Anisakis
Anisakis | |
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Anisakis simplex | |
Scientific classification | |
Kingdom: | |
Phylum: | |
Class: | Secernentea
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Order: | |
Family: | |
Genus: | Anisakis (Karl Rudolphi 1809)[verification needed]
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Species | |
A. pegreffii |
Anisakis is a genus of parasitic nematodes, which have a life cycle involving fish and marine mammals. They are infective to humans and cause Anisakiasis, and fish which have been infected with Anisakis spp. can produce an anaphylactic reaction in people who have become sensitized to Immunoglobulin E (IgE).
Life cycle
Anisakis spp. have a complex life cycle which passes through a number of hosts through the course of its life. Eggs hatch in sea water and larvae are eaten by crustaceans, usually Euphausids. The infected crustacean is subsequently eaten by a fish or squid and the nematode burrows into the wall of the gut and encysts in a protective coat, usually on the outside of the visceral organs, but occasionally in the muscle or beneath the skin. The life cycle is completed when an infected fish is eaten by a marine mammal, such as a whale or dolphin. The nematode excysts in the intestine, feeds, grows, mates and releases eggs into the sea water in the host's feces. As the gut of a marine mammal is functionally very similar to that of a human, Anisakis spp. are able to infect humans who eat raw or undercooked fish.
The diversity of the genus has increased greatly over the past 20 years, with the advent of modern genetic techniques in species identification. It has been discovered that each final host species is home to its own biochemically and genetically identifiable sibling species of Anisakis spp., which is reproductively isolated. This finding has allowed the proportion of different sibling species in a fish to be used as an indicator of population identity in fish stocks.
Morphology
Anisakids share the common features of all nematodes; the vermiform body plan, round in cross section and a lack of segmentation. The body cavity is reduced to a narrow pseudocoel. The mouth located anteriorly, and surrounded by projections used in feeding and sensation, with the anus slightly offset from the posterior. The epidermis secretes a layered cuticle that protects the body from digestive juices.
As with all parasites with a complex life cycle involving a number of hosts, details of the morphology vary depending on the host and stage of life cycle which it is in. In the stage which infects fish, Anisakis are found in a distinctive watch-spring coil shape. They are roughly 2 cm long when uncoiled. When in the final host, Anisakids are longer, thicker and more sturdy, to deal with the hazardous environment of a mammalian gut.
Health implications
Anisakids pose a risk to human health in two ways: through infection with worms from the eating of under-processed fish, and through allergic reactions to chemicals left by the worms in fish flesh.
Anisakiasis
Anisakiasis is the disease caused by infection with Anisakis worms. It is frequently reported in areas of the world where fish is consumed raw, lightly pickled or salted. The areas of highest prevalence are Scandinavia (from cod livers), Japan (after eating sushi and sashimi), the Netherlands (by eating infected fermented herrings (Maatjes)), and along the Pacific coast of South America (from eating ceviche). Heating to 60 °C, or freezing to below −20 °C is an effective method of killing Anisakis.
Within hours after ingestion of infective larvae, violent abdominal pain, nausea, and vomiting may occur. Occasionally the larvae are coughed up. If the larvae pass into the bowel, a severe eosinophilic granulomatous response may also occur 1 to 2 weeks following infection, causing symptoms mimicking Crohn's disease.
Diagnosis can be made by gastroscopic examination during which the 2 cm larvae are visualized and removed, or by histopathologic examination of tissue removed at biopsy or during surgery.
Humans are thought to be more at risk of Anisakiasis from eating wild fish than farm-raised fish, because the grinding process used for pellet food for farmed fish kills the parasites. A 2003 study by the Food and Agriculture Organization of the United Nations found no parasites in any farm-raised salmon, in contrast to wild salmon in which parasites were frequently found[1].
Many countries require all types of fish with potential risk intended for raw consumption to be previously frozen to kill parasites.
Allergic reactions
Even when throroughly cooked Anisakis pose a health risk to humans. Anisakids (and related species such as the sealworm, Pseudoterranova spp., and the codworm Hysterothylacium aduncum) release a number of biochemicals into the surrounding tissues when they infect a fish. They are also often consumed whole, accidentally, inside a fillet of fish.
People who are sensitized to nematodes can have severe anaphylactic reactions after eating fish which have been infected with Anisakis spp. This is often confused with a fish or shellfish allergy, as the allergenic components of Anisakids are difficult to test for and often produce a reaction in tests for other allergens.
Treatment
For the worm, humans are a dead-end host. Anisakis and Pseudoterranova larvae cannot survive in humans and eventually die. Treatment therefore in the vast majority of cases is symptomatic, with a heavy dose of re-assurance. The only indication for treatment is small bowel obstruction due to Anisakis larvae, which may require emergency surgery, although there are case reports of treatment with albendazole alone (avoiding surgery) being successful (Pacios et al., 2005).
Occurrence
Larval anisakis are common parasites of marine and anadromous fish, and can also be found in squid and cuttlefish. In contrast, they are absent from fish in waters of low salinity, due to the physiological requirements of Euphausids, which are needed to complete their life cycle. Anisakids are also uncommon in areas where cetaceans are rare, such as the southern North Sea (Grabda, 1976).
Similar Parasites
- Cod or Seal Worm Pseudoterranova (Phocanema, Terranova) decipiens
- Contracaecum spp.
- Hysterothylacium (Thynnascaris) spp.
References
- Huss, H.H.; Ababouch, L.; Gram, L. (2003), Assessment and Management of Seafood Safety and Quality (PDF), vol. 444, Rome: FAO, ISBN 92-5-104954-8
- Akbar A, Ghosh H (2005). "Anisakiasis—a neglected diagnosis in the West". Allergy. 37 (1): 7–9.
- Grabda, J. (1976). "Studies on the life cycle and morphogenesis of Anisakis simplex (Rudolphi, 1809)(Nematoda: Anisakidae) cultured in vitro". Acta Ichthyologica et Piscatoria. 6 (1): 119–131.
- Lorenzo S, Iglesias R, Leiro J, Ubeira FM, Ansotegui I, Garcia M, Fernandez de Corres L (2000). "Usefulness of currently available methods for the diagnosis of Anisakis simplex allergy". Allergy. 55: 627–33.
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: CS1 maint: multiple names: authors list (link) - Mattiucci S., Nascetti G., Tortini E., Ramadori L., Abaunza P. & Paggi L (2000). "Composition and structure of metazoan parasitic communities of European hake (Merluccius merluccius) from Mediterranean and Atlantic waters: stock implications". Parassitologia. 42 (S1): 176–186.
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: CS1 maint: multiple names: authors list (link) - Orecchia P, Paggi L, Mattiucci S, Smith JW, Nascetti G & Bullini L (1986). "Electrophoretic identification of larvae and adults of Anisakis (Ascaridida:Anisakidae)". J Helminthol. 60 (4): 331–9.
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: CS1 maint: multiple names: authors list (link)