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Coenurosis

Different forms of coenurus in sheep and rabbits and an adult worm

Coenurosis, also known as caenurosis, coenuriasis, gid or sturdy, is a parasitic infection that develops in the intermediate hosts of some tapeworm species (Taenia multiceps,[1] T. serialis,[2] T. brauni, or T. glomerata). It is caused by the coenurus, the larval stage of these tapeworms. The disease occurs mainly in sheep and other ungulates,[3] but it can also occur in humans by accidental ingestion of tapeworm eggs.

Adult worms of these species develop in the small intestine of the definitive hosts (dogs, foxes and other canids), causing a disease from the group of taeniasis.[4] Humans cannot be definitive hosts for these species of tapeworms.

History

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The texts of Hippocrates describe a nervous disease of sheep consistent with the symptoms of gid, comparing its symptoms to epilepsy and describing the accumulation of bad-smelling fluid in the brain.[5][6] However, it was only in the 1600s that clearer behavioural and necropsy descriptions were recorded, including the chacteristic brain cysts and early surgical methods of removal.[7] The cause of these cysts was identified as an animal parasite in 1780 by Nathanael Gottfried Leske and Johann August Ephraim Goeze.[6][7] It was shown that the parasite could be transferred across species to and from dogs by Karl Theodor Ernst von Siebold and Friedrich Küchenmeister in the 1850s and the species was identified as Taenia multiceps (then called Coenurus cerebralis) in 1890.[7]

Coenurosis in humans is rare and was not diagnosed until the twentieth century, with the first recorded cases by each Taenia species being: T. multiceps in 1913,[8] T. glomerate in 1919,[9] T. serialis in 1933,[8] and T. brauni in 1956.[9]

Life cycle

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The eggs of T.multiceps, T. glomerate, T. serialis, and T. brauni are shed in the feces of infected hosts into the environment.[10]  The eggs are then ingested by an intermediate host, where the eggs hatch in intestines and release oncospheres.[10] Oncospheres are the larval form of tapeworms that contain hooks for attaching to the host’s tissues.[11] The oncospheres continue to move through the bloodstream of the intermediate host until they find suitable organs to inhabit.[11] The oncospheres can bind to the eyes, the brain, skeletal muscle, and subcutaneous tissue. Once the oncospheres reach their destination, they take about three months to develop into coenuri.[10] Coenuri are white, fluid filled structures that are 3-10 centimeters in diameter.[12] Coenuri have a collapsed membrane and several protoscolices on the interior.[12] The coenuri cysts found in the central nervous system have multiple cavities, and those that are not have only one cavity.[12] The disease is transferred to the definitive host when the host digests the tissue of the intermediate host. Next, eggs hatch in the intestine of the definitive host and circulate in the bloodstream until they reach suitable organs.[10]

Symptoms and diagnosis

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The symptoms for coenurosis vary depending on where the cyst is located.[citation needed]

Prevention and treatment

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In sheep, the usual treatment is surgical trepanation to remove the brain cyst, one of the few economically viable surgeries in farm animals.[5][13] The site of the cyst can usually be estimated based on the neurological symptoms and skull thinning.[5] Treated sheep typically regain sufficient function to rejoin the flock[5] and necropsy indicates that the site of the cyst collapses and scars, relieving pressure on the brain.[14]

In the rare cases where a human is infected, both surgical and pharmaceutical treatments are available.[15] Since the disease is so uncommon in humans, no vaccine has been developed for it.[15]

Epidemiology

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Hosts

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The definitive hosts for coenurosis are dogs, foxes, and other canids.[16] The intermediate hosts for coenurosis can vary depending on the Taenia spp. In T. multiceps, sheep are the intermediate hosts, but goats, cattle, horses, and antelopes are also common hosts.[16] T. multiceps can affect any tissue, but it normally targets the brain in animal hosts. In T. serialis, rabbits and rodents are the intermediate hosts.[16] T. serialis commonly targets subcutaneous and intramuscular tissue. In T. brauni and T. glomerata, gerbils are the intermediate host. T. brauni and T. glomerate larvae tend to inhabit the muscles. Intermediate hosts can be infected with either chronic or acute coenurosis.[16]  Chronic coenurosis is the more common form, and it occurs primarily in young sheep.[citation needed]

In wild animals

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Although coenurosis is more commonly associated with domestic animals, it has also been documented in wildlife, such as in mountain ungulates in the French Alps. It is believed that the ungulates are being contaminated by infected sheep. Understanding how this disease is transmitted from sheep to wild animals is important in managing the spread of this potentially dangerous zoonotic disease. A potential management strategy would be for farmers to dispose of animal carcasses found on their land. In Ethiopia, gelada monkeys with coenurosis were found to have higher mortality and lower reproductive success.[17][18]

See also

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References

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  1. ^ University of Pennsylvania - Veterinary Medicine: Taenia multiceps Homepage Archived 2010-07-10 at the Wayback Machine
  2. ^ University of Pennsylvania - Veterinary medicine: Taenia serialis Homepage Archived 2010-07-10 at the Wayback Machine
  3. ^ Stanford University: Coenurosis - Hosts Archived 2012-10-23 at the Wayback Machine
  4. ^ Stanford University: Taeniasis Archived 2013-07-09 at the Wayback Machine
  5. ^ a b c d Komnenou, A.; Dessiris, A.; Giadinis, N. (2000). "Surgical treatment of coenurosis (gid) in sheep". Veterinary Record. 147 (9): 242–244. doi:10.1136/vr.147.9.242. PMID 11014487. S2CID 24998839.
  6. ^ a b Hall, Maurice C. (1910). The gid parasite and allied species of the cestode genus Multiceps. U.S. Dept. of Agriculture, Bureau of Animal Industry. OCLC 681930104.
  7. ^ a b c Ransom, Brayton Howard. [from old catalog] (1905). The gid parasite (Cnurus cerebralis): its presence in American sheep. Washington: Govt. print. off. doi:10.5962/bhl.title.34582.
  8. ^ a b "Coenurosis". web.stanford.edu. Retrieved 2020-04-30.
  9. ^ a b Hermos, John A.; Healy, George R.; Schultz, Myron G.; Barlow, John; Church, William G. (1970-08-31). "Fatal Human Cerebral Coenurosis". JAMA. 213 (9): 1461–1464. doi:10.1001/jama.1970.03170350029006. ISSN 0098-7484. PMID 5468450.
  10. ^ a b c d Armon, Robert; Cheruti, Uta (2012). "Environmental Aspects of Zoonotic Diseases". Water Intelligence Online. 11. doi:10.2166/9781780400761. ISSN 1476-1777.
  11. ^ a b Smyth, James Desmond (2007). The physiology and biochemistry of cestodes. Cambridge University Press. ISBN 978-0-521-03895-9. OCLC 836624725.
  12. ^ a b c d e f g Ryan, Edward T.; Hill, David Russell; Solomon, Tom; Endy, Timothy P.; Aronson, Naomi, eds. (25 March 2019). Hunter's tropical medicine and emerging infectious diseases. Elsevier Health Sciences. ISBN 978-0-323-62550-0. OCLC 1096243611.
  13. ^ Skerritt, G.; Stallbaumer, M. (1984-10-20). "Diagnosis and treatment of coenuriasis (gid) in sheep". Veterinary Record. 115 (16): 399–403. doi:10.1136/vr.115.16.399. ISSN 0042-4900. PMID 6506419. S2CID 42469802.
  14. ^ Kelly, D.F.; Payne-Johnson, C.E. (1993). "Cerebral healing after craniotomy to evacuate a coenurus cerebralis cyst". Journal of Comparative Pathology. 108 (4): 399–403. doi:10.1016/S0021-9975(08)80212-5. PMID 8366207.
  15. ^ a b "Coenurosis". web.stanford.edu. Retrieved 2020-04-30.
  16. ^ a b c d Rahsan, Yilmaz; Nihat, Yumusak; Bestami, Yilmaz; Adnan, Ayan; Nuran, Aysul (2018-03-30). "Histopathological, immunohistochemical, and parasitological studies on pathogenesis of Coenurus cerebralis in sheep". Journal of Veterinary Research. 62 (1): 35–41. doi:10.2478/jvetres-2018-0005. ISSN 2450-8608. PMC 5957459. PMID 29978125.
  17. ^ Schneider-Crease I, Griffin RH, Gomery MA, Bergman TJ, Beehner JC (2017). "High mortality associated with tapeworm parasitism in geladas (Theropithecus gelada) in the Simien Mountains National Park, Ethiopia". American Journal of Primatology. 79 (9): e22684. doi:10.1002/ajp.22684. hdl:2027.42/138266. PMID 28783206. S2CID 3878796.
  18. ^ Nguyen N, Fashing PJ, Boyd DA, Barry TS, Burke RJ, Goodale CB, Jones SC, Kerby JT, Kellogg BS, Lee LM, Miller CM, Nurmi NO, Ramsay MS, Reynolds JD, Stewart KM, Turner TJ, Venkataraman VV, Knauf Y, Roos C, Knauf S (2017). "Fitness impacts of tapeworm parasitism on wild gelada monkeys at Guassa, Ethiopia". American Journal of Primatology. 77 (5): 579–594. doi:10.1002/ajp.22379. PMID 25716944. S2CID 23714669.
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