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Bioindicator

August 21, 2023

A bioindicator is any species (an indicator species) or group of species whose function, population, or status can reveal the qualitative status of the environment. The most common indicator species are animals.[2] For example, copepods and other small water crustaceans that are present in many water bodies can be monitored for changes (biochemical, physiological, or behavioural) that may indicate a problem within their ecosystem. Bioindicators can tell us about the cumulative effects of different pollutants in the ecosystem and about how long a problem may have been present, which physical and chemical testing cannot.[3]

Caddisfly (order Trichoptera), a macroinvertebrate used as an indicator of water quality.[1]

A biological monitor or biomonitor is an organism that provides quantitative information on the quality of the environment around it.[4] Therefore, a good biomonitor will indicate the presence of the pollutant and can also be used in an attempt to provide additional information about the amount and intensity of the exposure.

A biological indicator is also the name given to a process for assessing the sterility of an environment through the use of resistant microorganism strains (e.g. Bacillus or Geobacillus).[5] Biological indicators can be described as the introduction of a highly resistant microorganisms to a given environment before sterilization, tests are conducted to measure the effectiveness of the sterilization processes. As biological indicators use highly resistant microorganisms, any sterilization process that renders them inactive will have also killed off more common, weaker pathogens.

Overview

A bioindicator is an organism or biological response that reveals the presence of pollutants by the occurrence of typical symptoms or measurable responses and is, therefore, more qualitative. These organisms (or communities of organisms) can be used to deliver information on alterations in the environment or the quantity of environmental pollutants by changing in one of the following ways: physiologically, chemically or behaviourally. The information can be deduced through the study of:

  1. their content of certain elements or compounds
  2. their morphological or cellular structure
  3. metabolic biochemical processes
  4. behaviour
  5. population structure(s).

The importance and relevance of biomonitors, rather than man-made equipment, are justified by the observation that the best indicator of the status of a species or system is itself.[6] Bioindicators can reveal indirect biotic effects of pollutants when many physical or chemical measurements cannot. Through bioindicators, scientists need to observe only the single indicating species to check on the environment rather than monitor the whole community.[7] Small sets of indicator species can also be used to predict species richness for multiple taxonomic groups.[8]

The use of a biomonitor is described as biological monitoring and is the use of the properties of an organism to obtain information on certain aspects of the biosphere. Biomonitoring of air pollutants can be passive or active. Experts use passive methods to observe plants growing naturally within the area of interest. Active methods are used to detect the presence of air pollutants by placing test plants of known response and genotype into the study area.

The use of a biomonitor is described as biological monitoring. This refers to the measurement of specific properties of an organism to obtain information on the surrounding physical and chemical environment.[9]

Bioaccumulative indicators are frequently regarded as biomonitors. Depending on the organism selected and their use, there are several types of bioindicators.[10][11]

Use

In most instances, baseline data for biotic conditions within a pre-determined reference site are collected. Reference sites must be characterized by little to no outside disturbance (e.g. anthropogenic disturbances, land use change, invasive species). The biotic conditions of a specific indicator species are measured within both the reference site and the study region over time. Data collected from the study region are compared against similar data collected from the reference site in order to infer the relative environmental health or integrity of the study region.[12]

An important limitation of bioindicators in general is that they have been reported as inaccurate when applied to geographically and environmentally diverse regions.[13] As a result, researchers who use bioindicators need to consistently ensure that each set of indices is relevant within the environmental conditions they plan to monitor.[14]

Plant and fungal indicators

 
The lichen Lobaria pulmonaria is sensitive to air pollution.

The presence or absence of certain plant or other vegetative life in an ecosystem can provide important clues about the health of the environment: environmental preservation. There are several types of plant biomonitors, including mosses, lichens, tree bark, bark pockets, tree rings, and leaves. Fungi too may be useful as indicators.

Lichens are organisms comprising both fungi and algae. They are found on rocks and tree trunks, and they respond to environmental changes in forests, including changes in forest structure – conservation biology, air quality, and climate. The disappearance of lichens in a forest may indicate environmental stresses, such as high levels of sulfur dioxide, sulfur-based pollutants, and nitrogen oxides. The composition and total biomass of algal species in aquatic systems serve as an important metric for organic water pollution and nutrient loading such as nitrogen and phosphorus. There are genetically engineered organisms that can respond to toxicity levels in the environment; e.g., a type of genetically engineered grass that grows a different colour if there are toxins in the soil.[15]

Animal indicators and toxins

 
Populations of American crows (Corvus brachyrhynchos) are especially susceptible to the West Nile Virus, and can be used as a bioindicator species for the disease's presence in an area.

Changes in animal populations, whether increases or decreases, can indicate pollution.[16] For example, if pollution causes depletion of a plant, animal species that depend on that plant will experience population decline. Conversely, overpopulation may be opportunistic growth of a species in response to loss of other species in an ecosystem. On the other hand, stress-induced sub-lethal effects can be manifested in animal physiology, morphology, and behaviour of individuals long before responses are expressed and observed at the population level.[17] Such sub-lethal responses can be very useful as "early warning signals" to predict how populations will further respond.

Pollution and other stress agents can be monitored by measuring any of several variables in animals: the concentration of toxins in animal tissues; the rate at which deformities arise in animal populations; behaviour in the field or in the laboratory;[18] and by assessing changes in individual physiology.[19]

Frogs and toads

Amphibians, particularly anurans (frogs and toads), are increasingly used as bioindicators of contaminant accumulation in pollution studies.[20] Anurans absorb toxic chemicals through their skin and their larval gill membranes and are sensitive to alterations in their environment.[21] They have a poor ability to detoxify pesticides that are absorbed, inhaled, or ingested by eating contaminated food.[21] This allows residues, especially of organochlorine pesticides, to accumulate in their systems.[21] They also have permeable skin that can easily absorb toxic chemicals, making them a model organism for assessing the effects of environmental factors that may cause the declines of the amphibian population.[21] These factors allow them to be used as bioindicator organisms to follow changes in their habitats and in ecotoxicological studies due to humans increasing demands on the environment.[22]

Knowledge and control of environmental agents is essential for sustaining the health of ecosystems. Anurans are increasingly utilized as bioindicator organisms in pollution studies, such as studying the effects of agricultural pesticides on the environment.[citation needed] Environmental assessment to study the environment in which they live is performed by analyzing their abundance in the area as well as assessing their locomotive ability and any abnormal morphological changes, which are deformities and abnormalities in development.[citation needed] Decline of anurans and malformations could also suggest increased exposure to ultra-violet light and parasites.[22] Expansive application of agrochemicals such as glyphosate have been shown to have harmful effects on frog populations throughout their lifecycle due to run off of these agrochemicals into the water systems these species live and their proximity to human development.[23]

Pond-breeding anurans are especially sensitive to pollution because of their complex life cycles, which could consist of terrestrial and aquatic living.[20] During their embryonic development, morphological and behavioral alterations are the effects most frequently cited in connection with chemical exposures.[24] Effects of exposure may result in shorter body length, lower body mass and malformations of limbs or other organs.[20] The slow development, late morphological change, and small metamorph size result in increased risk of mortality and exposure to predation.[20]

Crustaceans

Crayfish have also been hypothesized as being suitable bioindicators, under the appropriate conditions.[25]

Microbial indicators

Chemical pollutants

Microorganisms can be used as indicators of aquatic or terrestrial ecosystem health. Found in large quantities, microorganisms are easier to sample than other organisms. Some microorganisms will produce new proteins, called stress proteins, when exposed to contaminants such as cadmium and benzene. These stress proteins can be used as an early warning system to detect changes in levels of pollution.

In oil and gas exploration

Microbial Prospecting for oil and gas (MPOG) is often used to identify prospective areas for oil and gas occurrences. In many cases, oil and gas is known to seep toward the surface as a hydrocarbon reservoir will usually leak or have leaked towards the surface through buoyancy forces overcoming sealing pressures. These hydrocarbons can alter the chemical and microbial occurrences found in the near-surface soils or can be picked up directly. Techniques used for MPOG include DNA analysis, simple bug counts after culturing a soil sample in a hydrocarbon-based medium or by looking at the consumption of hydrocarbon gases in a culture cell.[26]

Microalgae in water quality

Microalgae have gained attention in recent years due to several reasons including their greater sensitivity to pollutants than many other organisms. In addition, they occur abundantly in nature, they are an essential component in very many food webs, they are easy to culture and to use in assays and there are few if any ethical issues involved in their use.

 
Gravitactic mechanism of the microalgae Euglena gracilis (A) in the absence and (B) in the presence of pollutants.

Euglena gracilis is a motile, freshwater, photosynthetic flagellate. Although Euglena is rather tolerant to acidity, it responds rapidly and sensitively to environmental stresses such as heavy metals or inorganic and organic compounds. Typical responses are the inhibition of movement and a change of orientation parameters. Moreover, this organism is very easy to handle and grow, making it a very useful tool for eco-toxicological assessments. One very useful particularity of this organism is gravitactic orientation, which is very sensitive to pollutants. The gravireceptors are impaired by pollutants such as heavy metals and organic or inorganic compounds. Therefore, the presence of such substances is associated with random movement of the cells in the water column. For short-term tests, gravitactic orientation of E. gracilis is very sensitive.[27][28] Other species such as Paramecium biaurelia (see Paramecium aurelia) also use gravitactic orientation.[29]

Automatic bioassay is possible, using the flagellate Euglena gracilis in a device which measures their motility at different dilutions of the possibly polluted water sample, to determine the EC50 (the concentration of sample which affects 50 percent of organisms) and the G-value (lowest dilution factor at which no-significant toxic effect can be measured).[30][31]

Macroinvertebrates

Macroinvertebrates are useful and convenient indicators of the ecological health of water bodies[32] and terrestrial ecosystems.[33][34] They are almost always present, and are easy to sample and identify. This is largely due to the fact that most macro-invertebrates are visible to the naked eye, they typically have a short life-cycle (often the length of a single season) and are generally sedentary.[35] Pre-existing river conditions such as river type and flow will affect macro invertebrate assemblages and so various methods and indices will be appropriate for specific stream types and within specific eco-regions.[35] While some benthic macroinvertebrates are highly tolerant to various types of water pollution, others are not. Changes in population size and species type in specific study regions indicate the physical and chemical state of streams and rivers.[9] Tolerance values are commonly used to assess water pollution[36] and environmental degradation, such as human activities (e.g. selective logging and wildfires) in tropical forests.[37][38]

 
An integrative biological assessment of sites in the Custer National Forest, Ashland Ranger District

Benthic indicators for water quality testing

Benthic macroinvertebrates are found within the benthic zone of a stream or river. They consist of aquatic insects, crustaceans, worms and mollusks that live in the vegetation and stream beds of rivers.[9] Macroinvertebrate species can be found in nearly every stream and river, except in some of the world's harshest environments. They also can be found in mostly any size of stream or river, prohibiting only those that dry up within a short timeframe.[39] This makes the beneficial for many studies because they can be found in regions where stream beds are too shallow to support larger species such as fish.[9] Benthic indicators are often used to measure the biological components of fresh water streams and rivers. In general, if the biological functioning of a stream is considered to be in good standing, then it is assumed that the chemical and physical components of the stream are also in good condition.[9] Benthic indicators are the most frequently used water quality test within the United States.[9] While benthic indicators should not be used to track the origins of stressors in rivers and streams, they can provide background on the types of sources that are often associated with the observed stressors.[40]

Global context

In Europe, the Water Framework Directive (WFD) went into effect on October 23, 2000.[41] It requires all EU member states to show that all surface and groundwater bodies are in good status. The WFD requires member states to implement monitoring systems to estimate the integrity of biological stream components for specific sub-surface water categories. This requirement increased the incidence of biometrics applied to ascertain stream health in Europe[13] A remote online biomonitoring system was designed in 2006. It is based on bivalve molluscs and the exchange of real-time data between a remote intelligent device in the field (able to work for more than 1 year without in-situ human intervention) and a data centre designed to capture, process and distribute the web information derived from the data. The technique relates bivalve behaviour, specifically shell gaping activity, to water quality changes. This technology has been successfully used for the assessment of coastal water quality in various countries (France, Spain, Norway, Russia, Svalbard (Ny-Ålesund) and New Caledonia).[18]

In the United States, the Environmental Protection Agency (EPA) published Rapid Bioassessment Protocols, in 1999, based on measuring macroinvertebrates, as well as periphyton and fish for assessment of water quality.[1][42][43]

In South Africa, the Southern African Scoring System (SASS) method is based on benthic macroinvertebrates, and is used for the assessment of water quality in South African rivers. The SASS aquatic biomonitoring tool has been refined over the past 30 years and is now on the fifth version (SASS5) in accordance with the ISO/IEC 17025 protocol.[35] The SASS5 method is used by the South African Department of Water Affairs as a standard method for River Health Assessment, which feeds the national River Health Programme and the national Rivers Database.

The imposex phenomenon in the dog conch species of sea snail leads to the abnormal development of a penis in females, but does not cause sterility. Because of this, the species has been suggested as a good indicator of pollution with organic man-made tin compounds in Malaysian ports.[44]

See also

References

  1. ^ a b Barbour, M.T.; Gerritsen, J.; Stribling, J.B. (1999). Rapid Bioassessment Protocols for Use in Streams and Wadeable Rivers: 😀Periphyton, Benthic Macroinvertebrates and Fish, Second Edition (Report). Washington, D.C.: U.S. Environmental Protection Agency (EPA). EPA 841-B-99-002.
  2. ^ Siddig, Ahmed A.H.; Ellison, Aaron M.; Ochs, Alison; Villar-Leeman, Claudia; Lau, Matthew K. (2016). "How do ecologists select and use indicator species to monitor ecological change? Insights from 14 years of publication in Ecological Indicators". ResearchGate. 60: 223–230. doi:10.1016/j.ecolind.2015.06.036. S2CID 54948928.
  3. ^ Karr, James R. (1981). "Assessment of biotic integrity using fish communities". Fisheries. 6 (6): 21–27. doi:10.1577/1548-8446(1981)006<0021:AOBIUF>2.0.CO;2. ISSN 1548-8446.
  4. ^ NCSU Water Quality Group. . WATERSHEDSS: A Decision Support System for Nonpoint Source Pollution Control. Raleigh, NC: North Carolina State University. Archived from the original on 2016-07-23. Retrieved 2016-07-31.
  5. ^ Protak Scientific (2017-02-03). "Biological ind". Protak Scientific. United Kingdom: Protak Scientific. Retrieved 2017-08-05.
  6. ^ Tingey, David T. (1989). Bio indicators in Air Pollution Research – Applications and Constraints. pp. 73–80. ISBN 978-0-309-07833-7. {{cite book}}: |journal= ignored (help)
  7. ^ "Bioindicators". Science Learning Hub. The University of Waikato, New Zealand. 2015-02-10.
  8. ^ Fleishman, Erica; Thomson, James R.; Mac Nally, Ralph; Murphy, Dennis D.; Fay, John P. (August 2005). "Using Indicator Species to Predict Species Richness of Multiple Taxonomic Groups". Conservation Biology. 19 (4): 1125–1137. doi:10.1111/j.1523-1739.2005.00168.x. ISSN 0888-8892. S2CID 53659601.
  9. ^ a b c d e f U.S. Environmental Protection Agency. Office of Water and Office of Research and Development. (March 2016). "National Rivers and Streams Assessment 2008-2009: A Collaborative Study" (PDF). Washington D.C.
  10. ^ Government of Canada. . Archived from the original on October 3, 2011.
  11. ^ Chessman, Bruce (2003). (PDF). Monitoring River Heath Initiative Technical Report no. 31. Canberra: Commonwealth of Australia, Department of the Environment and Heritage. ISBN 978-0642548979. Archived from the original (PDF) on 2007-09-13.
  12. ^ Lewin, Iga; Czerniawska-Kusza, Izabela; Szoszkiewicz, Krzysztof; Ławniczak, Agnieszka Ewa; Jusik, Szymon (2013-06-01). "Biological indices applied to benthic macroinvertebrates at reference conditions of mountain streams in two ecoregions (Poland, the Slovak Republic)". Hydrobiologia. 709 (1): 183–200. doi:10.1007/s10750-013-1448-2. ISSN 1573-5117.
  13. ^ a b Monteagudo, Laura; Moreno, José Luis (2016-08-01). "Benthic freshwater cyanobacteria as indicators of anthropogenic pressures". Ecological Indicators. 67: 693–702. doi:10.1016/j.ecolind.2016.03.035. ISSN 1470-160X.
  14. ^ Mazor, Raphael D.; Rehn, Andrew C.; Ode, Peter R.; Engeln, Mark; Schiff, Kenneth C.; Stein, Eric D.; Gillett, David J.; Herbst, David B.; Hawkins, Charles P. (2016-03-01). "Bioassessment in complex environments: designing an index for consistent meaning in different settings". Freshwater Science. 35 (1): 249–271. doi:10.1086/684130. ISSN 2161-9549. S2CID 54717345.
  15. ^ Halper, Mark (2006-12-03). "Saving Lives And Limbs With a Weed". Time. Retrieved 2016-06-22.
  16. ^ Grabarkiewicz, Jeffrey D.; Davis, Wayne S. (November 2008). An Introduction to Freshwater Fishes As Biological Indicators (Report). EPA. p. 1. EPA-260-R-08-016.
  17. ^ Beaulieu, Michaël; Costantini, David (2014-01-01). "Biomarkers of oxidative status: missing tools in conservation physiology". Conservation Physiology. 2 (1): cou014. doi:10.1093/conphys/cou014. PMC 4806730. PMID 27293635.
  18. ^ a b Université Bordeaux et al. MolluSCAN eye project 2016-11-13 at the Wayback Machine
  19. ^ França, Filipe; Barlow, Jos; Araújo, Bárbara; Louzada, Julio (2016-12-01). "Does selective logging stress tropical forest invertebrates? Using fat stores to examine sublethal responses in dung beetles". Ecology and Evolution. 6 (23): 8526–8533. doi:10.1002/ece3.2488. PMC 5167030. PMID 28031804.
  20. ^ a b c d Simon, E., Braun, M. & Tóthmérész, B. Water Air Soil Pollut (2010) 209: 467. doi:10.1007/s11270-009-0214-6
  21. ^ a b c d Lambert, M. R. K. (1997-01-01). "Environmental Effects of Heavy Spillage from a Destroyed Pesticide Store near Hargeisa (Somaliland) Assessed During the Dry Season, Using Reptiles and Amphibians as Bioindicators". Archives of Environmental Contamination and Toxicology. 32 (1): 80–93. doi:10.1007/s002449900158. PMID 9002438. S2CID 24315472.
  22. ^ a b Center for Global Environmental Education. What are the frogs trying to tell us? OR Malformed Amphibians. Retrieved from http://cgee.hamline.edu/frogs/archives/corner3.html
  23. ^ (Herek et al., 2020)
  24. ^ Venturino, A., Rosenbaum, E., De Castro, A. C., Anguiano, O. L., Gauna, L., De Schroeder, T. F., & De D'Angelo, A. P. (2003). Biomarkers of effect in toads and frogs. Biomarkers, 8(3/4), 167.
  25. ^ Füreder, L.; Reynolds, J. D. (2003). "Is Austropotamobius Pallipes a Good Bioindicator?". Bulletin Français de la Pêche et de la Pisciculture (370–371): 157–163. doi:10.1051/kmae:2003011. ISSN 0767-2861.
  26. ^ Rasheed, M. A.; et al. (2015). "Application of geo-microbial prospecting method for finding oil and gas reservoirs". Frontiers of Earth Science. 9 (1): 40–50. Bibcode:2015FrES....9...40R. doi:10.1007/s11707-014-0448-5. S2CID 129440067.
  27. ^ Azizullah, Azizullah; Murad, Waheed; Muhammad, Adnan; Waheed, Ullah; Häder, Donat-Peter (2013). "Gravitactic orientation of Euglena gracilis - a sensitive endpoint for ecotoxicological assessment of water pollutants". Frontiers in Environmental Science. 1 (4): 1–4. doi:10.3389/fenvs.2013.00004.
  28. ^ Tahedl, Harald; Donat-Peter, Haeder (2001). "Automated Biomonitoring Using Real Time Movement Analysis of Euglena gracilis". Ecotoxicology and Environmental Safety. 48 (2): 161–169. doi:10.1006/eesa.2000.2004. PMID 11161690.
  29. ^ Hemmersbach, Ruth; Simon, Anja; Waßer, Kai; Hauslage, Jens; Christianen, Peter C.M.; Albers, Peter W.; Lebert, Michael; Richter, Peter; Alt, Wolfgang; Anken, Ralf (2014). "Impact of a High Magnetic Field on the Orientation of Gravitactic Unicellular Organisms—A Critical Consideration about the Application of Magnetic Fields to Mimic Functional Weightlessness". Astrobiology. 14 (3): 205–215. Bibcode:2014AsBio..14..205H. doi:10.1089/ast.2013.1085. PMC 3952527. PMID 24621307.
  30. ^ Tahedl, Harald; Hader, Donat-Peter (1999). "Fast examination of water quality using the automatic biotest ECOTOX based on the movement behavior of a freshwater flagellate". Water Research. 33 (2): 426–432. doi:10.1016/s0043-1354(98)00224-3.
  31. ^ Ahmed, Hoda; Häder, Donat-Peter (2011). "Monitoring of Waste Water Samples Using the ECOTOX Biosystem and the Flagellate Alga Euglena gracilis". Water, Air, & Soil Pollution. 216 (1–4): 547–560. Bibcode:2011WASP..216..547A. doi:10.1007/s11270-010-0552-4. S2CID 98814927.
  32. ^ Gooderham, John; Tsyrlin, Edward (2002). The Waterbug Book: A Guide to the Freshwater Macroinvertebrates of Temperate Australia. Collingswood, Victoria: CSIRO Publishing. ISBN 0-643-06668-3.
  33. ^ Bicknell, Jake E.; Phelps, Simon P.; Davies, Richard G.; Mann, Darren J.; Struebig, Matthew J.; Davies, Zoe G. (2014). "Dung beetles as indicators for rapid impact assessments: Evaluating best practice forestry in the neotropics". Ecological Indicators. 43: 154–161. doi:10.1016/j.ecolind.2014.02.030.
  34. ^ Beiroz, W.; Audino, L. D.; Rabello, A. M.; Boratto, I. A.; Silva, Z; Ribas, C. R. (2014). "Structure and composition of edaphic arthropod community and its use as bioindicators of environmental disturbance". Applied Ecology and Environmental Research. 12 (2): 481–491. doi:10.15666/aeer/1202_481491. ISSN 1785-0037. Retrieved 2017-08-02.
  35. ^ a b c Dickens, CWS; Graham, PM (2002). (PDF). African Journal of Aquatic Science. 27: 1–10. doi:10.2989/16085914.2002.9626569. S2CID 85035010. Archived from the original (PDF) on 2016-03-28. Retrieved 2011-11-16.
  36. ^ Chang, F.C. & J.E. Lawrence (2014). "Tolerance Values of Benthic Macroinvertebrates for Stream Biomonitoring: Assessment of Assumptions Underlying Scoring Systems Worldwide". Environmental Monitoring and Assessment. 186 (4): 2135–2149. doi:10.1007/s10661-013-3523-6. PMID 24214297. S2CID 39590510.
  37. ^ Barlow, Jos; Lennox, Gareth D.; Ferreira, Joice; Berenguer, Erika; Lees, Alexander C.; Nally, Ralph Mac; Thomson, James R.; Ferraz, Silvio Frosini de Barros; Louzada, Julio (2016). "Anthropogenic disturbance in tropical forests can double biodiversity loss from deforestation" (PDF). Nature. 535 (7610): 144–147. Bibcode:2016Natur.535..144B. doi:10.1038/nature18326. PMID 27362236. S2CID 4405827.
  38. ^ França, Filipe; Louzada, Julio; Korasaki, Vanesca; Griffiths, Hannah; Silveira, Juliana M.; Barlow, Jos (2016-08-01). "Do space-for-time assessments underestimate the impacts of logging on tropical biodiversity? An Amazonian case study using dung beetles". Journal of Applied Ecology. 53 (4): 1098–1105. doi:10.1111/1365-2664.12657. ISSN 1365-2664. S2CID 67849288.
  39. ^ "Aquatic Macroinvertebrates". Water Quality. Logan, UT: Utah State University Extension. Retrieved 2020-10-11.
  40. ^ Smith, A. J.; Duffy, B. T.; Onion, A.; Heitzman, D. L.; Lojpersberger, J. L.; Mosher, E. A.; Novak, M. A . (2018). "Long-term trends in biological indicators and water quality in rivers and streams of New York State (1972–2012)". River Research and Applications. 34 (5): 442–450. doi:10.1002/rra.3272. ISSN 1535-1467. S2CID 133650984.
  41. ^ "The EU Water Framework Directive - integrated river basin management for Europe". Environment. European Commission. 2020-08-04.
  42. ^ . Izaak Walton League of America. Archived from the original on 2015-04-21. Retrieved 2010-08-14.
  43. ^ Volunteer Stream Monitoring: A Methods Manual (PDF) (Report). EPA. November 1997. EPA 841-B-97-003.
  44. ^ Cob, Z. C.; Arshad, A.; Bujang, J. S.; Ghaffar, M. A. (2011). "Description and evaluation of imposex in Strombus canarium Linnaeus, 1758 (Gastropoda, Strombidae): a potential bio-indicator of tributyltin pollution" (PDF). Environmental Monitoring and Assessment. 178 (1–4): 393–400. doi:10.1007/s10661-010-1698-7. PMID 20824325. S2CID 207130813.

Herek, J. S., Vargas, L., Trindade, S. A. R., Rutkoski, C. F., Macagnan, N., Hartmann, P. A., & Hartmann, M. T. (2020). Can environmental concentrations of glyphosate affect survival and cause malformation in amphibians? Effects from a glyphosate-based herbicide on Physalaemus cuvieri and P. gracilis (Anura: Leptodactylidae). Environmental Science and Pollution Research, 27(18), 22619–22630. https://doi.org/10.1007/s11356-020-08869-z

Further reading

  • Caro, Tim (2010). Conservation by proxy: indicator, umbrella, keystone, flagship, and other surrogate species. Washington, DC: Island Press. ISBN 9781597261920.

External links

 
Wikimedia Commons has media related to Bioindicators.
  • – U.S. Department of Energy, Richland, WA
  • Volunteer Monitoring Program – U.S. EPA
  • – South Africa
  • Pyxine cocoes Nyl. – A Foliose Lichen as a Potential Bio-indicator/Bio-monitor of Air Pollution in Philippines: An Update by Isidro A. T. Savillo
  • Biological Indicators for Sterilization – Protak Scientific

August 21, 2023
bioindicator, bioindicator, species, indicator, species, group, species, whose, function, population, status, reveal, qualitative, status, environment, most, common, indicator, species, animals, example, copepods, other, small, water, crustaceans, that, presen. A bioindicator is any species an indicator species or group of species whose function population or status can reveal the qualitative status of the environment The most common indicator species are animals 2 For example copepods and other small water crustaceans that are present in many water bodies can be monitored for changes biochemical physiological or behavioural that may indicate a problem within their ecosystem Bioindicators can tell us about the cumulative effects of different pollutants in the ecosystem and about how long a problem may have been present which physical and chemical testing cannot 3 Caddisfly order Trichoptera a macroinvertebrate used as an indicator of water quality 1 A biological monitor or biomonitor is an organism that provides quantitative information on the quality of the environment around it 4 Therefore a good biomonitor will indicate the presence of the pollutant and can also be used in an attempt to provide additional information about the amount and intensity of the exposure A biological indicator is also the name given to a process for assessing the sterility of an environment through the use of resistant microorganism strains e g Bacillus or Geobacillus 5 Biological indicators can be described as the introduction of a highly resistant microorganisms to a given environment before sterilization tests are conducted to measure the effectiveness of the sterilization processes As biological indicators use highly resistant microorganisms any sterilization process that renders them inactive will have also killed off more common weaker pathogens Contents 1 Overview 1 1 Use 2 Plant and fungal indicators 3 Animal indicators and toxins 3 1 Frogs and toads 3 2 Crustaceans 4 Microbial indicators 4 1 Chemical pollutants 4 2 In oil and gas exploration 4 3 Microalgae in water quality 5 Macroinvertebrates 5 1 Benthic indicators for water quality testing 5 2 Global context 6 See also 7 References 8 Further reading 9 External linksOverview EditA bioindicator is an organism or biological response that reveals the presence of pollutants by the occurrence of typical symptoms or measurable responses and is therefore more qualitative These organisms or communities of organisms can be used to deliver information on alterations in the environment or the quantity of environmental pollutants by changing in one of the following ways physiologically chemically or behaviourally The information can be deduced through the study of their content of certain elements or compounds their morphological or cellular structure metabolic biochemical processes behaviour population structure s The importance and relevance of biomonitors rather than man made equipment are justified by the observation that the best indicator of the status of a species or system is itself 6 Bioindicators can reveal indirect biotic effects of pollutants when many physical or chemical measurements cannot Through bioindicators scientists need to observe only the single indicating species to check on the environment rather than monitor the whole community 7 Small sets of indicator species can also be used to predict species richness for multiple taxonomic groups 8 The use of a biomonitor is described as biological monitoring and is the use of the properties of an organism to obtain information on certain aspects of the biosphere Biomonitoring of air pollutants can be passive or active Experts use passive methods to observe plants growing naturally within the area of interest Active methods are used to detect the presence of air pollutants by placing test plants of known response and genotype into the study area The use of a biomonitor is described as biological monitoring This refers to the measurement of specific properties of an organism to obtain information on the surrounding physical and chemical environment 9 Bioaccumulative indicators are frequently regarded as biomonitors Depending on the organism selected and their use there are several types of bioindicators 10 11 Use Edit In most instances baseline data for biotic conditions within a pre determined reference site are collected Reference sites must be characterized by little to no outside disturbance e g anthropogenic disturbances land use change invasive species The biotic conditions of a specific indicator species are measured within both the reference site and the study region over time Data collected from the study region are compared against similar data collected from the reference site in order to infer the relative environmental health or integrity of the study region 12 An important limitation of bioindicators in general is that they have been reported as inaccurate when applied to geographically and environmentally diverse regions 13 As a result researchers who use bioindicators need to consistently ensure that each set of indices is relevant within the environmental conditions they plan to monitor 14 Plant and fungal indicators Edit The lichen Lobaria pulmonaria is sensitive to air pollution The presence or absence of certain plant or other vegetative life in an ecosystem can provide important clues about the health of the environment environmental preservation There are several types of plant biomonitors including mosses lichens tree bark bark pockets tree rings and leaves Fungi too may be useful as indicators Lichens are organisms comprising both fungi and algae They are found on rocks and tree trunks and they respond to environmental changes in forests including changes in forest structure conservation biology air quality and climate The disappearance of lichens in a forest may indicate environmental stresses such as high levels of sulfur dioxide sulfur based pollutants and nitrogen oxides The composition and total biomass of algal species in aquatic systems serve as an important metric for organic water pollution and nutrient loading such as nitrogen and phosphorus There are genetically engineered organisms that can respond to toxicity levels in the environment e g a type of genetically engineered grass that grows a different colour if there are toxins in the soil 15 Animal indicators and toxins Edit Populations of American crows Corvus brachyrhynchos are especially susceptible to the West Nile Virus and can be used as a bioindicator species for the disease s presence in an area Changes in animal populations whether increases or decreases can indicate pollution 16 For example if pollution causes depletion of a plant animal species that depend on that plant will experience population decline Conversely overpopulation may be opportunistic growth of a species in response to loss of other species in an ecosystem On the other hand stress induced sub lethal effects can be manifested in animal physiology morphology and behaviour of individuals long before responses are expressed and observed at the population level 17 Such sub lethal responses can be very useful as early warning signals to predict how populations will further respond Pollution and other stress agents can be monitored by measuring any of several variables in animals the concentration of toxins in animal tissues the rate at which deformities arise in animal populations behaviour in the field or in the laboratory 18 and by assessing changes in individual physiology 19 Frogs and toads Edit Amphibians particularly anurans frogs and toads are increasingly used as bioindicators of contaminant accumulation in pollution studies 20 Anurans absorb toxic chemicals through their skin and their larval gill membranes and are sensitive to alterations in their environment 21 They have a poor ability to detoxify pesticides that are absorbed inhaled or ingested by eating contaminated food 21 This allows residues especially of organochlorine pesticides to accumulate in their systems 21 They also have permeable skin that can easily absorb toxic chemicals making them a model organism for assessing the effects of environmental factors that may cause the declines of the amphibian population 21 These factors allow them to be used as bioindicator organisms to follow changes in their habitats and in ecotoxicological studies due to humans increasing demands on the environment 22 Knowledge and control of environmental agents is essential for sustaining the health of ecosystems Anurans are increasingly utilized as bioindicator organisms in pollution studies such as studying the effects of agricultural pesticides on the environment citation needed Environmental assessment to study the environment in which they live is performed by analyzing their abundance in the area as well as assessing their locomotive ability and any abnormal morphological changes which are deformities and abnormalities in development citation needed Decline of anurans and malformations could also suggest increased exposure to ultra violet light and parasites 22 Expansive application of agrochemicals such as glyphosate have been shown to have harmful effects on frog populations throughout their lifecycle due to run off of these agrochemicals into the water systems these species live and their proximity to human development 23 Pond breeding anurans are especially sensitive to pollution because of their complex life cycles which could consist of terrestrial and aquatic living 20 During their embryonic development morphological and behavioral alterations are the effects most frequently cited in connection with chemical exposures 24 Effects of exposure may result in shorter body length lower body mass and malformations of limbs or other organs 20 The slow development late morphological change and small metamorph size result in increased risk of mortality and exposure to predation 20 Crustaceans Edit Crayfish have also been hypothesized as being suitable bioindicators under the appropriate conditions 25 Microbial indicators EditChemical pollutants Edit Microorganisms can be used as indicators of aquatic or terrestrial ecosystem health Found in large quantities microorganisms are easier to sample than other organisms Some microorganisms will produce new proteins called stress proteins when exposed to contaminants such as cadmium and benzene These stress proteins can be used as an early warning system to detect changes in levels of pollution In oil and gas exploration Edit Microbial Prospecting for oil and gas MPOG is often used to identify prospective areas for oil and gas occurrences In many cases oil and gas is known to seep toward the surface as a hydrocarbon reservoir will usually leak or have leaked towards the surface through buoyancy forces overcoming sealing pressures These hydrocarbons can alter the chemical and microbial occurrences found in the near surface soils or can be picked up directly Techniques used for MPOG include DNA analysis simple bug counts after culturing a soil sample in a hydrocarbon based medium or by looking at the consumption of hydrocarbon gases in a culture cell 26 Microalgae in water quality Edit Microalgae have gained attention in recent years due to several reasons including their greater sensitivity to pollutants than many other organisms In addition they occur abundantly in nature they are an essential component in very many food webs they are easy to culture and to use in assays and there are few if any ethical issues involved in their use Gravitactic mechanism of the microalgae Euglena gracilis A in the absence and B in the presence of pollutants Euglena gracilis is a motile freshwater photosynthetic flagellate Although Euglena is rather tolerant to acidity it responds rapidly and sensitively to environmental stresses such as heavy metals or inorganic and organic compounds Typical responses are the inhibition of movement and a change of orientation parameters Moreover this organism is very easy to handle and grow making it a very useful tool for eco toxicological assessments One very useful particularity of this organism is gravitactic orientation which is very sensitive to pollutants The gravireceptors are impaired by pollutants such as heavy metals and organic or inorganic compounds Therefore the presence of such substances is associated with random movement of the cells in the water column For short term tests gravitactic orientation of E gracilis is very sensitive 27 28 Other species such as Paramecium biaurelia see Paramecium aurelia also use gravitactic orientation 29 Automatic bioassay is possible using the flagellate Euglena gracilis in a device which measures their motility at different dilutions of the possibly polluted water sample to determine the EC50 the concentration of sample which affects 50 percent of organisms and the G value lowest dilution factor at which no significant toxic effect can be measured 30 31 Macroinvertebrates EditMacroinvertebrates are useful and convenient indicators of the ecological health of water bodies 32 and terrestrial ecosystems 33 34 They are almost always present and are easy to sample and identify This is largely due to the fact that most macro invertebrates are visible to the naked eye they typically have a short life cycle often the length of a single season and are generally sedentary 35 Pre existing river conditions such as river type and flow will affect macro invertebrate assemblages and so various methods and indices will be appropriate for specific stream types and within specific eco regions 35 While some benthic macroinvertebrates are highly tolerant to various types of water pollution others are not Changes in population size and species type in specific study regions indicate the physical and chemical state of streams and rivers 9 Tolerance values are commonly used to assess water pollution 36 and environmental degradation such as human activities e g selective logging and wildfires in tropical forests 37 38 An integrative biological assessment of sites in the Custer National Forest Ashland Ranger DistrictBenthic indicators for water quality testing Edit Benthic macroinvertebrates are found within the benthic zone of a stream or river They consist of aquatic insects crustaceans worms and mollusks that live in the vegetation and stream beds of rivers 9 Macroinvertebrate species can be found in nearly every stream and river except in some of the world s harshest environments They also can be found in mostly any size of stream or river prohibiting only those that dry up within a short timeframe 39 This makes the beneficial for many studies because they can be found in regions where stream beds are too shallow to support larger species such as fish 9 Benthic indicators are often used to measure the biological components of fresh water streams and rivers In general if the biological functioning of a stream is considered to be in good standing then it is assumed that the chemical and physical components of the stream are also in good condition 9 Benthic indicators are the most frequently used water quality test within the United States 9 While benthic indicators should not be used to track the origins of stressors in rivers and streams they can provide background on the types of sources that are often associated with the observed stressors 40 Global context Edit In Europe the Water Framework Directive WFD went into effect on October 23 2000 41 It requires all EU member states to show that all surface and groundwater bodies are in good status The WFD requires member states to implement monitoring systems to estimate the integrity of biological stream components for specific sub surface water categories This requirement increased the incidence of biometrics applied to ascertain stream health in Europe 13 A remote online biomonitoring system was designed in 2006 It is based on bivalve molluscs and the exchange of real time data between a remote intelligent device in the field able to work for more than 1 year without in situ human intervention and a data centre designed to capture process and distribute the web information derived from the data The technique relates bivalve behaviour specifically shell gaping activity to water quality changes This technology has been successfully used for the assessment of coastal water quality in various countries France Spain Norway Russia Svalbard Ny Alesund and New Caledonia 18 In the United States the Environmental Protection Agency EPA published Rapid Bioassessment Protocols in 1999 based on measuring macroinvertebrates as well as periphyton and fish for assessment of water quality 1 42 43 In South Africa the Southern African Scoring System SASS method is based on benthic macroinvertebrates and is used for the assessment of water quality in South African rivers The SASS aquatic biomonitoring tool has been refined over the past 30 years and is now on the fifth version SASS5 in accordance with the ISO IEC 17025 protocol 35 The SASS5 method is used by the South African Department of Water Affairs as a standard method for River Health Assessment which feeds the national River Health Programme and the national Rivers Database The imposex phenomenon in the dog conch species of sea snail leads to the abnormal development of a penis in females but does not cause sterility Because of this the species has been suggested as a good indicator of pollution with organic man made tin compounds in Malaysian ports 44 See also EditBiological integrity Biological monitoring working party a measurement procedure Biosignature Ecological indicator Environmental indicator Indicator value MERMOZ remote detection of lifeforms Sentinel speciesReferences Edit a b Barbour M T Gerritsen J Stribling J B 1999 Rapid Bioassessment Protocols for Use in Streams and Wadeable Rivers Periphyton Benthic Macroinvertebrates and Fish Second Edition Report Washington D C U S Environmental Protection Agency EPA EPA 841 B 99 002 Siddig Ahmed A H Ellison Aaron M Ochs Alison Villar Leeman Claudia Lau Matthew K 2016 How do ecologists select and use indicator species to monitor ecological change Insights from 14 years of publication in Ecological Indicators ResearchGate 60 223 230 doi 10 1016 j ecolind 2015 06 036 S2CID 54948928 Karr James R 1981 Assessment of biotic integrity using fish communities Fisheries 6 6 21 27 doi 10 1577 1548 8446 1981 006 lt 0021 AOBIUF gt 2 0 CO 2 ISSN 1548 8446 NCSU Water Quality Group Biomonitoring WATERSHEDSS A Decision Support System for Nonpoint Source Pollution Control Raleigh NC North Carolina State University Archived from the original on 2016 07 23 Retrieved 2016 07 31 Protak Scientific 2017 02 03 Biological ind Protak Scientific United Kingdom Protak Scientific Retrieved 2017 08 05 Tingey David T 1989 Bio indicators in Air Pollution Research Applications and Constraints pp 73 80 ISBN 978 0 309 07833 7 a href Template Cite book html title Template Cite book cite book a journal ignored help Bioindicators Science Learning Hub The University of Waikato New Zealand 2015 02 10 Fleishman Erica Thomson James R Mac Nally Ralph Murphy Dennis D Fay John P August 2005 Using Indicator Species to Predict Species Richness of Multiple Taxonomic Groups Conservation Biology 19 4 1125 1137 doi 10 1111 j 1523 1739 2005 00168 x ISSN 0888 8892 S2CID 53659601 a b c d e f U S Environmental Protection Agency Office of Water and Office of Research and Development March 2016 National Rivers and Streams Assessment 2008 2009 A Collaborative Study PDF Washington D C Government of Canada Biobasics bio indicatorrs Archived from the original on October 3 2011 Chessman Bruce 2003 SIGNAL 2 A Scoring System for Macro invertebrate Water Bugs in Australian Rivers PDF Monitoring River Heath Initiative Technical Report no 31 Canberra Commonwealth of Australia Department of the Environment and Heritage ISBN 978 0642548979 Archived from the original PDF on 2007 09 13 Lewin Iga Czerniawska Kusza Izabela Szoszkiewicz Krzysztof Lawniczak Agnieszka Ewa Jusik Szymon 2013 06 01 Biological indices applied to benthic macroinvertebrates at reference conditions of mountain streams in two ecoregions Poland the Slovak Republic Hydrobiologia 709 1 183 200 doi 10 1007 s10750 013 1448 2 ISSN 1573 5117 a b Monteagudo Laura Moreno Jose Luis 2016 08 01 Benthic freshwater cyanobacteria as indicators of anthropogenic pressures Ecological Indicators 67 693 702 doi 10 1016 j ecolind 2016 03 035 ISSN 1470 160X Mazor Raphael D Rehn Andrew C Ode Peter R Engeln Mark Schiff Kenneth C Stein Eric D Gillett David J Herbst David B Hawkins Charles P 2016 03 01 Bioassessment in complex environments designing an index for consistent meaning in different settings Freshwater Science 35 1 249 271 doi 10 1086 684130 ISSN 2161 9549 S2CID 54717345 Halper Mark 2006 12 03 Saving Lives And Limbs With a Weed Time Retrieved 2016 06 22 Grabarkiewicz Jeffrey D Davis Wayne S November 2008 An Introduction to Freshwater Fishes As Biological Indicators Report EPA p 1 EPA 260 R 08 016 Beaulieu Michael Costantini David 2014 01 01 Biomarkers of oxidative status missing tools in conservation physiology Conservation Physiology 2 1 cou014 doi 10 1093 conphys cou014 PMC 4806730 PMID 27293635 a b Universite Bordeaux et al MolluSCAN eye project Archived 2016 11 13 at the Wayback Machine Franca Filipe Barlow Jos Araujo Barbara Louzada Julio 2016 12 01 Does selective logging stress tropical forest invertebrates Using fat stores to examine sublethal responses in dung beetles Ecology and Evolution 6 23 8526 8533 doi 10 1002 ece3 2488 PMC 5167030 PMID 28031804 a b c d Simon E Braun M amp Tothmeresz B Water Air Soil Pollut 2010 209 467 doi 10 1007 s11270 009 0214 6 a b c d Lambert M R K 1997 01 01 Environmental Effects of Heavy Spillage from a Destroyed Pesticide Store near Hargeisa Somaliland Assessed During the Dry Season Using Reptiles and Amphibians as Bioindicators Archives of Environmental Contamination and Toxicology 32 1 80 93 doi 10 1007 s002449900158 PMID 9002438 S2CID 24315472 a b Center for Global Environmental Education What are the frogs trying to tell us OR Malformed Amphibians Retrieved from http cgee hamline edu frogs archives corner3 html Herek et al 2020 Venturino A Rosenbaum E De Castro A C Anguiano O L Gauna L De Schroeder T F amp De D Angelo A P 2003 Biomarkers of effect in toads and frogs Biomarkers 8 3 4 167 Fureder L Reynolds J D 2003 Is Austropotamobius Pallipes a Good Bioindicator Bulletin Francais de la Peche et de la Pisciculture 370 371 157 163 doi 10 1051 kmae 2003011 ISSN 0767 2861 Rasheed M A et al 2015 Application of geo microbial prospecting method for finding oil and gas reservoirs Frontiers of Earth Science 9 1 40 50 Bibcode 2015FrES 9 40R doi 10 1007 s11707 014 0448 5 S2CID 129440067 Azizullah Azizullah Murad Waheed Muhammad Adnan Waheed Ullah Hader Donat Peter 2013 Gravitactic orientation of Euglena gracilis a sensitive endpoint for ecotoxicological assessment of water pollutants Frontiers in Environmental Science 1 4 1 4 doi 10 3389 fenvs 2013 00004 Tahedl Harald Donat Peter Haeder 2001 Automated Biomonitoring Using Real Time Movement Analysis of Euglena gracilis Ecotoxicology and Environmental Safety 48 2 161 169 doi 10 1006 eesa 2000 2004 PMID 11161690 Hemmersbach Ruth Simon Anja Wasser Kai Hauslage Jens Christianen Peter C M Albers Peter W Lebert Michael Richter Peter Alt Wolfgang Anken Ralf 2014 Impact of a High Magnetic Field on the Orientation of Gravitactic Unicellular Organisms A Critical Consideration about the Application of Magnetic Fields to Mimic Functional Weightlessness Astrobiology 14 3 205 215 Bibcode 2014AsBio 14 205H doi 10 1089 ast 2013 1085 PMC 3952527 PMID 24621307 Tahedl Harald Hader Donat Peter 1999 Fast examination of water quality using the automatic biotest ECOTOX based on the movement behavior of a freshwater flagellate Water Research 33 2 426 432 doi 10 1016 s0043 1354 98 00224 3 Ahmed Hoda Hader Donat Peter 2011 Monitoring of Waste Water Samples Using the ECOTOX Biosystem and the Flagellate Alga Euglena gracilis Water Air amp Soil Pollution 216 1 4 547 560 Bibcode 2011WASP 216 547A doi 10 1007 s11270 010 0552 4 S2CID 98814927 Gooderham John Tsyrlin Edward 2002 The Waterbug Book A Guide to the Freshwater Macroinvertebrates of Temperate Australia Collingswood Victoria CSIRO Publishing ISBN 0 643 06668 3 Bicknell Jake E Phelps Simon P Davies Richard G Mann Darren J Struebig Matthew J Davies Zoe G 2014 Dung beetles as indicators for rapid impact assessments Evaluating best practice forestry in the neotropics Ecological Indicators 43 154 161 doi 10 1016 j ecolind 2014 02 030 Beiroz W Audino L D Rabello A M Boratto I A Silva Z Ribas C R 2014 Structure and composition of edaphic arthropod community and its use as bioindicators of environmental disturbance Applied Ecology and Environmental Research 12 2 481 491 doi 10 15666 aeer 1202 481491 ISSN 1785 0037 Retrieved 2017 08 02 a b c Dickens CWS Graham PM 2002 The Southern Africa Scoring System SASS version 5 rapid bioassessment for rivers PDF African Journal of Aquatic Science 27 1 10 doi 10 2989 16085914 2002 9626569 S2CID 85035010 Archived from the original PDF on 2016 03 28 Retrieved 2011 11 16 Chang F C amp J E Lawrence 2014 Tolerance Values of Benthic Macroinvertebrates for Stream Biomonitoring Assessment of Assumptions Underlying Scoring Systems Worldwide Environmental Monitoring and Assessment 186 4 2135 2149 doi 10 1007 s10661 013 3523 6 PMID 24214297 S2CID 39590510 Barlow Jos Lennox Gareth D Ferreira Joice Berenguer Erika Lees Alexander C Nally Ralph Mac Thomson James R Ferraz Silvio Frosini de Barros Louzada Julio 2016 Anthropogenic disturbance in tropical forests can double biodiversity loss from deforestation PDF Nature 535 7610 144 147 Bibcode 2016Natur 535 144B doi 10 1038 nature18326 PMID 27362236 S2CID 4405827 Franca Filipe Louzada Julio Korasaki Vanesca Griffiths Hannah Silveira Juliana M Barlow Jos 2016 08 01 Do space for time assessments underestimate the impacts of logging on tropical biodiversity An Amazonian case study using dung beetles Journal of Applied Ecology 53 4 1098 1105 doi 10 1111 1365 2664 12657 ISSN 1365 2664 S2CID 67849288 Aquatic Macroinvertebrates Water Quality Logan UT Utah State University Extension Retrieved 2020 10 11 Smith A J Duffy B T Onion A Heitzman D L Lojpersberger J L Mosher E A Novak M A 2018 Long term trends in biological indicators and water quality in rivers and streams of New York State 1972 2012 River Research and Applications 34 5 442 450 doi 10 1002 rra 3272 ISSN 1535 1467 S2CID 133650984 The EU Water Framework Directive integrated river basin management for Europe Environment European Commission 2020 08 04 Biological Stream Monitoring Izaak Walton League of America Archived from the original on 2015 04 21 Retrieved 2010 08 14 Volunteer Stream Monitoring A Methods Manual PDF Report EPA November 1997 EPA 841 B 97 003 Cob Z C Arshad A Bujang J S Ghaffar M A 2011 Description and evaluation of imposex in Strombus canarium Linnaeus 1758 Gastropoda Strombidae a potential bio indicator of tributyltin pollution PDF Environmental Monitoring and Assessment 178 1 4 393 400 doi 10 1007 s10661 010 1698 7 PMID 20824325 S2CID 207130813 Herek J S Vargas L Trindade S A R Rutkoski C F Macagnan N Hartmann P A amp Hartmann M T 2020 Can environmental concentrations of glyphosate affect survival and cause malformation in amphibians Effects from a glyphosate based herbicide on Physalaemus cuvieri and P gracilis Anura Leptodactylidae Environmental Science and Pollution Research 27 18 22619 22630 https doi org 10 1007 s11356 020 08869 zFurther reading EditCaro Tim 2010 Conservation by proxy indicator umbrella keystone flagship and other surrogate species Washington DC Island Press ISBN 9781597261920 External links Edit Wikimedia Commons has media related to Bioindicators Environmental Biomarkers Initiative at Pacific Northwest National Laboratory U S Department of Energy Richland WA Volunteer Monitoring Program U S EPA The National River Health Programme South Africa Pyxine cocoes Nyl A Foliose Lichen as a Potential Bio indicator Bio monitor of Air Pollution in Philippines An Update by Isidro A T Savillo Biological Indicators for Sterilization Protak Scientific Retrieved from https en wikipedia org w index php title Bioindicator amp oldid 1165046455, wikipedia, wiki, book, books, library,

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