How are paired and unpaired fins of fish arranged? Paired fins of fish. Circulatory system in fish

Fish fins can be paired or unpaired. The paired ones include the thoracic P (pinna pectoralis) and the abdominal V (pinna ventralis); to the unpaired ones - dorsal D (pinna dorsalis), anal A (pinna analis) and caudal C (pinna caudalis). The exoskeleton of the fins of bony fishes consists of rays that can be branchy And unbranched. The upper part of the branched rays is divided into separate rays and has the appearance of a brush (branched). They are soft and located closer to the caudal end of the fin. Unbranched rays lie closer to the anterior edge of the fin and can be divided into two groups: articulated and non-articulated (spiny). Articulated the rays are divided along their length into separate segments; they are soft and can bend. Unarticulated– hard, with a sharp apex, tough, can be smooth or jagged (Fig. 10).

Figure 10 – Fin rays:

1 – unbranched, segmented; 2 – branched; 3 – prickly smooth; 4 – prickly jagged.

The number of branched and unbranched rays in the fins, especially in unpaired ones, is an important systematic feature. The rays are calculated and their number is recorded. Non-segmented (spiny) ones are designated by Roman numerals, branched ones - by Arabic numerals. Based on the calculation of the rays, a fin formula is compiled. So, pike perch has two dorsal fins. The first of them has 13-15 spiny rays (in different individuals), the second has 1-3 spines and 19-23 branched rays. The formula for the dorsal fin of pike perch is as follows: D XIII-XV, I-III 19-23. In the anal fin of pike perch, the number of spiny rays is I-III, branched 11-14. The formula for the anal fin of pike perch looks like this: A II-III 11-14.

Paired fins. All real fish have these fins. Their absence, for example, in moray eels (Muraenidae) is a secondary phenomenon, the result of late loss. Cyclostomes (Cyclostomata) do not have paired fins. This is a primary phenomenon.

The pectoral fins are located behind the gill slits of fish. In sharks and sturgeon, the pectoral fins are located in a horizontal plane and are inactive. These fish have a convex dorsal surface and a flattened ventral side of the body that gives them a resemblance to the profile of an airplane wing and creates lift when moving. Such an asymmetry of the body causes the appearance of a torque that tends to turn the fish’s head down. Pectoral fins and rostrum of sharks and sturgeons in functionally form a single system: directed at a small (8-10°) angle to the movement, they create additional lifting force and neutralize the effect of torque (Fig. 11). If a shark's pectoral fins are removed, it will raise its head upward to keep its body horizontal. In sturgeon fish, removal pectoral fins is not compensated for in any way due to poor flexibility of the body in the vertical direction, which is hampered by bugs, so when the pectoral fins are amputated, the fish sinks to the bottom and cannot rise. Since the pectoral fins and rostrum in sharks and sturgeons are functionally connected, the strong development of the rostrum is usually accompanied by a decrease in the size of the pectoral fins and their removal from the anterior part of the body. This is clearly noticeable in the hammerhead shark (Sphyrna) and the saw shark (Pristiophorus), whose rostrum is highly developed and the pectoral fins are small, whereas in sea ​​fox(Alopiias) and the blue shark (Prionace) the pectoral fins are well developed and the rostrum is small.

Figure 11 – Diagram of vertical forces arising during the forward movement of a shark or sturgeon fish in the direction of the longitudinal axis of the body:

1 - center of gravity; 2 – center of dynamic pressure; 3 – force of residual mass; V0– lift force created by the body; Vр– lifting force created by the pectoral fins; Vr– lifting force created by the rostrum; Vv– lifting force created by the pelvic fins; Vс– lift force created by the caudal fin; Curved arrows show the effect of torque.

The pectoral fins of bony fish, unlike the fins of sharks and sturgeons, are located vertically and can perform rowing movements back and forth. The main function of the pectoral fins of bony fishes is low-speed propulsion, allowing precise maneuvering when searching for food. The pectoral fins, together with the pelvic and caudal fins, allow the fish to maintain balance when motionless. The pectoral fins of stingrays, which evenly border their body, serve as the main propellers when swimming.

The pectoral fins of fish are very diverse in both shape and size (Fig. 12). In flying fish, the length of the rays can be up to 81% of the body length, which allows

Figure 12 – Shapes of pectoral fins of fish:

1 - flying fish; 2 – slider perch; 3 – keel belly; 4 – body; 5 – sea rooster; 6 - angler.

fish soar in the air. In freshwater fish, keelbellies from the Characin family, enlarged pectoral fins allow the fish to fly, reminiscent of the flight of birds. In gurnards (Trigla), the first three rays of the pectoral fins have turned into finger-like outgrowths, relying on which the fish can move along the bottom. Representatives of the order Anglerfish (Lophiiformes) have pectoral fins with fleshy bases that are also adapted to move along the ground and quickly bury themselves in it. Moving along hard substrates with the help of pectoral fins made these fins very mobile. When moving along the ground, anglerfish can rely on both pectoral and ventral fins. In catfish of the genus Clarias and blennies of the genus Blennius, the pectoral fins serve as additional supports during serpentine movements of the body while moving along the bottom. The pectoral fins of jumpers (Periophthalmidae) are arranged in a unique way. Their bases are equipped with special muscles that allow the fin to move forward and backward, and have a bend reminiscent of the elbow joint; The fin itself is located at an angle to the base. Living on coastal shallows, jumpers with the help of pectoral fins are able not only to move on land, but also to climb up plant stems, using the caudal fin with which they clasp the stem. With the help of pectoral fins, slider fish (Anabas) also move on land. Pushing off with their tail and clinging to plant stems with their pectoral fins and gill cover spines, these fish are able to travel from body of water to body of water, crawling hundreds of meters. In such bottom-dwelling fish as rock perches(Serranidae), sticklebacks (Gasterosteidae), and wrasse (Labridae), pectoral fins are usually wide, rounded, fan-shaped. When they work, undulation waves move vertically downward, the fish appears to be suspended in the water column and can rise upward like a helicopter. Fishes of the order Pufferfish (Tetraodontiformes), pipefish (Syngnathidae) and pipits (Hyppocampus), which have small gill slits (the gill cover is hidden under the skin), can make circular movements with their pectoral fins, creating an outflow of water from the gills. When the pectoral fins are amputated, these fish suffocate.

The pelvic fins perform mainly the function of balance and therefore, as a rule, are located near the center of gravity of the fish's body. Their position changes with the change in the center of gravity (Fig. 13). In low-organized fish (herring-like, carp-like) the pelvic fins are located on the belly behind the pectoral fins, occupying abdominal position. The center of gravity of these fish is on the belly, which is due to the non-compact position of the internal organs occupying a large cavity. In highly organized fish, the pelvic fins are located in the front of the body. This position of the pelvic fins is called thoracic and is characteristic primarily of most perciform fish.

The pelvic fins can be located in front of the pectoral fins - on the throat. This arrangement is called jugular, and it is typical for large-headed fish with a compact arrangement of internal organs. The jugular position of the pelvic fins is characteristic of all fish of the order Codfish, as well as large-headed fish of the order Perciformes: stargazers (Uranoscopidae), nototheniids (Nototheniidae), blennies (Blenniidae), etc. Pelvic fins are absent in fish with eel-shaped and ribbon-shaped bodies. In erroneous (Ophidioidei) fish, which have a ribbon-eel-shaped body, the pelvic fins are located on the chin and serve as organs of touch.

Figure 13 – Position of the ventral fins:

1 – abdominal; 2 – thoracic; 3 – jugular.

The pelvic fins can be modified. With their help, some fish attach to the ground (Fig. 14), forming either a suction funnel (gobies) or a suction disk (lumpfish, slugs). The ventral fins of sticklebacks, modified into spines, have a protective function, and in triggerfishes, the pelvic fins have the appearance of a spiny spine and, together with the spiny ray of the dorsal fin, are a protective organ. In male cartilaginous fish, the last rays of the ventral fins are transformed into pterygopodia - copulatory organs. In sharks and sturgeons, the pelvic fins, like the pectoral fins, serve as load-bearing planes, but their role is less than that of the pectoral fins, since they serve to increase lifting force.

Figure 14 - Modification of the pelvic fins:

1 – suction funnel in gobies; 2 - suction disk of a slug.

Cartilaginous fish.

Paired fins: The shoulder girdle looks like a cartilaginous semi-ring lying in the muscles of the body walls behind the gill region. On its lateral surface there are articular processes on each side. The part of the girdle lying dorsal to this process is called the scapular section, and the part ventral is called the coracoid section. At the base of the skeleton of the free limb (pectoral fin) there are three flattened basal cartilages, attached to the articular process of the shoulder girdle. Distal to the basal cartilages are three rows of rod-shaped radial cartilages. The rest of the free fin - its skin blade - is supported by numerous thin elastin threads.

The pelvic girdle is represented by a transversely elongated cartilaginous plate lying in the thickness of the abdominal muscles in front of the cloacal fissure. The skeleton of the ventral fins is attached to its ends. The pelvic fins have only one basal element. It is greatly elongated and one row of radial cartilages is attached to it. The rest of the free fin is supported by elastin threads. In males, the elongated basal element continues beyond the fin blade as the skeletal basis of the copulatory outgrowth.

Unpaired fins: Typically represented by a caudal, anal, and two dorsal fins. The tail fin of sharks is heterocercal, i.e. its upper lobe is significantly longer than the lower one. The axial skeleton, the spine, enters it. The skeletal base of the caudal fin is formed by elongated upper and lower vertebral arches and a number of radial cartilages attached to the upper arches of the caudal vertebrae. Most of the tail blade is supported by elastin threads. At the base of the skeleton of the dorsal and anal fins lie radial cartilages, which are embedded in the thickness of the muscles. The free blade of the fin is supported by elastin threads.

Bony fish.

Paired fins. Represented by pectoral and ventral fins. The shoulder girdle serves as support for the pectorals. The pectoral fin at its base has one row of small bones - radials, extending from the scapula (which makes up the shoulder girdle). The skeleton of the entire free fin blade consists of segmented skin rays. The difference from cartilaginous ones is the reduction of basalia. The mobility of the fins is increased, since the muscles are attached to the expanded bases of the skin rays, which movably articulate with the radials. The pelvic girdle is represented by paired flat triangular bones closely interlocking with each other, lying in the thickness of the muscles and not connected with the axial skeleton. Most teleost pelvic fins lack basalia in the skeleton and have reduced radials - the blade is supported only by cutaneous rays, the expanded bases of which are directly attached to the pelvic girdle.

Unpaired limbs.

Paired limbs. Review of the structure of paired fins in modern fish.

They are represented by dorsal, anal (subcaudal) and caudal fins. The anal and dorsal fins consist of bony rays, divided into internal (hidden in the thickness of the muscles) pterygiophores (corresponding to radials) and external fin rays - lepidotrichia. The caudal fin is asymmetrical. In it, a continuation of the spine is the urostyle, and behind and below it, like a fan, there are flat triangular bones - hypuralia, derivatives of the lower arches of underdeveloped vertebrae. This type of fin structure is externally symmetrical, but not internally - homocercal. The external skeleton of the caudal fin is composed of numerous skin rays - lepidotrichia.

There is a difference in the location of the fins in space - in cartilaginous ones it is horizontal to support it in the water, and in bony ones it is vertical, since they have a swim bladder. Fins perform various functions when moving:

• unpaired - dorsal, caudal and anal fins, located in the same plane, help the movement of the fish;
• The paired pectoral and pelvic fins maintain balance and also serve as a rudder and brake.

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Pelvic fin

Page 1

The pelvic fins are fused and form a sucker. Black, Azov, Caspian and Far East. Spawning in the spring, eggs are laid in nests, the clutch is guarded by the male.

Topic 3. FISH FINS, THEIR DESIGNATIONS,

The pelvic fins have 1–17 rays, sometimes there are no fins. Scales are cycloid or absent. Veliferidae) and opahaceae (Lampri-dae); 12 births, approx. All except Veliferidae live in the pelagic zone open ocean to depth

The rudiments of the pelvic fins appear. A notch on the dorsal edge of the fin fold marks the boundary between it and the growing caudal fin. There are more melanophores, some reaching the intestinal level.

The structure of the lancelet (diagram): / - central opening surrounded by tentacles; 2 - mouth; 3 - pharynx; 4 - gill slits: 5 - genitals: 6 - liver: 7 - intestine; 8 - anus; 9 - ventral fin: 10 - caudal fin; // - dorsal fin; / 2 - eyespot; 13 - olfactory fossa; 14 - brain; 15 - spinal cord; 16 - chord.

The pectoral and usually the dorsal and anal fins are absent. Pelvic fins with 2 rays or absent. The scales are cycloid or absent. The gill openings are connected into a single slit on the throat. The gills are usually reduced, and there are devices for air in the pharynx and intestines.

The pelvic fins are long, with 2–3 rays. Fossil forms are known from the Pleistocene and Holocene.

The anal and ventral fins are crimson. The iris of the eyes, unlike roaches, is greenish. Lives in rivers and reservoirs of Eurasia; in the USSR - in Europe. Siberia (before Lena), Puberty at 4 - 6 years.

The separation of the dorsal and anal fins begins. The rudiments of the pelvic fins appear. The rays in the caudal fin reach the posterior edge.

The dorsal and anal fins are long, almost reaching the caudal fin, the paired pelvic fins are in the form of long threads. The body of males has alternating blue and red transverse stripes; throat and parts of fins with metallic. Lives in overgrown reservoirs of the South. Produces sterile hybrids with labiaza (C.

Known from the Jurassic, they were numerous in the Cretaceous. In addition to the copula, organs (pterygopodia), formed from the outer rays of the ventral fins, males have spiny frontal and abdominal appendages that serve to hold the female.

The dorsal fin is short (7 - 14 rays), located above the ventral fins. They live in the waters of the North.

Haeckel): the formation of the gonads in higher animals in the mesoderm, and not in the ecto- or endoderm, as is the case in lower multicellular organisms; The formation and location of the paired ventral fins in some bony fishes is not behind, as usual, but in front of the pectoral fins.

Body laterally compressed or ovate, long. Pelvic fins are absent in some species. A network of seismosensory channels is developed on the head.

They are related to carpozoans and garfishes. There are usually 2 dorsal fins, the first one is made of flexible, unbranched rays, the ventral fins have 6 rays. The lateral line is poorly developed. Phallostethidae) and neostetidae (Neostethidae), ca.

The body in the anterior part is rounded, in the caudal part it is laterally compressed. The skin is covered with bony tubercles; the largest ones are arranged in longitudinal rows. The pelvic fins are modified into a round sucker. Adult fish are bluish-gray, the back is almost black; during spawning, the belly and fins of males are painted a deep red color.

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Fins and types of fish movement

Fins. Their sizes, shape, quantity, position and functions are different. The fins allow the body to maintain balance and participate in movement.

Rice. 1 Fins

The fins are divided into paired, corresponding to the limbs of higher vertebrates, and unpaired (Fig. 1).

TO doubles relate:

1) chest P ( pinna pectoralis);

2) abdominal V.

Paired fish fins

(R. ventralis).

TO unpaired:

1) dorsal D ( p. dorsalis);

2) anal A (R. analis);

3) tail C ( R. caudalis).

4) fat ar (( p.adiposa).

In salmonids, characins, killer whales, and others, there is a adipose fin(Fig. 2), devoid of fin rays ( p.adiposa).

Rice. 2 Adipose fin

Pectoral fins common among bony fish. In stingrays, the pectoral fins are enlarged and are the main organs of movement.

Pelvic fins occupy different positions in fish, which is associated with a movement of the center of gravity caused by contraction of the abdominal cavity and concentration of viscera in the front part of the body.

Abdominal position– pelvic fins are located in the middle of the abdomen (sharks, herring, carp) (Fig. 3).

Rice. 3 Abdominal position

Thoracic position– the pelvic fins are shifted to the front of the body (perciform) (Fig. 4).

Rice. 4 Thoracic position

Jugular position– the pelvic fins are located in front of the pectoral fins and on the throat (cod fins) (Fig. 5).

Rice. 5 Jugular position

Dorsal fins there may be one (herring-like, carp-like), two (mullet-like, perch-like) or three (cod-like). Their location is different. In pike, the dorsal fin is shifted back, in herrings and cyprinids it is located in the middle of the body, in fish with a massive front part of the body (perch, cod) one of them is located closer to the head.

Anal fin Usually there is one, cod has two, and the spiny shark does not have one.

Caudal fin has a varied structure.

Depending on the size of the upper and lower blades, they are distinguished:

1)isobathic type – in the fin the upper and lower blades are the same (tuna, mackerel);

Rice. 6 Isobath type

2)hypobate type – the lower blade is lengthened (flying fish);

Rice. 7 Hypobate type

3)epibate type – the upper blade is lengthened (sharks, sturgeon).

Rice. 8. Epibathic type

Based on their shape and location relative to the end of the spine, several types are distinguished:

1) Protocercal type - in the form of a fin border (lamrey) (Fig. 9).

Rice. 9 Protocercal type -

2) Heterocercal type – asymmetrical, when the end of the spine enters the upper, most elongated blade of the fin (sharks, sturgeon) (Fig. 10).

Rice. 10 Heterocercal type;

3) Homocercal type – externally symmetrical, with the modified body of the last vertebra extending into the upper lobe (bony) (

Rice. 11 Homocercal type

The fins are supported by fin rays. In fish, branched and unbranched rays are distinguished (Fig. 12).

Unbranched fin rays can be:

1)articulated (capable of bending);

2)inarticulate hard (spiny), which in turn are smooth and jagged.

Rice. 12 Types of fin rays

The number of rays in the fins, especially in the dorsal and anal, is a species characteristic.

The number of spiny rays is indicated by Roman numerals, and the branched rays - by Arabic numerals. For example, the dorsal fin formula for river perch is:

DXIII-XVII, I-III 12-16.

This means that the perch has two dorsal fins, the first of which consists of 13 - 17 spiny fins, the second of 2 - 3 spiny and 12-16 branched rays.

Functions of fins

• Caudal fin creates driving force, provides high maneuverability of the fish when turning, acts as a rudder.
• Thoracic and abdominal (paired fins ) maintain balance and act as rudders when turning and at depth.
• Dorsal and anal the fins act as a keel, preventing the body from rotating around its axis.

Habitats and external structure of fish

The habitat of fish is various bodies of water on our planet: oceans, seas, rivers, lakes, ponds. It is very vast: the area occupied by the oceans exceeds 70% of the Earth’s surface, and the most deep depressions They go 11 thousand meters deep into the oceans.

The variety of living conditions in water influenced the appearance of fish and contributed to a wide variety of body shapes: the emergence of many adaptations to living conditions, both in structure and in biological characteristics.

Overall plan external structure fish

On the head of the fish there are eyes, nostrils, a mouth with lips, and gill covers. The head smoothly transitions into the body. From gill covers The body continues to the anal fin. The body of the fish ends with a tail.

The outside of the body is covered with skin. Protects mucus-coated skin of most fish scales .

The locomotion organs of fish are fins . Fins are outgrowths of skin resting on bones. fin rays . The caudal fin is of greatest importance. On the lower sides of the body there are paired fins: pectoral and ventral. They correspond to the fore and hind limbs of terrestrial vertebrates. The position of paired fins varies among different fish. The dorsal fin is located on top of the fish’s body, and the anal fin is located below, closer to the tail. The number of dorsal and anal fins may vary.

On the sides of the body of most fish there is a kind of organ that senses the flow of water. This lateral line . Thanks to the lateral line, even blinded fish do not bump into obstacles and are able to catch moving prey. The visible part of the lateral line is formed by scales with holes. Through them, water penetrates into a channel stretching along the body, to which the endings of nerve cells approach. The lateral line may be intermittent, continuous, or completely absent.

Functions of fins

Thanks to fins, fish are able to move and maintain balance in aquatic environment. Deprived of fins, it turns over with its belly up, since the center of gravity is located in the dorsal part.

Unpaired fins (dorsal and anal) provide stability to the body. The caudal fin in the vast majority of fish performs the function of propulsion.

Paired fins (thoracic and abdominal) serve as stabilizers, i.e. provide a balanced position of the body when it is immobile. With their help, the fish supports the body in in the right position. When moving they serve load-bearing planes, driving. The pectoral fins move the fish's body when swimming slowly. The pelvic fins perform mainly a balancing function.

Fish have a streamlined body shape. It reflects the characteristics of the environment and lifestyle. In fish adapted to fast, long-term swimming in the water column ( tuna(2), mackerel, herring, cod, salmon ), “torpedo-shaped” body shape. In predators that practice quick throws at short distances ( pike, taimen, barracuda, garfish (1) , saury), it is “arrow-shaped”. Some fish adapted to long-term residence on the bottom ( stingray (6) , flounder (3) ), have a flat body. In some species, the body has a bizarre shape. For example, sea ​​Horse resembles a corresponding chess piece: its head is located at right angles to the axis of the body.

Sea Horses inhabit different oceans Globe. These fish surprise everyone who observes them: the body, like an insect, is enclosed in a shell, the prehensile tail of a monkey, the rotating eyes of a chameleon and, finally, a pouch like a kangaroo.

Although this cute fish can swim upright using the oscillatory movement of its dorsal fin, it is a poor swimmer and spends most of its time hanging, clinging to the seaweed with its tail and looking for small prey. The tubular snout of the skate acts like a pipette - when the cheeks are sharply inflated, the prey is quickly drawn into the mouth from a distance of up to 4 cm.

The smallest fish is considered Philippine bull Pandaku . Its length is about 7 mm. At one time fashionistas wore these fish in their ears. In crystal aquarium earrings!

The biggest fish is considered whale shark , which reaches a length of 15 m.

Additional fish organs

Some fish species (such as carp and catfish) have antennae around their mouths. These are additional organs of touch and determination of the taste of food. In many deep-sea fish (for example, deep sea anglerfish, hatchet fish, anchovy, photoblepharon ) luminous organs are developed.

There are protective spines on the scales of fish. They can be located in different parts of the body. For example, spines cover the body hedgehog fish .

Some fish, for example scorpionfish, sea dragon, wart They have organs of defense and attack - poisonous glands located at the base of the spines and fin rays.

Coverings of the body

On the outside, the skin of fish is covered with scales - thin translucent plates. The scales overlap each other with their ends, arranged in a tile-like manner. This provides

strong protection of the body and at the same time does not create obstacles to movement. Scales are formed special cells skin. The size of the scales varies: from microscopic to blackheads up to several centimeters Indian barbel . There is a wide variety of scales: in shape, strength, composition, quantity and some other characteristics.

Lie in the skin pigment cells - chromatophores : when they expand, the pigment grains spread over a larger space and the color of the body becomes bright. If the chromatophores contract, the pigment grains accumulate in the center, leaving most of the cell uncolored, and the body color fades. If pigment grains of all colors are evenly distributed inside the chromatophores, the fish has bright color; if pigment grains are collected in the centers of cells, the fish becomes almost colorless and transparent; if only yellow pigment grains are distributed among their chromatophores, the fish changes color to light yellow.

Chromatophores determine the diversity of fish colors, which are especially bright in the tropics. Thus, fish skin performs the function of external protection. It protects the body from mechanical damage, facilitates sliding, determines the color of the fish, and communicates with external environment. The skin contains organs that sense temperature and chemical composition water.

Color meaning

Pelagic fish often have a dark "back" and a light "belly" like this fish abadejo cod family.

Indian glass catfish can serve as a textbook for studying anatomy.

Many fish that live in the upper and middle layers of water have a darker color on the upper part of the body and a lighter color on the lower part. The silvery belly of the fish, if you look at the fish from below, will not stand out against the light background of the sky. In the same way, the dark back, if you look at the fish from above, will merge with the dark background of the bottom.

By studying the coloration of fish, you can see how it helps camouflage and imitate other species of organisms, observe the demonstration of danger and inedibility, as well as the presentation of other signals by fish.

During certain periods of life, many fish acquire bright mating colors. Often the color and shape of the fish complement each other.

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The hydrosphere is characterized by an extreme diversity of conditions. These are fresh, flowing and standing waters, as well as salty seas and oceans inhabited by organisms at different depths. To exist in such diverse conditions, fish have developed both general principles of structure that meet the requirements of the environment (smooth, elongated body without protrusions, covered with mucus and scales; pointed head with pressed gill covers; fin system; lateral line), and adaptations characteristic of individual groups (flattened body, light organs, etc.). Each species of fish has numerous and varied adaptations corresponding to a specific way of life.

The unpaired fins include the dorsal, anal and caudal fins.

The dorsal and anal fins act as stabilizers and resist lateral displacement of the body during tail action.

The large dorsal fin of sailfish acts as a rudder during sharp turns, greatly increasing the maneuverability of the fish when pursuing prey. The dorsal and anal fins of some fish act as propellers, imparting forward movement to the fish (Fig. 15).

Figure 15 – Shape of undulating fins in various fish:

1 - sea Horse; 2 – sunflower; 3 – moon fish; 4 – body; 5 – needlefish; 6 – flounder; 7 - electric eel.

Locomotion with the help of undulating movements of the fins is based on the wave-like movements of the fin plate, caused by successive transverse deflections of the rays. This method of movement is usually characteristic of fish with a short body length that are unable to bend the body - boxfishes, sunfish. Only due to the undulation of the dorsal fin do seahorses and pipefish move. Fishes such as flounders and sunfishes, along with the undulating movements of the dorsal and anal fins, swim by laterally curving their body.

Figure 16 – Topography of the passive locomotor function of unpaired fins in various fish:

1 – eel; 2 – cod; 3 – horse mackerel; 4 – tuna.

In slow-swimming fish with an eel-like body shape, the dorsal and anal fins, merging with the caudal fin, form in a functional sense a single fin bordering the body and have a passive locomotor function, since the main work falls on the body body. In fast-moving fish, as the speed of movement increases, the locomotor function is concentrated in the posterior part of the body and on the posterior parts of the dorsal and anal fins. An increase in speed leads to the loss of locomotor function by the dorsal and anal fins, reduction of their posterior sections, while the anterior sections perform functions not related to locomotion (Fig. 16).

In fast-swimming scombroid fish, the dorsal fin fits into a groove running along the back when moving.

Herring, garfish and other fish have one dorsal fin. Highly organized orders of bony fish (perciformes, mullets) usually have two dorsal fins. The first consists of spiny rays, which give it a certain lateral stability. These fish are called spiny-finned fish. Gadfish have three dorsal fins. Most fish have only one anal fin, but cod-like fish have two.

Some fish lack dorsal and anal fins. For example, there is no dorsal fin electric eel, the locomotor undulating apparatus of which is a highly developed anal fin; Stingrays do not have it either. Stingrays and sharks of the order Squaliformes do not have an anal fin.

Figure 17 – Modified first dorsal fin of the sticky fish ( 1 ) and anglerfish ( 2 ).

The dorsal fin can be modified (Fig. 17). Thus, in the sticky fish, the first dorsal fin moved to the head and turned into a suction disk. It is, as it were, divided by partitions into a number of independently acting smaller, and therefore relatively more powerful, suction cups. The septa are homologous to the rays of the first dorsal fin; they can bend back, taking an almost horizontal position, or straighten. Due to their movement, a suction effect is created. In anglerfish, the first rays of the first dorsal fin, separated from each other, turned into a fishing rod (ilicium). In sticklebacks, the dorsal fin has the appearance of separate spines that perform a protective function. In triggerfish of the genus Balistes, the first ray of the dorsal fin has a locking system. It straightens and is fixed motionless. You can remove it from this position by pressing the third spiny ray of the dorsal fin. With the help of this ray and the spiny rays of the ventral fins, the fish, when in danger, hides in crevices, fixing the body in the floor and ceiling of the shelter.

In some sharks, the rear elongated lobes of the dorsal fins create a certain lifting force. A similar, but more significant, supporting force is created by the anal fin with a long base, for example, in catfishes.

The caudal fin acts as the main mover, especially with the scombroid type of movement, being the force that imparts forward movement to the fish. It provides high maneuverability of fish when turning. There are several forms of the caudal fin (Fig. 18).

Figure 18 – Shapes of the caudal fin:

1 – protocentral; 2 – heterocercal; 3 – homocercal; 4 – diphycercal.

Protocercal, i.e., primarily equilobed, has the appearance of a border, and is supported by thin cartilaginous rays. The end of the chord enters central part and divides the fin into two equal halves. This is the most ancient type fin, characteristic of cyclostome and larval stages of fish.

Diphycercal – symmetrical externally and internally. The spine is located in the middle of equal blades. It is characteristic of some lungfishes and lobe-finned fishes. Of the bony fishes, garfish and cod have such a fin.

Heterocercal, or asymmetrical, unequally lobed. The upper blade expands, and the end of the spine, bending, enters it. This type of fin is characteristic of many cartilaginous fishes and cartilaginous ganoids.

Homocercal, or falsely symmetrical. This fin can be externally classified as equilobed, but the axial skeleton is distributed unequally in the blades: the last vertebra (urostyle) extends into the upper blade. This type of fin is widespread and characteristic of most bony fish.

According to the ratio of the sizes of the upper and lower blades, the caudal fins can be epi-, hypo- And isobathic(ecclesiastical). With the epibate (epicercal) type, the upper lobe is longer (sharks, sturgeons); with hypobate (hypocercal) the upper lobe is shorter (flying fish, sabrefish), with isobathic (isocercal) both lobes have the same length (herring, tuna) (Fig. 19). The division of the caudal fin into two blades is associated with the peculiarities of counter currents of water flowing around the body of the fish. It is known that a friction layer is formed around a moving fish - a layer of water, to which a certain additional speed is imparted by the moving body. As the fish develops speed, the boundary layer of water may separate from the surface of the fish's body and a zone of vortices may form. If the body of the fish is symmetrical (relative to its longitudinal axis), the zone of vortices that arises behind is more or less symmetrical relative to this axis. In this case, to exit the zone of vortices and the friction layer, the blades of the caudal fin lengthen equally - isobathism, isocercia (see Fig. 19, a). With an asymmetrical body: a convex back and a flattened ventral side (sharks, sturgeons), the vortex zone and the friction layer are shifted upward relative to the longitudinal axis of the body, therefore the upper lobe elongates to a greater extent - epibathicity, epicercia (see Fig. 19, b). If fish have a more convex ventral and straight dorsal surface (siberian fish), the lower lobe of the caudal fin lengthens, since the vortex zone and the friction layer are more developed on the lower side of the body - hypobate, hypocercion (see Fig. 19, c). The higher the speed of movement, the more intense the process of vortex formation and the thicker the friction layer, and the more developed the blades of the caudal fin, the ends of which should extend beyond the boundaries of the vortex zone and the friction layer, which ensures high speeds. In fast-swimming fish, the caudal fin has either a semilunar shape - short with well-developed sickle-shaped elongated blades (scombroids), or forked - the notch of the tail goes almost to the base of the fish's body (horse mackerel, herring). In sedentary fish, during the slow movement of which the processes of vortex formation almost do not take place, the blades of the caudal fin are usually short - a notched caudal fin (carp, perch) or not differentiated at all - rounded (burbot), truncated (sunfish, butterfly fish), pointed ( captain's croakers).

Figure 19 – Layout of the caudal fin blades relative to the vortex zone and friction layer at different shapes body:

A– with a symmetrical profile (isocercia); b– with a more convex profile contour (epicerkia); V– with a more convex lower contour of the profile (hypocercia). The vortex zone and friction layer are shaded.

The size of the caudal fin blades is usually related to the body height of the fish. The higher the body, the longer the caudal fin blades.

In addition to the main fins, fish may have additional fins on their body. These include fatty fin (pinna adiposa), located behind the dorsal fin above the anal fin and representing a fold of skin without rays. It is typical for fish of the Salmon, Smelt, Grayling, Characin and some catfish families. On the caudal peduncle of a number of fast-swimming fish, behind the dorsal and anal fins, there are often small fins consisting of several rays.

Figure 20 – Keels on the caudal peduncle of fish:

A– in the herring shark; b- in mackerel.

They act as dampers for turbulence generated during the movement of fish, which helps to increase the speed of fish (scombroid, mackerel). On the caudal fin of herrings and sardines there are elongated scales (alae), which act as fairings. On the sides of the caudal peduncle in sharks, horse mackerel, mackerel, and swordfish there are lateral keels, which help reduce the lateral bendability of the caudal peduncle, which improves the locomotor function of the caudal fin. In addition, the side keels serve as horizontal stabilizers and reduce vortex formation when the fish swims (Fig. 20).

Fins

organs of movement of aquatic animals. Among invertebrates, P. have pelagic forms of gastropods and cephalopods and setaceous-maxillary. In gastropods, the legs are a modified leg; in cephalopods, they are lateral folds of skin. The chaetomagnaths are characterized by lateral and caudal wings formed by folds of skin. Among modern vertebrates, cyclostomes, fish, some amphibians, and mammals have P. In cyclostomes there are only unpaired P.: anterior and posterior dorsal (in lampreys) and caudal.

In fish, there are paired and unpaired P. Paired ones are represented by anterior (thoracic) and posterior (abdominal) ones. In some fish, such as cod and blenny, the abdominal pectorals are sometimes located in front of the pectoral ones. The skeleton of paired limbs consists of cartilaginous or bone rays, which are attached to the skeleton of the limb girdles (See Limb girdles) ( rice. 1 ). The main function of paired propellers is the direction of fish movement in the vertical plane (depth rudders). In a number of fish, paired parasites perform the functions of active swimming organs (See Swimming) or are used for gliding in the air (in flying fish), crawling along the bottom, or moving on land (in fish that periodically leave the water, for example, in representatives of the tropical genus Periophthalmus , which, with the help of chest pectorals, can even climb trees). The skeleton of unpaired P. - dorsal (often divided into 2 and sometimes into 3 parts), anus (sometimes divided into 2 parts) and caudal - consists of cartilaginous or bone rays lying between the lateral muscles of the body ( rice. 2 ). The skeletal rays of the caudal vertebrae are connected to the posterior end of the spine (in some fish they are replaced by the spinous processes of the vertebrae).

The peripheral parts of the P. are supported by thin rays of horn-like or bone tissue. In spiny-finned fish, the anterior of these rays thicken and form hard spines, sometimes associated with poisonous glands. Muscles that stretch the lobe of the pancreas are attached to the base of these rays. The dorsal and anal parasites serve to regulate the direction of movement of the fish, but sometimes they can also be organs forward movement or perform additional functions (for example, attracting prey). The caudal part, which varies greatly in shape in different fish, is the main organ of movement.

During the evolution of vertebrates, P. fishes probably arose from a continuous skin fold, which ran along the back of the animal, went around the rear end of its body and continued on the ventral side to the anus, then divided into two lateral folds that continued to the gill slits; This is the position of the fin folds in the modern primitive chordate - Lancelet a. It can be assumed that during the evolution of animals, skeletal elements formed in some places of such folds and in the intervals the folds disappeared, which led to the emergence of unpaired folds in cyclostomes and fish, and paired ones in fish. This is supported by the presence of lateral folds or venom of spines in the most ancient vertebrates (some jawless animals, acanthodia) and the fact that in modern fish, paired spines are longer in the early stages of development than in adulthood. Among amphibians, unpaired amphibians, in the form of a fold of skin devoid of a skeleton, are present as permanent or temporary formations in most larvae living in water, as well as in adult caudate amphibians and the larvae of tailless amphibians. Among mammals, P. are found in cetaceans and lilacs that have switched to an aquatic lifestyle for the second time. Gypsy cetaceans (vertical dorsal and horizontal caudal) and lilacs (horizontal caudal) do not have a skeleton; these are secondary formations that are not homologous (see Homology) to the unpaired P. of fish. The paired limbs of cetaceans and lilacs, represented only by the anterior limbs (the hind limbs are reduced), have an internal skeleton and are homologous to the forelimbs of all other vertebrates.

Lit. Guide to Zoology, vol. 2, M.-L., 1940; Shmalgauzen I.I., Fundamentals of comparative anatomy of vertebrate animals, 4th ed., M., 1947; Suvorov E.K., Fundamentals of Ichthyology, 2nd ed., M., 1947; Dogel V.A., Zoology of invertebrates, 5th ed., M., 1959; Aleev Yu. G., Functional principles of the external structure of fish, M., 1963.

V. N. Nikitin.

Big Soviet encyclopedia. - M.: Soviet Encyclopedia. 1969-1978 .

See what “Fins” are in other dictionaries:

- (pterigiae, pinnae), organs of movement or regulation of body position of aquatic animals. Among invertebrates, pelagics have P. forms of certain mollusks (modified leg or fold of skin), bristle-jawed. In skullless fish and larvae of fish, the unpaired P.... ... Biological encyclopedic dictionary

Organs of movement or regulation of body position of aquatic animals (some mollusks, chaetognaths, lancelets, cyclostomes, fish, some amphibians and mammals, cetaceans and sirenids). They can be paired or unpaired. * * * FINS… … encyclopedic Dictionary

Organs of movement or regulation of body position of aquatic animals (some mollusks, chaetognaths, lancelets, cyclostomes, fish, some amphibians and mammals, cetaceans and sirenids). There are paired and unpaired fins … Big Encyclopedic Dictionary

The habitat of fish is all kinds of bodies of water on our planet: ponds, lakes, rivers, seas and oceans.

Fish occupy very vast territories; in any case, the ocean area exceeds 70% earth's surface. Add to this the fact that the deepest depressions go 11 thousand meters into the ocean depths and it becomes clear what spaces the fish own.

Life in water is extremely diverse, which could not but affect the appearance of fish, and led to the fact that the shape of their bodies is varied, like underwater life itself.

On the head of fish there are gill wings, lips and mouth, nostrils and eyes. The head transitions into the body very smoothly. Starting from the gill wings to the anal fin there is a body that ends with a tail.

Fins serve as organs of movement for fish. In essence, they are skin outgrowths that rest on bony fin rays. The most important thing for fish is the caudal fin. On the sides of the body, in its lower part, there are paired ventral and pectoral fins, which correspond to the hind and forelimbs of vertebrates living on the earth. U different types In fish, paired fins can be arranged in different ways. At the top of the fish’s body there is a dorsal fin, and at the bottom, next to the tail, there is an anal fin. Moreover, it is important to note that the number of anal and dorsal fins in fish can vary.

Most fish have an organ on the sides of their body that senses the flow of water, called the “lateral line.” Thanks to this, even a blind fish is able to catch moving prey without bumping into obstacles. The visible part of the lateral line consists of scales with holes.

Through these holes, water penetrates into a channel running along the body, where it is sensed by the endings of nerve cells passing through the channel. The lateral line in fish can be continuous, intermittent, or absent altogether.

Functions of fins in fish

Thanks to the presence of fins, fish are able to move and maintain balance in the water. If the fish is deprived of fins, it will simply turn over with its belly up, since the center of gravity of the fish is located in its dorsal part.

The dorsal and anal fins provide the fish with a stable body position, and the caudal fin in almost all fish is a kind of propulsion device.

As for the paired fins (pelvic and pectoral), they mainly perform a stabilizing function, since they provide an equilibrium body position when the fish is immobilized. With the help of these fins, the fish can take the body position it needs. In addition, they are load-bearing planes during the movement of the fish, and act as a rudder. As for the pectoral fins, they are a kind of small motor with which the fish moves during slow swimming. The pelvic fins are primarily used to maintain balance.

Body shape of fish

Fish are characterized by a streamlined body shape. This is a consequence of her lifestyle and habitat. For example, those fish that are adapted to long and fast swimming in the water column (for example, salmon, cod, herring, mackerel or tuna) have a body shape similar to a torpedo. Predators that practice lightning-fast throws over very short distances (for example, saury, garfish, taimen or) have an arrow-shaped body shape.

Some species of fish that are adapted to lying on the bottom for a long time, such as flounder or stingray, have a flat body. Selected species fish even have a bizarre body shape, which may resemble a chess knight, as can be seen in the horse, whose head is located perpendicular to the axis of the body.

The seahorse inhabits almost all sea waters on Earth. His body is encased in a shell like that of an insect, his tail is tenacious like that of a monkey, his eyes can rotate like those of a chameleon, and the picture is complemented by a bag similar to that of a kangaroo. And although this strange fish can swim, maintaining a vertical body position, using the vibrations of the dorsal fin to do this, it is still a useless swimmer. The seahorse uses its tubular snout as a “hunting pipette”: when prey appears nearby, the seahorse sharply inflates its cheeks and pulls the prey into its mouth from a distance of 3-4 centimeters.

The smallest fish is the Philippine goby Pandaku. Its length is about seven millimeters. It even happened that women of fashion wore this bull in their ears, using aquarium earrings made of crystal.

But the largest fish is the fish, whose body length is sometimes about fifteen meters.

Additional organs in fish

In some fish species, such as catfish or carp, antennae can be seen around the mouth. These organs perform a tactile function and are also used to determine taste qualities food. Many deep sea fish, such as photoblepharon, anchovy, hatchet fish and have luminous organs.

On the scales of fish you can sometimes find protective spines, which can be located in different parts of the body. For example, the body of a hedgehog fish is almost completely covered with spines. Certain species of fish, such as the wart, sea dragon and, have special organs of attack and defense - poisonous glands, which are located at the base of the fin rays and the base of the spines.

Body coverings in fish

On the outside, the skin of fish is covered with thin translucent plates - scales. The ends of the scales overlap each other, arranged like tiles. On the one hand, this provides the animal with strong protection, and on the other hand, it does not interfere free movement in water. The scales are formed by special skin cells. The size of the scales can vary: in those they are almost microscopic, while in the Indian longhorned beetle they are several centimeters in diameter. Scales are distinguished by great diversity, both in their strength and in quantity, composition and a number of other characteristics.

The skin of fish contains chromatophores (pigment cells), when they expand, the pigment grains spread over a significant area, making the color of the body brighter. If the chromatophores are reduced, then the pigment grains will accumulate in the center and most of the cell will remain uncolored, due to which the body of the fish will become paler. When pigment grains of all colors are evenly distributed inside the chromatophores, the fish has a bright color, and if they are collected in the centers of the cells, the fish will be so colorless that it may even appear transparent.

If only yellow pigment grains are distributed among the chromatophores, the fish will change its color to light yellow. All the variety of colors of fish is determined by chromatophores. This is especially typical for tropical waters. In addition, the skin of fish contains organs that sense the chemical composition and temperature of the water.

From all of the above, it becomes clear that the skin of fish performs many functions at once, including external protection, protection from mechanical damage, communication with the external environment, communication with relatives, and facilitating gliding.

The role of color in fish

Pelagic fish often have a dark back and a light-colored belly, for example, like a representative of the family cod fish abadejo. In many fish that live in the middle and upper layers of water, the color of the upper part of the body is much darker than the lower part. If you look at such fish from below, then its light belly will not stand out against the light background of the sky shining through the water column, which disguises the fish from those lying in wait for it. sea ​​predators. In the same way, when viewed from above, its dark back merges with the dark background of the seabed, which protects not only from predatory sea animals, but also from various fishing birds.

If you analyze the coloration of fish, you will notice how it is used to imitate and camouflage other organisms. Thanks to this, the fish demonstrates danger or inedibility, and also gives signals to other fish. IN mating season, many species of fish tend to acquire very bright colors, while the rest of the time they try to blend in with their environment or imitate a completely different animal. Often this color camouflage is complemented by the shape of the fish.

Internal structure of fish

The musculoskeletal system of fish, like that of land animals, consists of muscles and a skeleton. The skeleton is based on the spine and skull, consisting of individual vertebrae. Each vertebra has a thickened part called the vertebral body, as well as lower and upper arches. Together, the upper arches form a canal in which the spinal cord is located, which is protected from injury by the arches. In the upper direction, long spinous processes extend from the arches. In the body part the lower arches are open. In the caudal part of the spine, the lower arches form a canal through which blood vessels pass. The ribs are adjacent to the lateral processes of the vertebrae and perform a number of functions, primarily protecting the internal organs and creating the necessary support for the muscles of the trunk. The most powerful muscles in fish are located in the tail and back.

The skeleton of a fish includes bones and bony rays of both paired and unpaired fins. In unpaired fins, the skeleton consists of many elongated bones attached to the thickness of the muscles. There is a single bone in the abdominal girdle. The free pelvic fin has a skeleton consisting of many long bones.

The skeleton of the head also includes a small skull. The bones of the skull serve as protection for the brain, but most of the skeleton of the head is occupied by the bones of the upper and mandibles, bones gill apparatus and eye sockets. Speaking about the gill apparatus, we can primarily note the large gill covers. If you lift the gill covers slightly, then underneath you can see paired gill arches: left and right. Gills are located on these arches.

As for the muscles, there are few of them in the head; they are located mostly in the area of ​​the gill covers, on the back of the head and jaws.

The muscles that provide movement are attached to the skeletal bones. The main part of the muscles is evenly located in the dorsal part of the animal’s body. The most developed are the muscles that move the tail.

The functions of the musculoskeletal system in the fish body are very diverse. The skeleton serves as protection for internal organs, bony fin rays protect the fish from rivals and predators, and the entire skeleton in combination with muscles allows this inhabitant of the waters to move and protect itself from collisions and impacts.

Digestive system in fish

Begins digestive system a large mouth, which is located in front of the head and is armed with jaws. There are large small teeth. Behind the oral cavity is the pharyngeal cavity, in which you can see the gill slits, which are separated by interbranchial septa on which the gills are located. Outside, the gills are covered with gill covers. Next is the esophagus, followed by a fairly voluminous stomach. Behind it is the intestine.

The stomach and intestines, using the action of digestive juices, digest food, and gastric juice acts in the stomach, and in the intestine several juices are secreted by the glands of the intestinal walls, as well as the walls of the pancreas. Bile coming from the liver and gallbladder is also involved in this process. Water and food digested in the intestines are absorbed into the blood, and undigested remains are thrown out through the anus.

A special organ that is found only in bony fish is the swim bladder, which is located under the spine in the body cavity. The swim bladder arises during embryonic development as a dorsal outgrowth of the intestinal tube. In order for the bladder to be filled with air, the newly born fry floats to the surface of the water and swallows air into its esophagus. After some time, the connection between the esophagus and the swim bladder is interrupted.

It is interesting that some fish use their swim bladder as a means by which they amplify the sounds they make. True, some fish do not have a swim bladder. Usually these are those fish that live on the bottom, as well as those that are characterized by vertical rapid movements.

Thanks to the swim bladder, the fish does not sink under its own weight. This organ consists of one or two chambers and is filled with a mixture of gases, which in its composition is close to air. The volume of gases contained in the swim bladder can change when they are absorbed and released through the blood vessels of the swim bladder walls, as well as when air is swallowed. Thus, specific gravity fish and the volume of its body and can change in one direction or another. The swim bladder provides the fish with balance between its body mass and the buoyant force acting on it at a certain depth.

Gill apparatus in fish

As a skeletal support for the gill apparatus, fish serve four pairs of gill arches located in a vertical plane, to which the gill plates are attached. They consist of fringe-like gill filaments.

Inside the gill filaments there are blood vessels that branch into capillaries. Gas exchange occurs through the walls of the capillaries: oxygen is absorbed from the water and carbon dioxide is released back. Thanks to the contraction of the muscles of the pharynx, as well as due to the movements of the gill covers, water moves between the gill filaments, which have gill rakers that protect the delicate soft gills from clogging them with food particles.

Circulatory system in fish

Schematically, the circulatory system of fish can be depicted as a closed circle consisting of vessels. The main organ of this system is the two-chamber heart, consisting of an atrium and a ventricle, which ensures blood circulation throughout the animal’s body. Moving through the vessels, blood ensures gas exchange, as well as the transfer nutrients in the body, and some other substances.

In fish, the circulatory system includes one circulation. The heart sends blood to the gills, where it is enriched with oxygen. This oxygenated blood is called arterial blood, and is carried throughout the body, distributing oxygen to the cells. At the same time, it is saturated with carbon dioxide (in other words, it becomes venous), after which the blood returns back to the heart. It should be recalled that in all vertebrates, the vessels leaving the heart are called arteries, while those returning to it are called veins.

The excretory organs in fish are responsible for removing metabolic end products from the body, filtering blood and removing water from the body. They are represented by paired kidneys, which are located along the spine by the ureters. Some fish have a bladder.

The kidneys remove excess fluid from the blood vessels, harmful products exchange and salts. The ureters carry urine into the bladder, from where it is pumped out. Externally, the urinary canal opens with an opening located slightly behind the anus.

Through these organs, the fish removes excess salts, water and metabolic products harmful to the body.

Metabolism in fish

Metabolism is the totality of chemical processes occurring in the body. The basis of metabolism in any organism is the construction of organic substances and their breakdown. When complex organic substances enter the fish’s body along with food, during the process of digestion they are transformed into less complex ones, which, being absorbed into the blood, are carried throughout the cells of the body. There they form the proteins, carbohydrates and fats required by the body. Of course, this uses up the energy released during breathing. At the same time, many substances in cells break down into urea, carbon dioxide and water. Therefore, metabolism is a combination of the process of construction and breakdown of substances.

The intensity with which metabolism occurs in a fish’s body depends on its body temperature. Since fish are animals with variable temperature bodies, that is, cold-blooded, then their body temperature is in close proximity to the ambient temperature. As a rule, the body temperature of fish does not exceed the ambient temperature by more than one degree. True, in some fish, for example tuna, the difference can be about ten degrees.

Nervous system of fish

The nervous system is responsible for the coherence of all organs and systems of the body. It also ensures the body’s response to certain changes in the environment. It consists of a central nervous system(spinal cord and brain) and the peripheral nervous system (branches extending from the brain and spinal cord). The fish brain consists of five sections: the anterior, which includes the optic lobes, the middle, intermediate, cerebellum and medulla oblongata. In all active pelagic fish, the cerebellum and optic lobes are quite large, since they need fine coordination and good vision. The medulla oblongata in fish passes into the spinal cord, ending in the caudal spine.

With the help of the nervous system, the fish’s body responds to irritations. These reactions are called reflexes, which can be divided into conditioned reflexes and unconditional. The latter are also called innate reflexes. Unconditioned reflexes manifest themselves in the same way in all animals belonging to the same species, while conditioned reflexes are individual and are developed during the life of a particular fish.

Sense organs in fish

The sense organs of fish are very well developed. The eyes are able to clearly recognize objects on close range and distinguish colors. Fish perceive sounds through the inner ear located inside the skull, and smells are recognized through the nostrils. In the oral cavity, the skin of the lips and antennae, there are taste organs that allow fish to distinguish between salty, sour and sweet. The lateral line, thanks to the sensitive cells located in it, reacts sensitively to changes in water pressure and transmits corresponding signals to the brain.

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