Biology
provided by Arkive
Bigeye tunas are excellent swimmers, with a number of remarkable adaptations which make them efficient predators of the ocean. Unlike many other fish, they cannot pump water over their gills, but instead, swim with their mouth open which forces water over their gills. While this is an efficient way of getting water over their gills, it means that if they stop swimming, they will suffocate. The gills of tuna cover a surface area up to 30 times larger than other fish, giving a large surface over which water can flow, enabling about half the oxygen present in the water to be absorbed. The hearts of tuna are also much larger than those of other fish; about ten times as large, relative to the size of the body. This, along with a high blood pressure, creates perfect conditions to rapidly transfer oxygen from the gills to other tissues (6).
As well as adaptations to enhance the amount of oxygen reaching the muscles, a unique system to regulate their body temperature enables tuna to maintain their body temperature above that of the ocean. This system is called the rete mirabile; a counter-current heat exchange system which prevents heat from being lost to the surroundings. This maximises the efficiency of the muscles and maintains good brain and eye function, allowing the bigeye tuna to forage in cold water (6).
Juvenile and small adult bigeye tunas school at the ocean's surface, sometimes together with yellowfin or skipjack tuna, and often associated with floating objects (2), while adult bigeye tunas are found in deeper water (5). The bigeye tunas migrate between feeding grounds in temperate waters and their spawning grounds in tropical waters; however, they are on the move almost all the time as they search for areas of plentiful food (6). Bigeye tunas feed on a variety of fish, cephalopods and crustaceans; which it searches for in the daytime and nighttime. Bigeye tunas become prey themselves for larger billfish and toothed whales (2).
Mature bigeye tuna spawn at least twice a year; releasing between an incredible 2.9 million and 6.3 million eggs each time. In the eastern Pacific, spawning has been recorded between 10°N and l0° S throughout the year, peaking between April and September in the northern hemisphere and between January and March in the southern hemisphere (2).
Conservation
provided by Arkive
In the Atlantic, Indian and Pacific oceans there are commissions responsible for the conservation and management of the bigeye tuna; the International Commission for the Conservation of Atlantic Tunas (ICCAT), the Indian Ocean Tuna Commission (IOTC), the Western and Central Pacific Fisheries Commission (WCPFC), and the Inter-American Tropical Tuna Commission (IATTC). However, a report by Traffic International and WWF Australia found that management of bigeye tuna stocks has been slow to respond to scientific advice, and have failed to initiate appropriate management measures. Unless this situation changes, all four bigeye tuna stocks will become overfished (5), and the collapse of bigeye tuna stocks would greatly impact many people reliant on the employment and income of the fishing, processing and trading industries (7). Hopefully more precautionary management measures will soon be implemented, before it is too late for this important and fascinating fish.
Description
provided by Arkive
This large, fast-swimming tuna is an important target for numerous commercial fisheries around the world. The streamlined body of the bigeye tuna is dark metallic blue on the back, white on the undersides, and bears moderately long pectoral fins, used for balancing and breaking. The first dorsal fin is deep yellow, while the second dorsal fin and anal fin are pale yellow, and small fins just behind the dorsal and anal fins, called finlets, are bright yellow edged with black (2) (3). The length of the anal fin and the larger eyes of the bigeye tuna, after which it is named, distinguish this species from the similar yellowfin tuna (4).
Habitat
provided by Arkive
The bigeye tuna inhabits oceanic waters from the surface down to a depth of 250 metres, in temperatures from 13° to 29° C (2)
Range
provided by Arkive
Occurs in the Atlantic, Pacific and Indian Oceans, but does not occur in the Mediterranean (2). Bigeye tunas are most commonly found in tropical and subtropical waters, but its distribution does extend into temperate waters. There are considered to be separate stocks in the Eastern Pacific, Western Pacific, Atlantic and Indian Oceans (5).
Status
provided by Arkive
Classified as Vulnerable (VU) on the IUCN Red List 2007. The Pacific stock is classified as Endangered (EN) (1).
Threats
provided by Arkive
The bigeye tuna is an important target for fisheries in many parts of its range, and its flesh attracts high prices. All stocks of the bigeye tuna are now considered fully fished or over-fished, and overfishing is occurring in some areas, notably in the Endangered Pacific stock (5). The biological characteristics of the bigeye tuna, (it is relatively long-lived, late to spawn, and has a low productivity) make it more vulnerable to over-fishing than species such as skipjack tuna and yellowfin tuna. Without swift and effective management actions, populations of bigeye tuna are likely to go the same way as the Southern bluefin tuna (5), classified by the World Conservation Union (IUCN) as Critically Endangered (1).
Benefits
provided by FAO species catalogs
Catch statistics are reported by 17 countries for 14 fishing areas. Yearly catches of more than 10 000 metric tons are taken in Fishing Areas 34, 51, 61, 71) and 77 with more than two thirds of the total taken in the Pacific up to 1980. Among the countries reporting bigeye tuna catches Japan ranks first, followed by the Republic of Korea with much lower landings. The world catch increased from about 164 000 t in 1974 to 201 000 metric tons in 1980 reaching a peak of 214 000 t in 1977 (FAO, 1981). For 1981 a decrease to about 167 000 t was estimated (FAO, 1983). In the Indian Ocean, the bigeye tuna fishery was dominated by Japanese fleets up to the end of the sixties, but subsequently operations of vessels from the Republic of Korea became more important, and have accounted for more than 60% of the catch in the late seventies. The most important fishing technique is Industrial tuna longlining and the fishing gear longlines, comprise some 400 "baskets" (consisting of 5 branch lines, each with a baited hook) extending over up to 130 km. Species commonly used as bait include (frozen) Pacific saury (Cololabis saira ), chub mackerel (Scomber japonicus ), jack mackerel (Trachurus ) and squid. Day- and night-time operations are common throughout the year, but there are seasonal variations in apparent abundance reflected in changes of fishing effort. In the seventies, deep longlines employing between 10 and 15 branch lines per basket were introduced. This new type of gear is theoretically capable of fishing down to 300 m depth, as compared to the usual 170 m reached by traditional longline gear. Catch rates increased for about 3 years and then declined to previous levels again, suggesting that only a portion of the bigeye resources are exploited. Bigeye tuna is exploited in increasing quantities as associated catch of the spring and summer pole and lines fishery in the northwestern Pacific, and of the purse seines fishery in the eastern Pacific, both directed primarily at skipjack and yellowfin tuna. In Japan, its meat is highly priced and processed into sashimi in substitution for bluefin tuna.The total catch reported for this species to FAO for 1999 was 399 628 t. The countries with the largest catches were Japan (79 742 t) and Other nei (70 597 t).
- bibliographic citation
- FAO Species Catalogue. Vol. 2. Scombrids of the world. An annotated and illustrated catalogue of Tunas, Mackerels, Bonitos and related species known to date.Collette, B.B. & C.E. Nauen 1983.. FAO Fish. Synop., (125)Vol.2:137 p.
- author
- Food and Agriculture Organization of the UN
Diagnostic Description
provided by FAO species catalogs
A large species, deepest near middle of first dorsal fin base. Gillrakers 23 to 31 on first arch. Pectoral fins moderately long (22 to 31% of fork length) in large individuals (over 110 cm fork length), but very long (as long as in T. alalunga ) in smaller individuals (though in fish shorter than 40 cm they may be very short). In fish longer than 30 cm, ventral surface of liver striated. Swimbladder present. Vertebrae 18 precaudal plus 21 caudal. Colour: lower sides and belly whitish; a lateral iridescent blue band runs along sides in live specimens; first dorsal fin deep yellow, second dorsal and anal fins light yellow, finlets bright yellow edged with black.
- Alverson & Peterson, 1963 (Pacific)
- Calkins, 1980 (Pacific)
- Collette, 1978 (Species Identification Sheets, Western Central Atlantic), 1981 (Species Identification Sheets, Eastern Central Atlantic)
- Mimura, et al. 1936a (Indian Ocean)
- bibliographic citation
- FAO Species Catalogue. Vol. 2. Scombrids of the world. An annotated and illustrated catalogue of Tunas, Mackerels, Bonitos and related species known to date.Collette, B.B. & C.E. Nauen 1983.. FAO Fish. Synop., (125)Vol.2:137 p.
- author
- Food and Agriculture Organization of the UN
Distribution
provided by FAO species catalogs
Worldwide in tropical and subtropical waters of the Atlantic, Indian and Pacific oceans, but absent from the Mediterranean.
- bibliographic citation
- FAO Species Catalogue. Vol. 2. Scombrids of the world. An annotated and illustrated catalogue of Tunas, Mackerels, Bonitos and related species known to date.Collette, B.B. & C.E. Nauen 1983.. FAO Fish. Synop., (125)Vol.2:137 p.
- author
- Food and Agriculture Organization of the UN
Size
provided by FAO species catalogs
Maximum fork length over 200 cm; common to 180 cm (corresponding to an age of at least 3 years). The all-tackle angling record for the Pacific is a 197.3 kg fish from off Cabo Blanco, Peru in 1957. This fish was 236 cm long but it was not specified whether this pertained to fork length or total length. For the Atlantic, the all-tackle angling record is a 170.3 kg fish with a fork length of 206 cm taken off Ocean City, Maryland, USA in 1977. Maturity seems to be attained at 100 to 130 cm fork length in the eastern Pacific and in the Indian Ocean, and at about 130 cm in the central Pacific.
- bibliographic citation
- FAO Species Catalogue. Vol. 2. Scombrids of the world. An annotated and illustrated catalogue of Tunas, Mackerels, Bonitos and related species known to date.Collette, B.B. & C.E. Nauen 1983.. FAO Fish. Synop., (125)Vol.2:137 p.
- author
- Food and Agriculture Organization of the UN
Brief Summary
provided by FAO species catalogs
Epipelagic and mesopelagic in oceanic waters, occurring from the surface to about 250 m depth.Temperature and thermocline depth seem to be the main environmental factors governing the vertical and horizontal distribution of bigeye tuna. Water temperatures in which the species has been found range from 13° to 29° C, but the optimum range lies between 17° and 22° C. This coincides with the temperature range of the permanent thermocline. In fact, in the tropical western and central Pacific, major concentrations of T. obesus are in occurrence of the species is closely related to seasonal and climatic changes in surface temperature and thermocline Juveniles and small adults of bigeye tuna school at the surface in mono-species groups or together with yellowfin tuna and/or skipjack. Schools may be associated with floating objects. In the eastern Pacific some spawning is recorded between 10° N and 10° S throughout the year, with a peak from April through September in the northern hemisphere and between January and March in the southern hemisphere. Kume (1967) found a correlation between the occurrence of sexually inactive bigeye tuna and a decrease of surface temperature below 23° or 24° C. Mature fish spawn at least twice a year; the number of eggs per spawning has been estimated at 2.9 million to 6.3 million. The food spectrum of bigeye tuna covers a variety of fish species, cephalopods and crustaceans, thus not diverging significantly from that of other similar-sized tunas. Feeding occurs in daytime as well as at night.The main predators are large billfish and toothed whales.
- bibliographic citation
- FAO Species Catalogue. Vol. 2. Scombrids of the world. An annotated and illustrated catalogue of Tunas, Mackerels, Bonitos and related species known to date.Collette, B.B. & C.E. Nauen 1983.. FAO Fish. Synop., (125)Vol.2:137 p.
- author
- Food and Agriculture Organization of the UN
Diseases and Parasites
provided by Fishbase
Hexostoma sibi Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Köllikeria Infestation 5. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Metazoan Infection 1. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Dinurus Infestation. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Caligus Infestation 7. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Hexostoma thynni Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Pseudocycnus Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Koellikerioides Infestation 6. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Kudoa Infestation 3. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Dasyrhynchus Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Univietellodidymocytis Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Orbitonematobothrium Infection. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Neonematobothrioideis Infection. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Köllikeria Infestation 8. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Köllikeria Infestation 7. Parasitic infestations (protozoa, worms, etc.)
Diagnostic Description
provided by Fishbase
This large species is distinguished by the following characters: robust, fusiform body, slightly compressed from side to side; total gill rakers on first gill arch 23-31; dorsal fins separated only by a narrow interspace, the second followed by 8-10 finlets; anal fin followed by 7-10 finlets; pectoral fins moderately long (22 to 31% of fork length) in large specimens (over 110 cm FL), but very long (as long as in Thunnus alalunga) in smaller specimens; 2 flaps (interpelvic process) between pelvic fins; very small scales on body; corselet of larger and thicker scales developed, but not very distinct; caudal peduncle very slender, with a strong lateral keel between 2 smaller keels; ventral surface of liver striated; swimbladder present. Colour of back metallic dark blue, lower sides and belly whitish; a lateral iridescent blue band runs along sides in live specimens; first dorsal fin deep yellow, second dorsal and anal fins light yellow, finlets bright yellow edged with black (Ref. 9684).
Diseases and Parasites
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Areotestis Infection. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Tristomella Infestation 1. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 1. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 7. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 8. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 9. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 10. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystoides Infestation 4. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Nematobothrium Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Opisthorchinematobothrium Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Univietellodidymocytis Infestation. Parasitic infestations (protozoa, worms, etc.)
Life Cycle
provided by Fishbase
Are multiple spawners that may spawn every 1 or 2 days over several months (Ref. 30330). They spawn over periods of the full moon (Ref. 6390). Spawn throughout the year in tropical waters (Ref. 6390).
Migration
provided by Fishbase
Oceanodromous. Migrating within oceans typically between spawning and different feeding areas, as tunas do. Migrations should be cyclical and predictable and cover more than 100 km.
Morphology
provided by Fishbase
Dorsal spines (total): 13 - 14; Dorsal soft rays (total): 14 - 15; Analspines: 0; Analsoft rays: 14; Vertebrae: 39
Trophic Strategy
provided by Fishbase
Temperature and thermocline depth seem to be the main environmental factors governing the vertical and horizontal distribution of this species (Ref. 168). Bigeye tuna are more tolerant of lower temperatures and lower dissolved oxygen concentration than are other tunas and tend to occupy deeper waters (Ref. 30326). For example, during the day, adult bigeye tuna inhabit the thermocline zone at about 150-250 m in tropical waters where temperatures descend to almost 10°C, provided dissolved oxygen concentration is more than 1 mg per l (Ref. 28952, 30327). The tuna make occassional short ascents to 100 m or shallower (Ref. 6390).Young bigeye tuna have not been reported outside tropical waters (Ref. 30326). In Australia, bigeye tuna smaller than 20 kg may form surface-dwelling schools of similar sized fish with other species such as yellowfin tuna and skipjack tuna (Katsuwonus pelamis). Schools of only bigeye tuna are less common (Ref. 30328). In tropical waters, young bigeye tuna are often caught 50-100 m below floating objects such as logs and fish aggregating devices (Ref. 30326). Adults tend to be solitary (Ref. 6390). Behavioural studies in Hawaiian waters using ultrasonic tags (Ref. 30329) found that the distribution of adult bigeye tuna was closely correlated with the 15°C isotherm during the day (Ref. 6390). Like yellowfin tuna, bigeye tuna move into the warmer surface waters (within 50 m of the surface) at night. Feed during the day and at night. In Hawaii, more abundant in late fall through late spring.
Diseases and Parasites
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Hexostoma Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Hexostoma acutum Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Hexostoma grossum Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Capsala Infestation 3. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Caballerocotyla Infestation 9. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Caballerocotyla Infestation 8. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Caballerocotyla Infestation 4. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymozoon Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymosulcus Infestation 3. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Koellikerioides Infestation 3. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Euryphorous Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Euryphorous Infestation 1. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Caligus Infestation 18. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Caligus Infestation 17. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Brachiella Infestation. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Sphyriocephalus Disease. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Sphyriocephalus Infestation 1. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Neohexostoma Infestation 3. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Koellikerioides Infestation 4. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Koellikerioides Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystoides Infestation 7. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystoides Infestation 5. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 23. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation 20. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Didymocystis Infestation18. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Dermatodidymocystis Infestation. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Dermatodidymocystis vivipira Infection. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Dermatodidymocystis indicus Infection. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Cardicola Infestation 1. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Botulus Infection. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Tristomella Infestation 3. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Sibitrema Infection. Parasitic infestations (protozoa, worms, etc.)
Diseases and Parasites
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Nasicola Infestation 2. Parasitic infestations (protozoa, worms, etc.)
Biology
provided by Fishbase
Occur in areas where water temperatures range from 13°-29°C, but the optimum is between 17° and 22°C. Variation in occurrence is closely related to seasonal and climatic changes in surface temperature and thermocline. Juveniles and small adults school at the surface in mono-species groups or mixed with other tunas, may be associated with floating objects. Adults stay in deeper waters (Ref. 5377). Eggs and larvae are pelagic (Ref. 6390). Feed on a wide variety of fishes, cephalopods and crustaceans during the day and at night (Ref. 9340). Meat is highly prized and processed into sashimi in Japan. Marketed mainly canned or frozen (Ref. 9684), but also sold fresh (Ref. 9340).
Importance
provided by Fishbase
fisheries: highly commercial; gamefish: yes; price category: very high; price reliability: reliable: based on ex-vessel price for this species
分布
provided by The Fish Database of Taiwan
廣泛分布於全世界各熱帶及亞熱帶海域,其範圍涵蓋北緯40°-南緯30°間,唯地中海缺如。台灣各地均產,尤以東部及南部產量最多。
利用
provided by The Fish Database of Taiwan
熱帶及亞熱帶帶海域是重要之漁獲物,全世界年產量在100,000-500,000公噸。一般漁法包括延繩釣、圍網及流刺網等。可作生魚片或加工以及各種烹煮調理皆宜。
描述
provided by The Fish Database of Taiwan
體紡錘形,肥壯,橫切面近圓形,稍側扁;尾柄細,平扁,每側具發達的中央隆起脊,尾鰭基部每側另具小隆起脊2條。眼特大,大於吻長之半。上下頜各具細小尖齒一列。鰓耙正常,第一鰓弓上之鰓耙數為23-31。體被細小圓鱗,頭部無鱗,胸部鱗片特大,形成胸甲。第一背鰭具硬棘XIII-XIV,與第二背鰭起點距離相當近,其後具8-10個離鰭;臀鰭與第二背鰭同形,皆不特別延長而略呈鐮刀形,遠短於胸鰭長;胸鰭較頭長為長,幼時延伸至第一離鰭基底之下方,成魚則延伸至第二背鰭起點之後方;尾鰭新月形。體背側藍綠色,腹部銀白色。第一背鰭黃色;第二背鰭、臀鰭為淡黃色;離鰭淡黃色而具黑緣;胸鰭及尾鰭灰黑色。
棲地
provided by The Fish Database of Taiwan
大洋中上層洄游性魚類。常依季節之變化而在水表層或躍溫層的水域活動,常出現水域之水溫約在13℃-29℃之間,常因水團溫度之改變而有垂直分布現象。以洄游性之小型魚類,如鯖等為食,亦捕食甲殼類及頭足類等。
Bigeye tuna
provided by wikipedia EN
The bigeye tuna (Thunnus obesus) is a species of true tuna of the genus Thunnus, belonging to the wider mackerel family Scombridae. In Hawaiian, it is one of two species known as ʻahi, the other being the yellowfin tuna.[4] Bigeye tuna are found in the open waters of all tropical and temperate oceans, but not in the Mediterranean Sea.
Description
Bigeye tuna can grow up to 2.5 m (98 in; 8.2 ft) in length. Maximum weight of individuals probably exceeds 180 kg (400 lb), with the all-tackle angling record standing at 178 kg (392 lb). They are large, deep-bodied, streamlined fish with large heads and eyes. The pectoral fins are very long, reaching back beyond the start of the second dorsal fin in juveniles and the space between the first and second dorsal fin in adults. They have 13 or 14 dorsal spines.
Physiology
Bigeye tuna have a unique physiology which allows them to forage in deeper colder waters and tolerate oxygen-poor waters. Bigeye tuna are reported to tolerate ambient oxygen levels of 1.0 mL/L and routinely reach depths where ambient oxygen content is below 1.5 mL/L,[5] largely due to the presence of blood with a high oxygen affinity.[6] Vascular counter-current heat exchangers maintain body temperatures above ambient water temperature. These heat exchangers are engaged to conserve heat in deeper colder waters and are disengaged to allow rapid warming as the tuna ascend from cold water into warmer surface waters, providing short-latency, physiological thermoregulation.[7] The eyes of bigeye tuna are well developed and with a large spherical lens allowing their vision to function well in low light conditions.[5]
Life history
Conventional tagging data and counts of growth increments in otoliths (ear bones) of bigeye tuna have recorded a maximum age of 16 years.[8] Recorded lengths at which sexual maturity is attained varies geographically with a length at which 50% of fishes sampled are mature of 135 cm in the eastern Pacific Ocean and 102–105 cm in the western Pacific Ocean.[8][9] This translates to an age of maturity of 2 – 4 years. Differences in methods of studies may contribute to this variability. Spawning takes place across most months of the year in tropical regions of the Pacific Ocean, becoming seasonal at higher latitudes when sea surface temperatures are above 24 °C. In the northwestern tropical Atlantic spawning occurs in June and July, and in January and February in the Gulf of Guinea, which is the only known Atlantic nursery area.
Behavior
Vertical movement
Bigeye tuna undertake a distinct diel shift in vertical behaviour, generally descending at dawn to deeper, cooler waters and returning to shallower, warmer waters at dusk. During the day they can undertake vertical movements into waters of 300–500 m depth that can be as much as 20 °C cooler than surface waters.[10][11][12] Individuals undertake thermoregulatory behaviour whilst at depth, periodically returning from deeper, cooler waters to shallower, warmer waters to re-warm.[10][11] Across the Pacific Ocean the depths at which bigeye tuna spend the majority of their time during the day vary: in the eastern Pacific the majority of time is spent at 200–350 m; around Hawaii the majority of time is spent at 300–400 m and in the Coral Sea the majority of time is spent at 300–500 m. These suggest that bigeye tuna (or their prey) are tracking an optimum temperature (10-15 °C) which is shallower in the eastern Pacific Ocean than in the western Pacific Ocean.[13] The diel shift in the vertical behaviour of bigeye tuna has been suggested to be associated with the diel migration of their prey.[14] This is supported by the identification of a number of diurnally migrating species from the stomachs of bigeye tuna [15] and observations of close associations between bigeye tuna and the sound scattering layer both during the day and at night.[16]
Typical vertical behaviour of bigeye tuna shifts when fish associate with seamounts, buoys and fish aggregating devices, with individuals remaining in surface waters. Association with objects has been observed to occur over periods of approximately 10–30 days.[17] This associative behaviour of bigeye tuna (and also other species of tuna) is taken advantage of by fisheries with approximately 27% of all catches of tunas by purse seine vessels in the western and central Pacific Ocean derived from fish aggregating devices.[18]
Migration
Results from tagging studies show that bigeye tuna are capable of traversing ocean basins, but can also show a high degree of site fidelity to some regions.[13][19][20][21][22] One study suggested an annual migration influenced by water temperature, specifically that near the surface. Central Pacific bigeye migrate from subtropical waters in September to tropical waters in March. The fish also briefly travel outside these thermal ranges. Other data indicate similar Pacific-wide variations.[23]
Diet
Bigeye tuna primarily feed on epipelagic and mesopelagic fish, crustaceans and cephalopods.[15][24]
Commercial fishery
Bigeye tuna caught with three-pole one-line rig
Globally, approximately 450,500 metric tonnes of bigeye tuna were caught by commercial vessels in 2012.[25] Commercial fisheries for bigeye tuna are regionally managed within the Pacific Ocean by the Western and Central Pacific Fisheries Commission (WCPFC) [26] and the Inter-American Tropical Tuna Commission (IATTC).[27] In the Indian Ocean catches are managed by the Indian Ocean Tuna Commission (IOTC) [28] and in the Atlantic Ocean by the International Commission for the Conservation of Atlantic Tunas (ICCAT).[29] Regular stock assessments are carried out for bigeye tuna by each of the regional fisheries management organisations with bigeye tuna currently regarded as overfished in the western and central Pacific Ocean [30] and eastern Pacific Ocean,[31] close to or being overfished in the Atlantic Ocean [32] and not overfished in the Indian Ocean.[33] The majority of commercial catches across the Pacific Ocean is by purse seine fleets, while catches are dominated by longline fleets in the Indian and Atlantic Oceans. Various conservation measures have been introduced by the regional fisheries management organisations which apply to particular sized vessels and fleets and include measures such as spatial and temporal closures, trip duration limits, observer requirements and limits on catches [34][35][36][37]
Gallery
Threats
The bigeye tuna catch rates have also declined abruptly during the past half century, mostly due to increased industrial fisheries, with the ocean warming adding further stress to the fish species.[38]
Research indicates that increasing ocean temperatures are taking a toll on the tuna in the Indian Ocean, where rapid warming of the ocean has resulted in a reduction of marine phytoplankton.[38]
Conservation
Most seafood sustainability guides encourage consumption of other types of tuna. In 2010, Greenpeace International added bigeye tuna to its seafood red list. "The Greenpeace International seafood red list is a list of fish that are commonly sold in supermarkets around the world, and which have a very high risk of being sourced from unsustainable fisheries."[39]
References
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^ Collette, B.; Acero, A.; Amorim, A.F.; et al. (2011). "Thunnus obesus". The IUCN Red List of Threatened Species. 2011: e.T21859A9329255. doi:10.2305/IUCN.UK.2011-2.RLTS.T21859A9329255.en.
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^ "Thunnus obesus". Integrated Taxonomic Information System. Retrieved 9 December 2012.
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^ Froese, Rainer; Pauly, Daniel (eds.) (2018). "Thunnus obesus" in FishBase. February 2018 version.
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^ [1] Archived March 31, 2009, at the Wayback Machine
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^ a b "Archived copy" (PDF). Archived from the original (PDF) on 2015-06-05. Retrieved 2014-10-07.
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^ Lowe, T. E. (2000). "Blood oxygen-binding characteristics of bigeye tuna (Thunnus obesus), a high-energy-demand teleost that is tolerant of low ambient oxygen". Marine Biology. 136 (6): 1087–1098. doi:10.1007/s002270000255. S2CID 84769358.
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^ Holland, Kim N. (1992). "Physiological and behavioural thermoregulation in bigeye tuna (Thunnus obesus)". Nature. 358 (6385): 410–412. Bibcode:1992Natur.358..410H. doi:10.1038/358410a0. PMID 1641023. S2CID 4344226.
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^ a b Farley, Jessica H.; Clear, Naomi P.; Leroy, Bruno; Davis, Tim L. O.; McPherson, Geoff (2006). "CSIRO PUBLISHING - Marine & Freshwater Research". Csiro.au. 57 (7): 713–724. doi:10.1071/MF05255.
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^ Schaefer, Kurt M.; Fuller, Daniel W.; Miyabe, Naozumi (2005). "Reproductive Biology of Bigeye Tuna (Thunnus Obesus) in the Eastern and Central Pacific Ocean" (PDF) (Bulletin). 23 (1). La Jolla, California: Inter-American Tropical Tuna Commission: 7–8. Archived from the original (PDF) on 2015-12-22. Retrieved 2014-10-07.
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^ a b Schaefer, Kurt M. (2010). "Vertical movements, behavior, and habitat of bigeye tuna (Thunnus obesus) in the equatorial eastern Pacific Ocean, ascertained from archival tag data". Marine Biology. 157 (12): 2625–2642. doi:10.1007/s00227-010-1524-3. S2CID 85941049.
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^ a b Arrizabalaga, H. (2008). "Bigeye tuna (Thunnus obesus) vertical movements in the Azores Islands determined with pop-up satellite archival tags". Fisheries Oceanography. 17 (2): 74–83. doi:10.1111/j.1365-2419.2008.00464.x.
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^ Howell, Evan A. (2010). "Spatiotemporal variability in bigeye tuna (Thunnus obesus) dive behavior in the central North Pacific Ocean". Progress in Oceanography. 86 (1–2): 81–93. Bibcode:2010PrOce..86...81H. doi:10.1016/j.pocean.2010.04.013.
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^ a b Evans, Karen (2008). "Behaviour and habitat preferences of bigeye tuna (Thunnus obesus) and their influence on longline fishery catches in the western Coral Sea". Canadian Journal of Fisheries and Aquatic Sciences. 65 (11): 2427–2443. doi:10.1139/F08-148.
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^ Dagorn, L. (2000). "Movement patterns of large bigeye tuna (Thunnus obesus) in the open ocean, determined using ultrasonic telemetry". Marine Biology. 136 (2): 361–371. doi:10.1007/s002270050694. S2CID 84674342.
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^ a b Young, Jock W. (2010). "Feeding ecology and niche segregation in oceanic top predators off eastern Australia". Marine Biology. 157 (11): 2347–2368. doi:10.1007/s00227-010-1500-y. S2CID 85067043.
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^ Josse, Erwan (1998). "Simultaneous observations of tuna movements and their prey by sonic tracking and acoustic surveys". Hydrobiologia. 371/372: 61–69. doi:10.1023/A:1017065709190. S2CID 42568333.
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^ Musyl, Michael K. (2003). "Vertical movements of bigeye tuna (Thunnus obesus) associated with islands, buoys, and seamounts near the main Hawaiian Islands from archival tagging data". Fisheries Oceanography. 12 (3): 152–169. doi:10.1046/j.1365-2419.2003.00229.x.
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^ "Cambridge Journals Online - Aquatic Living Resources - Abstract - A critique of the ecosystem impacts of drifting and anchored FADs use by purse-seine tuna fisheries in the Western and Central Pacific Ocean". Archived from the original on 2014-10-10. Retrieved 2013-10-31.
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^ Sibert, John R. (2003). "Horizontal movements of bigeye tuna (Thunnus obesus) near Hawaii determined by Kalman filter analysis of archival tagging data". Fisheries Oceanography. 12 (3): 141–151. doi:10.1046/j.1365-2419.2003.00228.x.
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^ Hampton, John; Gunn, John (1998). "CSIRO PUBLISHING - Marine & Freshwater Research". Csiro.au. 49 (6): 475–489. doi:10.1071/mf97210.
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^ "Archived copy" (PDF). Archived from the original (PDF) on 2016-03-04. Retrieved 2014-10-07.
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^ Schaefer, Kurt (2015). "Movements, dispersion, and mixing of bigeye tuna (Thunnus obesus) tagged and released in the equatorial Central Pacific Ocean, with conventional and archival tags" (PDF). Fisheries Research. 161: 336–355. doi:10.1016/j.fishres.2014.08.018.
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^ Hyder, Patrick; Bigelow, Keith; Brainard, Russell; Seki, Michael; Firing, June; Flament, Pierre. "Migration and Abundance of Bigeye Tuna (Thunnus obesus), and Other Pelagic Species, Inferred from Catch Rates and Their Relation to Variations in the Ocean Environment" (PDF). Retrieved August 26, 2016.
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^ Potier, M.; F. Marsac; V. Lucas; R. Sabatie; J-P Hallier; F. Menard (2004). "Feeding partitioning among tuna taken in surface and mid--water layers: the case of yellowfin and bigeye in the western tropical indian ocean". Western Indian Ocean J. Mar. Sci. 3 (1): 51–62.
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^ "FAO Fisheries and Aquaculture Department. FAO yearbook. Fishery and Aquaculture Statistics. 2012/FAO annuaire. Statistiques des pêches et de l'aquaculture. 2012/FAO anuario. Estadísticas de pesca y acuicultura. 2012". fao.org.
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^ "Home - WCPFC". wcpfc.int.
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^ "Inter-American-Tropical-Tuna-Commission". iattc.org.
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^ "IOTC - Indian Ocean Tuna Commission / Commission des Thons de l'Océan Indien". iotc.org.
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^ "ICCAT". iccat.int.
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^ "Stock assessment of bigeye tuna in the western and central Pacific Ocean Rev 1 (25 July 2014)". wcpfc.int.
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^ "Archived copy" (PDF). Archived from the original (PDF) on 2014-10-14. Retrieved 2014-10-07.
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^ "Archived copy" (PDF). Archived from the original (PDF) on 2014-07-27. Retrieved 2014-10-07.
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^ "Stock assessment of bigeye tuna in the Indian Ocean for 2012". iotc.org.
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^ "Conservation and Management Measures (CMMs)". iotc.org.
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^ "Conservation and Management Measure for bigeye, yellowfin and skipjack tuna in the Western and Central Pacific Ocean". wcpfc.int.
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^ a b Roxy, Mathew Koll; Modi, Aditi; Murtugudde, Raghu; Valsala, Vinu; Panickal, Swapna; Prasanna Kumar, S.; Ravichandran, M.; Vichi, Marcello; Lévy, Marina (2016-01-28). "A reduction in marine primary productivity driven by rapid warming over the tropical Indian Ocean" (PDF). Geophysical Research Letters. 43 (2): 2015GL066979. Bibcode:2016GeoRL..43..826R. doi:10.1002/2015GL066979. ISSN 1944-8007.
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^ Greenpeace International Seafood Red list Archived February 5, 2010, at the Wayback Machine
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Bigeye tuna: Brief Summary
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The bigeye tuna (Thunnus obesus) is a species of true tuna of the genus Thunnus, belonging to the wider mackerel family Scombridae. In Hawaiian, it is one of two species known as ʻahi, the other being the yellowfin tuna. Bigeye tuna are found in the open waters of all tropical and temperate oceans, but not in the Mediterranean Sea.
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Description
provided by World Register of Marine Species
Occurs in areas where water temperatures range from 13°-29°C, but the optimum is between 17° and 22°C. Variation in occurrence is closely related to seasonal and climatic changes in surface temperature and thermocline. Juveniles and small adults school at the surface in mono-species groups or mixed with other tunas, may be associated with floating objects. Feeds on a wide variety of fishes, cephalopods and crustaceans during the day and at night (Ref. 9340). Spawning occurs in waters between 10°N and 10°S throughout the year but occurs most often from April up to the end of September (Ref. 9340). Meat is highly prized and processed into sashimi in Japan. Marketed mainly canned or frozen (Ref. 9684), but also sold fresh (Ref. 9340).
Froese, R. & D. Pauly (Editors). (2023). FishBase. World Wide Web electronic publication. version (02/2023).
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Diet
provided by World Register of Marine Species
Feed on a wide variety of fishes, cephalopods and crustaceans during the day and at night
North-West Atlantic Ocean species (NWARMS)
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Distribution
provided by World Register of Marine Species
Atlantic, Indian and Pacific: in tropical and subtropical waters. Absent in the Mediterranean
North-West Atlantic Ocean species (NWARMS)
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Habitat
provided by World Register of Marine Species
Occur in areas where water temperatures range from 13°-29°C, but the optimum is between 17° and 22°C. Variation in occurrence is closely related to seasonal and climatic changes in surface temperature and thermocline.
North-West Atlantic Ocean species (NWARMS)
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Habitat
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nektonic
North-West Atlantic Ocean species (NWARMS)
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Habitat
provided by World Register of Marine Species
Known from seamounts and knolls
Stocks, K. 2009. Seamounts Online: an online information system for seamount biology. Version 2009-1. World Wide Web electronic publication.
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