The Canary In The Coal Mine Mac OS
Miners would take a caged canary to their worksite. If the bird stopped singing (or died), the miners would vacate immediately. The bird was telling them the air quality was unsafe. The phrase a, or the, canary in a, or the, (coal) mine denotes an early indicator of potential danger or failure. It refers to the former practice of taking live canaries into coal mines to test for the presence of toxic gases, particularly carbon monoxide, the illness or death of the canaries serving as an indication that such gases were present.
Sentinel species are organisms, often animals, used to detect risks to humans by providing advance warning of a danger. The terms primarily apply in the context of environmental hazards rather than those from other sources. Some animals can act as sentinels because they may be more susceptible or have greater exposure to a particular hazard than humans in the same environment.[1] People have long observed animals for signs of impending hazards or evidence of environmental threats. Plants and other living organisms have also been used for these purposes.
Historical examples[edit]
There are countless examples of environmental effects on animals that later manifested in humans. The classic example is the 'canary in the coal mine'. The idea of placing a canary or other warm blooded animal in a mine to detect carbon monoxide was first proposed by John Scott Haldane, in 1913 or later.[2][3][4] Well into the 20th century, coal miners brought canaries into coal mines as an early-warning signal for toxic gases, primarily carbon monoxide.[5] The birds, being more sensitive, would become sick before the miners, who would then have a chance to escape or put on protective respirators.
In Minamata Bay, Japan, cats developed 'dancing cat fever' before humans were affected due to eating mercury-contaminated fish.[6] Dogs were recognized as early as 1939 to be more susceptible to tonsil cancer if they were kept in crowded urban environments.[6] Studies similarly found higher disease rates in animals exposed to tobacco smoke.[6]Yushō disease was similarly discovered when poultry began dying at alarming rates due to polychlorinated biphenyl poisoning, although not before approximately 14,000 people were affected.
Characteristics[edit]
Animal sentinels must have measurable responses to the hazard in question, whether that is due to the animal's death, disappearance, or some other determinable aspect.[1]:34 Many of these species are ideally unendangered and easy to handle. It is important that the species' range overlap with the range being studied.[7] Often the ideal species is determined by the characteristics of the hazard.
For example, honey bees are susceptible to air pollution.[1]:35 Similarly both bats and swallows have been used to monitor pesticide contamination due to their diet of insects that may have been affected by the chemicals.[1]:35 By the same token, aquatic animals, or their direct predators, are used as sentinel species to monitor water pollution.[citation needed]
Some species may show effects of a contaminant before humans due to their size, their reproductive rate, or their increased exposure to the contaminant.[7]
Specific applications[edit]
Toxic gases[edit]
Canaries were iconically used in coal mines to detect the presence of carbon monoxide. The bird's rapid breathing rate, small size, and high metabolism, compared to the miners, led birds in dangerous mines to succumb before the miners, thereby giving them time to take action.
Air and water pollution[edit]
A number of animals have been used to measure varying kinds of air pollution. These include honey bees for air pollution, bivalve molluscs[8] for online water-quality survey and pigeons for atmospheric lead.[1]:35 Bats and swallows have been used to monitor pesticide contamination due to their diet of insects that may have been affected by the chemicals.[1]:35
Aquatic DDT pollution has been quantitatively measured in California fish. PCB has been measured through the analysis of fish livers.[1]:82Toxaphene concentrations were discovered far from the area of its use through analysis of trout in the Great Lakes.[1]:85 The evidence of atmospheric transport of the substance influenced the subsequent prohibition of its widespread use. Alligators may have been used to warn of hazardous contamination in Centreville, Mississippi retention ponds.[9]
Scientists also monitor crayfish in the wild in natural bodies of water to study the levels of pollutants there.[10][11][12]
The Protivin brewery in the Czech Republic uses crayfish outfitted with sensors to detect any changes in their bodies or pulse activity in order to monitor the purity of the water used in their product. The creatures are kept in a fish tank that is fed with the same local natural source water used in their brewing. If three or more of the crayfish have changes to their pulses, employees know there is a change in the water and examine the parameters.[10]
Infectious diseases[edit]
The discovery of West Nile virus in the Western Hemisphere was heralded by an outbreak of disease in crows and other wild birds. Other emerging diseases have demonstrated linkages between animal health events and human risk, including monkeypox, SARS, and avian influenza. In outbreaks of bubonic plague, rats begin dying out before humans.
Household toxins[edit]
Dogs may provide early warning of lead poisoning hazards in a home, and certain cancers in dogs and cats have been linked to household exposures to pesticides, cigarette smoke, and other carcinogens.
Cultural references[edit]
- Kurt Vonnegut in an interview compared the function of artists in human society to coal-mine canaries; see Wikiquote.
See also[edit]
References[edit]
Utah Coal Mine
- ^ abcdefghNational Research Council (U.S.). Committee on Animals as Monitors of Environmental Hazards, 'Animals as Sentinels of Environmental Health Hazards: Committee on Animals as Monitors of Environmental Hazards,' National Academy Press: 1991, ISBN0309040469.
- ^Acott, C. (1999). 'JS Haldane, JBS Haldane, L Hill, and A Siebe: A brief resume of their lives'. South Pacific Underwater Medicine Society Journal. 29 (3). ISSN0813-1988. OCLC16986801. Retrieved 2008-07-12.
- ^Boycott, A. E.; Damant, G. C. C.; Haldane, J. S. (1908). 'Prevention of compressed air illness'. J. Hygiene. 8 (3): 342–443. doi:10.1017/S0022172400003399. PMC2167126. PMID20474365. Retrieved 2013-09-05.
- ^Hellemans, Alexander; Bunch, Bryan (1988). The Timetables of Science. Simon & Schuster. p. 411. ISBN0671621300.
- ^David A. Bengston, Diane S. Henshel, 'Environmental Toxicology and Risk Assessment: Biomarkers and Risk Assessment', ASTM International, 1996, ISBN0803120311, p 220.
- ^ abcStephen J. Withrow, David M. Vail, Withrow and MacEwen's Small Animal Clinical Oncology, Elsevier: 2007, ISBN0721605583, p. 73-4.
- ^ abArthur D. Bloom, Frederick de Serres, Ecotoxicity and Human Health: A Biological Approach to Environmental Remediation, CRC Press: 1995, ISBN1566701414, page 76.
- ^[1]
- ^Eugene Love Fair Jr. (May 28, 2013), 'Christmas v. Exxon Mobil', Mississippi Court of Appeals, retrieved January 3, 2014
- ^ abHanrahan, Mark (27 September 2017). 'Crayfish staff help Czech brewery keep its water as pure as can be'. Reuters TV. Archived from the original on 25 October 2019. Retrieved 1 November 2019.
- ^'Clean Water'. Missouri Conservationist Magazine. Vol. 69 no. 11. Missouri Department of Conservation. November 2008. Retrieved 1 November 2019.
- ^Schilderman, P. A. E. L.; Moonen, E. J. C.; Maas, L. M.; Welle, I.; Kleinjans, J. C. S. (1999). 'Use of Crayfish in Biomonitoring Studies of Environmental Pollution of the River Meuse'. Ecotoxicology and Environmental Safety. 44 (3): 241–252. doi:10.1006/eesa.1999.1827. ISSN0147-6513. PMID10581118.
Further reading[edit]
A Canary In A Mine
- van der Schalie WH; Gardner HS Jr; Bantle JA; De Rosa CT; Finch RA; Reif JS; Reuter RH; Backer LC; Burger J; Folmar LC; Stokes WS. (Apr 1999). 'Animals as sentinels of human health hazards of environmental chemicals'. Environ Health Perspect. 107 (4): 309–315. doi:10.1289/ehp.99107309. PMC1566523. PMID10090711.
- O'Brien DJ; Kaneene JB; Poppenga RH (Mar 1993). 'The use of mammals as sentinels for human exposure to toxic contaminants in the environment'. Environ Health Perspect. 99: 351–368. doi:10.1289/ehp.9399351. PMC1567056. PMID8319652.
- Backer LC; Grindem CB; Corbett WT; Cullins L; Hunter JL (2001-07-02). 'Pet dogs as sentinels for environmental contamination'. Sci Total Environ. 274 (1–3): 161–169. Bibcode:2001ScTEn.274..161B. doi:10.1016/S0048-9697(01)00740-9. PMID11453293.
- Rabinowitz P; Gordon Z; Chudnov D; Wilcox M; Odofin L; Liu A; Dein J. (Apr 2006). 'Animals as sentinels of bioterrorism agents'. Emerg Infect Dis. 12 (4): 647–652. doi:10.3201/eid1204.051120. PMC3294700. PMID16704814.
- Meselson M; Guillemin J; Hugh-Jones M; Langmuir A; Popova I; Shelokov A; Yampolskaya O (1994-11-18). 'The Sverdlovsk anthrax outbreak of 1979'. Science. 266 (5188): 1202–1208. Bibcode:1994Sci...266.1202M. doi:10.1126/science.7973702. PMID7973702.
- Kahn LH (Apr 2006). 'Confronting zoonoses, linking human and veterinary medicine'. Emerg Infect Dis. 12 (4): 556–561. doi:10.3201/eid1204.050956. PMC3294691. PMID16704801.
External links[edit]
Canary In Coal Mine Idiom
- Online biomonitoring of water quality by a permanent record of bivalve molluscs' behavior and physiology (biological rhythms, growth rate, spawning, early warning), 24/7, worldwide: the MolluSCAN eye project