العربية
中国
Français
Deutsch
Ελληνική
हिन्दी
Italiano
日本語
Português
Русский
EspañolFISH ANATOMY
'Fish anatomy' is primarily governed by the physical characteristics of water, which is much denser than air, holds a relatively small amount of dissolved oxygen, and absorbs light more than air does.
2.png)
Fish have a variety of different body plans. Their body is divided into head, trunk, and tail, although the divisions are not always externally visible. The body is often 'fusiform', a streamlined body plan often found in fast-moving fish. They may also be 'filiform' (eel-shaped) or 'vermiform' (worm-shaped). Also, fish are often either laterally 'compressed' (thin) or vertically 'depressed' (flat).
The 'caudal peduncle' is the narrow part of the fish's body to which the caudal or tail fin is attached. The 'hypural joint' is the joint between the caudal fin and the last of the vertebrae. The hypural is often fan-shaped.
'Photophores' are light-emitting organs which appears as luminous spots on some fishes. The light can be produced from compounds during the digestion of prey, from specialized mitochondrial cells in the organism called photocytes, or associated with symbiotic bacteria, and are used for attracting food or confusing predators.
The 'lateral line' is a sense organ used to detect movement and vibration in the surrounding water. In most species, it consists of a line of receptors running along each side of the fish.
The 'ampullae of Lorenzini' allow sharks to sense electrical discharges.
The 'genital papilla' is a small, fleshy tube behind the anus in some fishes, from which the sperm or eggs are released; the sex of a fish often can be determined by the shape of its papilla.
The head includes the snout, from the 'eye' to the forwardmost point of the upper jaw, the 'operculum' or gill cover (absent in sharks), and the cheek, which extends from eye to preopercle. The operculum and preopercle may or may not have spines. The lower jaw defines a chin.
In lampreys, the mouth is formed into an 'oral disk'. In most jawed fish, however, there are three general configurations. The mouth may be on the forward end of the head ('terminal'), may be upturned ('superior'), or may be turned downwards or on the bottom of the fish ('subterminal' or 'inferior'). The mouth may be modified into a 'suckermouth' adapted for clinging onto objects in fast-moving water.
The head may have several fleshy structures known as 'barbels', which may be very long and resemble whiskers. Many fish species also have a variety of protrusions or spines on the head. The nostrils or 'nares' of almost all fishes do not connect to the oral cavity, but are pits of varying shape and depth.
Fish that feed on plankton and those with tube-shaped mouths (the Syngnathidae) may lack teeth. All other fish have teeth, in a wide range of configurations. The teeth are classified according to the bones they sit on:[1][2]
★ 'Premaxillary' and 'maxillary' teeth are on the upper jaw, and may extend to the very edges of their mouths.
★ 'Mandibulars' are associated with the dental bone in the lower jaw.
★ 'Vomerine', 'palatine', 'ectopterygoid', and 'parasphenoid' teeth are in the palate.
★ 'Pharyngeal teeth' located in the branchial bones of their throat, and are present in many species.
Some species, including salmonidae and osteoglossidae (meaning bony tongues), also have sharp teeth on dental plates on their tongue. Shark teeth are particularly unusual, having developed as modified scales.[3]
Tooth form is generally optimized for dietary function. Predatory fish may have sharp conical teeth, called canine (dog) teeth to hold prey. They generally hold a struggling baitfish until it is weakened, and then swallow it. Pharyngeal teeth help to block prey from escaping the throat. Non-predatory fish may have very different shapes of teeth; corallivorous have grinding teeth, and Scaridae (parrot fish) have plates of fused teeth for breaking coral.12
The fins are the most distinctive features of a fish.
In bony fish, most fins may have 'spines' or 'rays'. A fin can contain only spiny rays, only soft rays, or a combination of both. If both are present, the spiny rays are always anterior. Spines are generally stiff and sharp. Rays are generally soft, flexible, segmented, and may be branched. This segmentation of rays is the main difference that separates them from spines; spines may be flexible in certain species, but they will never be segmented.
Spines have a variety of uses. In catfish, they are used as a form of defense; many catfish have the ability to lock their spines outwards. Triggerfish also use spines to lock themselves in crevices to prevent being pulled out.
★ 'dorsal fins' are located on the back. A fish can have up to three of them. The dorsal fin serves to protect the fish against rolling and assist in sudden turns and stops.
★
★ In anglerfish, the anterior of the dorsal fin is modified into an 'illicium' and 'esca', a biological equivalent to a fishing pole and a lure.
★ The 'caudal fin' is the tail fin, located at the end of the caudal peduncle.
★
★ The tail can be 'heterocercal', which means that the vertebrae extend into a larger lobe of the tail or that the tail is asymmetrical
★
★
★ 'Epicercal' means that the upper lobe is longer (as in sharks)
★
★
★ 'Hypocercal' means that the lower lobe is longer (as in flying fish)
★
★ 'Protocercal' means that the caudal fin extends around the vertebral column, present in embryonic fish and hagfish. This is not to be confused with a caudal fin that has fused with the dorsal and anal fins to form a contiguous fin.
★
★ 'Diphycercal' refers to the special, three-lobed caudal fin of the coelacanth and lungfish where the vertebrae extend all the way to the end of the tail.
★
★ Most fish have a 'homocercal' tail, where the vertebrae do not extend into a lobe and the fin is more or less symmetrical. This can be expressed in a variety of shapes.
★
★
★ The tail fin may be 'rounded' at the end.
★
★
★ The tail fin may be 'truncated', or end in a more-or-less vertical edge (such as in salmon).
★
★
★ The tail fin may be 'forked', or end in two prongs.
★
★
★ The tail fin may be 'emarginate', or with a slight inward curve.
★
★
★ The tail fin may be 'lunate', or shaped like a crescent moon.
★ The 'anal fin' is located on the ventral surface behind the anus. This fin is used to stabilize the fish while swimming.
★ The paired 'pectoral fins' are located on each side, usually just behind the operculum, and are homologous to the forelimbs of tetrapods.
★
★ A peculiar function of pectoral fins, highly developed in some fish, is the creation of the dynamic lifting force that assists some fish, such as sharks, in maintaining depth and also enables the "flight" for flying fish._diagram_cropped.GIF)
★
★ In many fish, the pectoral fins aid in walking, especially in the lobe-like fins of some anglerfish and in the mudskipper.
★
★ Certain rays of the pectoral fins may be adapted into finger-like projections, such as in sea robins and flying gurnards.
★
★
★ The "horns" of manta rays and their relatives are called 'cephalic fins'; this is actually a modification of the anterior portion of the pectoral fin.
★ The paired 'pelvic' or 'ventral fins' are located ventrally below the pectoral fins. They are homologous to the hindlimbs of tetrapods.
★
★ In gobies, the pelvic fins are often fused into a single sucker disk. This can be used to attach to objects.
★ The 'adipose fin' is a soft, fleshy fin found on the back behind the dorsal fin and just forward of the caudal fin. It is absent in many fish families, but is found in Salmonidae, characins and catfishes.
★ Some types of fast-swimming fish have a horizontal 'caudal keel' just forward of the tail fin. This is a lateral ridge on the caudal peduncle, usually composed of scutes (see below), that provides stability and support to the caudal fin. There may be a single paired keel, one on each side, or two pairs above and below.
★ 'Finlets' are small fins, generally behind the dorsal and anal fins (in bichirs, there are only finlets on the dorsal surface and no dorsal fin). In some fish such as tuna or sauries, they are rayless, non-retractable, and found between the last dorsal and/or anal fin and the caudal fin.
For every fin, there are a number of fish species in which this particular fin has been lost during evolution.
In many species of fish, fins have been modified to allow internal fertilization.
A 'gonopodium' is a modified anal fin in males of certain species of live-bearing fish in the families Anablepidae and Poeciliidae. It is movable and used to impregnate females during mating. The male's anal fin’s 3rd, 4th and 5th rays are formed into a tube like structure in which the sperm of the fish is ejected. In some species, the gonopodium may be as much as 50% of the total body length. Occasionally the fin is too long to be used, as in the "lyretail" breeds of ''Xiphophorus helleri''. Hormone treated females may develop gonopodia. These are useless for breeding. One finds similar organs having the same characteristics in other types of fish, for example the 'andropodium' in the ''Hemirhamphodon'' or in the Goodeidae.
When ready for mating, the gonopodium becomes “erect” and points forward, towards the female. The male shortly inserts the organ into the sex opening of the female, with hook-like adaptations that allow the fish to grip onto the female to insure impregnation. If a female remains stationary and her partner contacts her vent with his gonopodium, she is fertilized. The sperm is preserved in the female's oviduct. This allows females to, at any time, fertilize themselves without further assistance of males.
Male cartilaginous fish have 'claspers' modified from pelvic fins. These are intromittent organs, used to channel semen into the female's cloaca during copulation.
The outer body of many fish is covered with 'scales'. Some species are covered instead by 'scutes'. Others have no outer covering on the skin; these are called 'naked' fish. Most fish are covered in a protective layer of slime (mucus).
There are four types of fish scales.
# 'Placoid scales', also called 'dermal denticles', are similar to teeth in that they are made of dentin covered by enamel. They are typical of sharks and rays.
# 'Ganoid scales' are flat, basal-looking scales that cover a fish body with little overlapping. They are typical of gar and bichirs.
# 'Cycloid scales' are small oval-shaped scales with growth rings. Bowfin and remora have cycloid scales.
# 'Ctenoid scales' are similar to the cycloid scales, with growth rings. They are distinguished by spines that cover one edge. Halibut have this type of scale.
Another, less common, type of scale is the 'scute', which is:
★ an external shield-like bony plate, or
★ a modified, thickened scale that often is keeled or spiny, or
★ a projecting, modified (rough and strongly ridged) scale, usually associated with the lateral line, or on the caudal peduncle forming caudal keels, or along the ventral profile. Some fish, such as pineconefish, are completely or partially covered in scutes.
★ The 'gas bladder', or swim bladder, is an internal organ that contributes to the ability of a fish to control its buoyancy, and thus to stay at the current water depth, ascend, or descend without having to waste energy in swimming. It is often absent in fast swimming fishes such as the tuna and mackerel families.
★ Certain groups of fish have modifications to allow them to hear, such as the Weberian apparatus of Ostariophysians.
★ The 'gills', located under the operculum, are a respiratory organ for the extraction of oxygen from water and for the excretion of carbon dioxide. They are not usually visible, but can be seen in some species, such as the frilled shark.
★ The 'labyrinth organ' of Anabantoidei and Clariidae is used to allow the fish to extract oxygen from the air.
★ 'Gill rakers' are bony, finger-like projections of the gill arch filaments which function in filter-feeders in retaining food organisms.
★ Electric fish are able to produce electric fields by modified muscles in their body.
★ Many fish species are hermaphrodites. ''Synchronous hermaphrodites'' possess both ovaries and testes at the same time. ''Sequential hermaphrodites'' have both types of tissue in their gonads, with one type being predominant while the fish belongs to the corresponding gender.[4]
★ Fish development
★ Ichthyology terms
★ Fish measurement
1. Alimentation. Comparative anatomy of the digestive system in fish.
2. Schultz, Ken. Ken Schultz's Field Guide to Saltwater Fish: Fish Anatomy (Excerpt). Wiley, 2003-10-31. ISBN 978-0-471-44995-9. Retrieved on 2007-07-17.
3. Moss, Melvin L., Sheila J. Jones, and Karl A. Piez. Calcified Ectodermal Collagens of Shark Tooth Enamel and Teleost Scale ''(Abstract)''. Science 1964-08-28: Vol. 145. no. 3635, pp. 940 - 942. Retrieved on 2007-07-17.
4. Developmental Biology, , Scott F., Gilbert, Sinauer Associates, Inc., 1994, ISBN 0878932496
| Contents |
| Body |
| Head |
| Teeth |
| Fins |
| Spines and rays |
| Types of fins |
| Internal fertilization |
| Skin |
| Internal organs |
| See also |
| References |
Body
''Lampanyctodes hectoris''
(1) - operculum (gill cover), (2) - lateral line, (3) - dorsal fin, (4) - adipose fin, (5) - caudal peduncle, (6) - caudal fin, (7) - anal fin, (8) - photophores, (9) - pelvic fins (paired), (10) - pectoral fins (paired)
(1) - operculum (gill cover), (2) - lateral line, (3) - dorsal fin, (4) - adipose fin, (5) - caudal peduncle, (6) - caudal fin, (7) - anal fin, (8) - photophores, (9) - pelvic fins (paired), (10) - pectoral fins (paired)
Fish have a variety of different body plans. Their body is divided into head, trunk, and tail, although the divisions are not always externally visible. The body is often 'fusiform', a streamlined body plan often found in fast-moving fish. They may also be 'filiform' (eel-shaped) or 'vermiform' (worm-shaped). Also, fish are often either laterally 'compressed' (thin) or vertically 'depressed' (flat).
The 'caudal peduncle' is the narrow part of the fish's body to which the caudal or tail fin is attached. The 'hypural joint' is the joint between the caudal fin and the last of the vertebrae. The hypural is often fan-shaped.
'Photophores' are light-emitting organs which appears as luminous spots on some fishes. The light can be produced from compounds during the digestion of prey, from specialized mitochondrial cells in the organism called photocytes, or associated with symbiotic bacteria, and are used for attracting food or confusing predators.
The 'lateral line' is a sense organ used to detect movement and vibration in the surrounding water. In most species, it consists of a line of receptors running along each side of the fish.
The 'ampullae of Lorenzini' allow sharks to sense electrical discharges.
The 'genital papilla' is a small, fleshy tube behind the anus in some fishes, from which the sperm or eggs are released; the sex of a fish often can be determined by the shape of its papilla.
Head
Parts of the head
The head includes the snout, from the 'eye' to the forwardmost point of the upper jaw, the 'operculum' or gill cover (absent in sharks), and the cheek, which extends from eye to preopercle. The operculum and preopercle may or may not have spines. The lower jaw defines a chin.
In lampreys, the mouth is formed into an 'oral disk'. In most jawed fish, however, there are three general configurations. The mouth may be on the forward end of the head ('terminal'), may be upturned ('superior'), or may be turned downwards or on the bottom of the fish ('subterminal' or 'inferior'). The mouth may be modified into a 'suckermouth' adapted for clinging onto objects in fast-moving water.
Positions of the fish's mouths:
(a) - terminal,
(b) - superior,
(c) - subterminal, inferior
(a) - terminal,
(b) - superior,
(c) - subterminal, inferior
The head may have several fleshy structures known as 'barbels', which may be very long and resemble whiskers. Many fish species also have a variety of protrusions or spines on the head. The nostrils or 'nares' of almost all fishes do not connect to the oral cavity, but are pits of varying shape and depth.
Teeth
Fish that feed on plankton and those with tube-shaped mouths (the Syngnathidae) may lack teeth. All other fish have teeth, in a wide range of configurations. The teeth are classified according to the bones they sit on:[1][2]
★ 'Premaxillary' and 'maxillary' teeth are on the upper jaw, and may extend to the very edges of their mouths.
★ 'Mandibulars' are associated with the dental bone in the lower jaw.
★ 'Vomerine', 'palatine', 'ectopterygoid', and 'parasphenoid' teeth are in the palate.
★ 'Pharyngeal teeth' located in the branchial bones of their throat, and are present in many species.
Some species, including salmonidae and osteoglossidae (meaning bony tongues), also have sharp teeth on dental plates on their tongue. Shark teeth are particularly unusual, having developed as modified scales.[3]
Tooth form is generally optimized for dietary function. Predatory fish may have sharp conical teeth, called canine (dog) teeth to hold prey. They generally hold a struggling baitfish until it is weakened, and then swallow it. Pharyngeal teeth help to block prey from escaping the throat. Non-predatory fish may have very different shapes of teeth; corallivorous have grinding teeth, and Scaridae (parrot fish) have plates of fused teeth for breaking coral.12
Fins
The fins are the most distinctive features of a fish.
Spines and rays
In bony fish, most fins may have 'spines' or 'rays'. A fin can contain only spiny rays, only soft rays, or a combination of both. If both are present, the spiny rays are always anterior. Spines are generally stiff and sharp. Rays are generally soft, flexible, segmented, and may be branched. This segmentation of rays is the main difference that separates them from spines; spines may be flexible in certain species, but they will never be segmented.
Spines have a variety of uses. In catfish, they are used as a form of defense; many catfish have the ability to lock their spines outwards. Triggerfish also use spines to lock themselves in crevices to prevent being pulled out.
Types of fins
★ 'dorsal fins' are located on the back. A fish can have up to three of them. The dorsal fin serves to protect the fish against rolling and assist in sudden turns and stops.
★
★ In anglerfish, the anterior of the dorsal fin is modified into an 'illicium' and 'esca', a biological equivalent to a fishing pole and a lure.
★ The 'caudal fin' is the tail fin, located at the end of the caudal peduncle.
types of caudal fin :
(A) - Heterocercal, (B) - Protocercal,
(C) - Homocercal, (D) - Diphycercal
(A) - Heterocercal, (B) - Protocercal,
(C) - Homocercal, (D) - Diphycercal
★
★ The tail can be 'heterocercal', which means that the vertebrae extend into a larger lobe of the tail or that the tail is asymmetrical
★
★
★ 'Epicercal' means that the upper lobe is longer (as in sharks)
★
★
★ 'Hypocercal' means that the lower lobe is longer (as in flying fish)
★
★ 'Protocercal' means that the caudal fin extends around the vertebral column, present in embryonic fish and hagfish. This is not to be confused with a caudal fin that has fused with the dorsal and anal fins to form a contiguous fin.
★
★ 'Diphycercal' refers to the special, three-lobed caudal fin of the coelacanth and lungfish where the vertebrae extend all the way to the end of the tail.
★
★ Most fish have a 'homocercal' tail, where the vertebrae do not extend into a lobe and the fin is more or less symmetrical. This can be expressed in a variety of shapes.
★
★
★ The tail fin may be 'rounded' at the end.
★
★
★ The tail fin may be 'truncated', or end in a more-or-less vertical edge (such as in salmon).
★
★
★ The tail fin may be 'forked', or end in two prongs.
★
★
★ The tail fin may be 'emarginate', or with a slight inward curve.
★
★
★ The tail fin may be 'lunate', or shaped like a crescent moon.
★ The 'anal fin' is located on the ventral surface behind the anus. This fin is used to stabilize the fish while swimming.
★ The paired 'pectoral fins' are located on each side, usually just behind the operculum, and are homologous to the forelimbs of tetrapods.
★
★ A peculiar function of pectoral fins, highly developed in some fish, is the creation of the dynamic lifting force that assists some fish, such as sharks, in maintaining depth and also enables the "flight" for flying fish.
_diagram_cropped.GIF)
Bigeye tuna ''Thunnus obesus'' showing finlets and keels.
Drawing by Dr Tony Ayling
Drawing by Dr Tony Ayling
★
★ In many fish, the pectoral fins aid in walking, especially in the lobe-like fins of some anglerfish and in the mudskipper.
★
★ Certain rays of the pectoral fins may be adapted into finger-like projections, such as in sea robins and flying gurnards.
★
★
★ The "horns" of manta rays and their relatives are called 'cephalic fins'; this is actually a modification of the anterior portion of the pectoral fin.
★ The paired 'pelvic' or 'ventral fins' are located ventrally below the pectoral fins. They are homologous to the hindlimbs of tetrapods.
★
★ In gobies, the pelvic fins are often fused into a single sucker disk. This can be used to attach to objects.
★ The 'adipose fin' is a soft, fleshy fin found on the back behind the dorsal fin and just forward of the caudal fin. It is absent in many fish families, but is found in Salmonidae, characins and catfishes.
★ Some types of fast-swimming fish have a horizontal 'caudal keel' just forward of the tail fin. This is a lateral ridge on the caudal peduncle, usually composed of scutes (see below), that provides stability and support to the caudal fin. There may be a single paired keel, one on each side, or two pairs above and below.
★ 'Finlets' are small fins, generally behind the dorsal and anal fins (in bichirs, there are only finlets on the dorsal surface and no dorsal fin). In some fish such as tuna or sauries, they are rayless, non-retractable, and found between the last dorsal and/or anal fin and the caudal fin.
For every fin, there are a number of fish species in which this particular fin has been lost during evolution.
Internal fertilization
In many species of fish, fins have been modified to allow internal fertilization.
A 'gonopodium' is a modified anal fin in males of certain species of live-bearing fish in the families Anablepidae and Poeciliidae. It is movable and used to impregnate females during mating. The male's anal fin’s 3rd, 4th and 5th rays are formed into a tube like structure in which the sperm of the fish is ejected. In some species, the gonopodium may be as much as 50% of the total body length. Occasionally the fin is too long to be used, as in the "lyretail" breeds of ''Xiphophorus helleri''. Hormone treated females may develop gonopodia. These are useless for breeding. One finds similar organs having the same characteristics in other types of fish, for example the 'andropodium' in the ''Hemirhamphodon'' or in the Goodeidae.
When ready for mating, the gonopodium becomes “erect” and points forward, towards the female. The male shortly inserts the organ into the sex opening of the female, with hook-like adaptations that allow the fish to grip onto the female to insure impregnation. If a female remains stationary and her partner contacts her vent with his gonopodium, she is fertilized. The sperm is preserved in the female's oviduct. This allows females to, at any time, fertilize themselves without further assistance of males.
Male cartilaginous fish have 'claspers' modified from pelvic fins. These are intromittent organs, used to channel semen into the female's cloaca during copulation.
Skin
The outer body of many fish is covered with 'scales'. Some species are covered instead by 'scutes'. Others have no outer covering on the skin; these are called 'naked' fish. Most fish are covered in a protective layer of slime (mucus).
There are four types of fish scales.
# 'Placoid scales', also called 'dermal denticles', are similar to teeth in that they are made of dentin covered by enamel. They are typical of sharks and rays.
# 'Ganoid scales' are flat, basal-looking scales that cover a fish body with little overlapping. They are typical of gar and bichirs.
# 'Cycloid scales' are small oval-shaped scales with growth rings. Bowfin and remora have cycloid scales.
# 'Ctenoid scales' are similar to the cycloid scales, with growth rings. They are distinguished by spines that cover one edge. Halibut have this type of scale.
Another, less common, type of scale is the 'scute', which is:
★ an external shield-like bony plate, or
★ a modified, thickened scale that often is keeled or spiny, or
★ a projecting, modified (rough and strongly ridged) scale, usually associated with the lateral line, or on the caudal peduncle forming caudal keels, or along the ventral profile. Some fish, such as pineconefish, are completely or partially covered in scutes.
Internal organs
★ The 'gas bladder', or swim bladder, is an internal organ that contributes to the ability of a fish to control its buoyancy, and thus to stay at the current water depth, ascend, or descend without having to waste energy in swimming. It is often absent in fast swimming fishes such as the tuna and mackerel families.
★ Certain groups of fish have modifications to allow them to hear, such as the Weberian apparatus of Ostariophysians.
★ The 'gills', located under the operculum, are a respiratory organ for the extraction of oxygen from water and for the excretion of carbon dioxide. They are not usually visible, but can be seen in some species, such as the frilled shark.
★ The 'labyrinth organ' of Anabantoidei and Clariidae is used to allow the fish to extract oxygen from the air.
★ 'Gill rakers' are bony, finger-like projections of the gill arch filaments which function in filter-feeders in retaining food organisms.
★ Electric fish are able to produce electric fields by modified muscles in their body.
★ Many fish species are hermaphrodites. ''Synchronous hermaphrodites'' possess both ovaries and testes at the same time. ''Sequential hermaphrodites'' have both types of tissue in their gonads, with one type being predominant while the fish belongs to the corresponding gender.[4]
See also
★ Fish development
★ Ichthyology terms
★ Fish measurement
References
1. Alimentation. Comparative anatomy of the digestive system in fish.
2. Schultz, Ken. Ken Schultz's Field Guide to Saltwater Fish: Fish Anatomy (Excerpt). Wiley, 2003-10-31. ISBN 978-0-471-44995-9. Retrieved on 2007-07-17.
3. Moss, Melvin L., Sheila J. Jones, and Karl A. Piez. Calcified Ectodermal Collagens of Shark Tooth Enamel and Teleost Scale ''(Abstract)''. Science 1964-08-28: Vol. 145. no. 3635, pp. 940 - 942. Retrieved on 2007-07-17.
4. Developmental Biology, , Scott F., Gilbert, Sinauer Associates, Inc., 1994, ISBN 0878932496
This article provided by Wikipedia. To edit the contents of this article, click here for original source.
psst.. try this: add to faves
