). "What is NASA's Aerobiology Lab?". NASA.
- ^ a b c d e McCartney, H. Alastair (April 1994). "Dispersal of spores and pollen from crops". Grana. 33 (2): 76–80. doi:10.1080/00173139409427835. ISSN 0017-3134.
- ^ Sabban, Lilach; van Hout, René (1 December 2011). "Measurements of pollen grain dispersal in still air and stationary, near homogeneous, isotropic turbulence". Journal of Aerosol Science. 42 (12): 867–882. doi:10.1016/j.jaerosci.2011.08.001. ISSN 0021-8502.
- ^ a b c Maya-Manzano, José M.; Tummon, Fiona; Abt, Reto; Allan, Nathan; Bunderson, Landon; Clot, Bernard; Crouzy, Benoît; Daunys, Gintautas; Erb, Sophie; Gonzalez-Alonso, Mónica; Graf, Elias; Grewling, Łukasz; Haus, Jörg; Kadantsev, Evgeny; Kawashima, Shigeto (25 March 2023). "Towards European automatic bioaerosol monitoring: Comparison of 9 automatic pollen observational instruments with classic Hirst-type traps". Science of the Total Environment. 866: 161220. doi:10.1016/j.scitotenv.2022.161220. ISSN 0048-9697. PMID 36584954. S2CID 255251758.
- ^ "Immunotherapy for Environmental Allergies". 17 June 2015. Archived from the original on 17 June 2015. Retrieved 20 April 2023.
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: CS1 maint: bot: original URL status unknown (link) - ^ Wheatley, Lisa M.; Togias, Alkis (29 January 2015). Solomon, Caren G. (ed.). "Allergic Rhinitis". The New England Journal of Medicine. 372 (5): 456–463. doi:10.1056/NEJMcp1412282. ISSN 0028-4793. PMC 4324099. PMID 25629743.
- ^ a b Bastl, Katharina; Berger, Uwe; Kmenta, Maximilian; Weber, Martina (1 October 2017). "Is there an advantage to staying indoors for pollen allergy sufferers? Composition and quantitative aspects of the indoor pollen spectrum". Building and Environment. 123: 78–87. doi:10.1016/j.buildenv.2017.06.040. ISSN 0360-1323.
- ^ López-Orozco, R.; García-Mozo, H.; Oteros, J.; Galán, C. (1 October 2021). "Long-term trends in atmospheric Quercus pollen related to climate change in southern Spain: A 25-year perspective". Atmospheric Environment. 262: 118637. doi:10.1016/j.atmosenv.2021.118637. hdl:10396/22063. ISSN 1352-2310.