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Fish locomotion

January 01, 1970

Fish locomotion is the various types of animal locomotion used by fish, principally by swimming. This is achieved in different groups of fish by a variety of mechanisms of propulsion, most often by wave-like lateral flexions of the fish's body and tail in the water, and in various specialised fish by motions of the fins. The major forms of locomotion in fish are:

  • Anguilliform, in which a wave passes evenly along a long slender body;
  • Sub-carangiform, in which the wave increases quickly in amplitude towards the tail;
  • Carangiform, in which the wave is concentrated near the tail, which oscillates rapidly;
  • Thunniform, rapid swimming with a large powerful crescent-shaped tail; and
  • Ostraciiform, with almost no oscillation except of the tail fin.
Fish, like these yellowfin tuna, use many different mechanisms to propel themselves through water

More specialized fish include movement by pectoral fins with a mainly stiff body, opposed sculling with dorsal and anal fins, as in the sunfish; and movement by propagating a wave along the long fins with a motionless body, as in the knifefish or featherbacks.

In addition, some fish can variously "walk" (i.e., crawl over land using the pectoral and pelvic fins), burrow in mud, leap out of the water and even glide temporarily through the air.

Swimming edit

Mechanism edit

Further information: Fish fin
 
Fins used for locomotion: (1) pectoral fins (paired), (2) pelvic fins (paired), (3) dorsal fin, (4) adipose fin, (5) anal fin, (6) caudal (tail) fin

Fish swim by exerting force against the surrounding water. There are exceptions, but this is normally achieved by the fish contracting muscles on either side of its body in order to generate waves of flexion that travel the length of the body from nose to tail, generally getting larger as they go along. The vector forces exerted on the water by such motion cancel out laterally, but generate a net force backwards which in turn pushes the fish forward through the water. Most fishes generate thrust using lateral movements of their body and caudal fin, but many other species move mainly using their median and paired fins. The latter group swim slowly, but can turn rapidly, as is needed when living in coral reefs for example. But they can not swim as fast as fish using their bodies and caudal fins.[1][2]

 
Skeletal anatomy of Tilapia[3]

Consider the tilapia shown in the diagram. Like most fish, the tilapia has a streamlined body shape reducing water resistance to movement and enabling the tilapia to cut easily through water. Its head is inflexible, which helps it maintain forward thrust.[3] Its scales overlap and point backwards, allowing water to pass over the fish without unnecessary obstruction. Water friction is further reduced by mucus which tilapia secrete over their body.[3]

 
Like a plane or submarine, a fish has six degrees of freedom.

The backbone is flexible, allowing muscles to contract and relax rhythmically and bring about undulating movement.[3] A swim bladder provides buoyancy which helps the fish adjust its vertical position in the water column. A lateral line system allows it to detect vibrations and pressure changes in water, helping the fish to respond appropriately to external events.[3]

Well developed fins are used for maintaining balance, braking and changing direction. The pectoral fins act as pivots around which the fish can turn rapidly and steer itself. The paired pectoral and pelvic fins control pitching, while the unpaired dorsal and anal fins reduce yawing and rolling. The caudal fin provides raw power for propelling the fish forward.[3]

Body/caudal fin propulsion edit

There are five groups that differ in the fraction of their body that is displaced laterally:[1]

Anguilliform edit

"Anguilliform" and "Anguilliforms" redirect here. For Anguilliformes, the order of ray-finned fishes, see Eel.
 
Eels propagate a more or less constant-sized flexion wave along their slender bodies.

In the anguilliform group, containing some long, slender fish such as eels, there is little increase in the amplitude of the flexion wave as it passes along the body.[1][4]

Subcarangiform edit

The subcarangiform group has a more marked increase in wave amplitude along the body with the vast majority of the work being done by the rear half of the fish. In general, the fish body is stiffer, making for higher speed but reduced maneuverability. Trout use sub-carangiform locomotion.[1]

Carangiform edit

"Carangiform" and "Carangiforms" redirect here. For the order of ray-finned fishes, see Carangiformes.

The carangiform group, named for the Carangidae, are stiffer and faster-moving than the previous groups. The vast majority of movement is concentrated in the very rear of the body and tail. Carangiform swimmers generally have rapidly oscillating tails.[1]

Thunniform edit

 
Tunas such as the bluefin swim fast with their large crescent-shaped tails.

The thunniform group contains high-speed long-distance swimmers, and is characteristic of tunas[5] and is also found in several lamnid sharks.[6] Here, virtually all the sideways movement is in the tail and the region connecting the main body to the tail (the peduncle). The tail itself tends to be large and crescent shaped.[1]

Ostraciiform edit

The ostraciiform group have no appreciable body wave when they employ caudal locomotion. Only the tail fin itself oscillates (often very rapidly) to create thrust. This group includes Ostraciidae.[1]

Median/paired fin propulsion edit

 
Boxfish use median-paired fin swimming, as they are not well streamlined, and use primarily their pectoral fins to produce thrust.
See also: Batoid locomotion

Not all fish fit comfortably in the above groups. Ocean sunfish, for example, have a completely different system, the tetraodontiform mode, and many small fish use their pectoral fins for swimming as well as for steering and dynamic lift. Fish in the order Gymnotiformes possess electric organs along the length of their bodies and swim by undulating an elongated anal fin while keeping the body still, presumably so as not to disturb the electric field that they generate.

Many fish swim using combined behavior of their two pectoral fins or both their anal and dorsal fins. Different types of Median paired fin propulsion can be achieved by preferentially using one fin pair over the other, and include rajiform, diodontiform, amiiform, gymnotiform and balistiform modes.[2]

Rajiform edit

Rajiform locomotion is characteristic of rays and skates, when thrust is produced by vertical undulations along large, well developed pectoral fins.[2]

Diodontiform edit

 
Porcupine fish (here, Diodon holocanthus) swim by undulating their pectoral fins.

Diodontiform locomotion propels the fish propagating undulations along large pectoral fins, as seen in the porcupinefish (Diodontidae).[2]

Amiiform edit

"Amiiform" and "Amiiforms" redirect here. For the order of bowfin fishes, see Amiiformes.

Amiiform locomotion consists of undulations of a long dorsal fin while the body axis is held straight and stable, as seen in the bowfin.[2]

Gymnotiform edit

"Gymnotiform" and "Gymnotiforms" redirect here. For the order of teleost bony fishes commonly known as the Neotropical or South American knifefish, see Gymnotiformes.
 
Gymnotus maintains a straight back while swimming to avoid disturbing its electric sense.

Gymnotiform locomotion consists of undulations of a long anal fin, essentially upside down amiiform, seen in the South American knifefish Gymnotiformes.[2]

Balistiform edit

In balistiform locomotion, both anal and dorsal fins undulate. It is characteristic of the family Balistidae (triggerfishes). It may also be seen in the Zeidae.[2]

Oscillatory edit

Oscillation is viewed as pectoral-fin-based swimming and is best known as mobuliform locomotion. The motion can be described as the production of less than half a wave on the fin, similar to a bird wing flapping. Pelagic stingrays, such as the manta, cownose, eagle and bat rays use oscillatory locomotion.[7]

Tetraodontiform edit

In tetraodontiform locomotion, the dorsal and anal fins are flapped as a unit, either in phase or exactly opposing one another, as seen in the Tetraodontiformes (boxfishes and pufferfishes). The ocean sunfish displays an extreme example of this mode.[2]

Labriform edit

In labriform locomotion, seen in the wrasses (Labriformes), oscillatory movements of pectoral fins are either drag based or lift based. Propulsion is generated either as a reaction to drag produced by dragging the fins through the water in a rowing motion, or via lift mechanisms.[2][8]

Dynamic lift edit

 
Sharks are denser than water and must swim continually to maintain depth, using dynamic lift from their pectoral fins.

Bone and muscle tissues of fish are denser than water. To maintain depth, bony fish increase buoyancy by means of a gas bladder. Alternatively, some fish store oils or lipids for this same purpose. Fish without these features use dynamic lift instead. It is done using their pectoral fins in a manner similar to the use of wings by airplanes and birds. As these fish swim, their pectoral fins are positioned to create lift which allows the fish to maintain a certain depth. The two major drawbacks of this method are that these fish must stay moving to stay afloat and that they are incapable of swimming backwards or hovering.[9][10]

Hydrodynamics edit

Similarly to the aerodynamics of flight, powered swimming requires animals to overcome drag by producing thrust. Unlike flying, however, swimming animals often do not need to supply much vertical force because the effect of buoyancy can counter the downward pull of gravity, allowing these animals to float without much effort. While there is great diversity in fish locomotion, swimming behavior can be classified into two distinct "modes" based on the body structures involved in thrust production, Median-Paired Fin (MPF) and Body-Caudal Fin (BCF). Within each of these classifications, there are numerous specifications along a spectrum of behaviours from purely undulatory to entirely oscillatory. In undulatory swimming modes, thrust is produced by wave-like movements of the propulsive structure (usually a fin or the whole body). Oscillatory modes, on the other hand, are characterized by thrust produced by swiveling of the propulsive structure on an attachment point without any wave-like motion.[2]

Body-caudal fin edit

Sardines use body-caudal fin propulsion to swim, holding their pectoral, dorsal, and anal fins flat against the body, creating a more streamlined body to reduce drag.

Most fish swim by generating undulatory waves that propagate down the body through the caudal fin. This form of undulatory locomotion is termed body-caudal fin (BCF) swimming on the basis of the body structures used; it includes anguilliform, sub-carangiform, carangiform, and thunniform locomotory modes, as well as the oscillatory ostraciiform mode.[2][11]

Adaptation edit

Similar to adaptation in avian flight, swimming behaviors in fish can be thought of as a balance of stability and maneuverability.[12] Because body-caudal fin swimming relies on more caudal body structures that can direct powerful thrust only rearwards, this form of locomotion is particularly effective for accelerating quickly and cruising continuously.[2][11] body-caudal fin swimming is, therefore, inherently stable and is often seen in fish with large migration patterns that must maximize efficiency over long periods. Propulsive forces in median-paired fin swimming, on the other hand, are generated by multiple fins located on either side of the body that can be coordinated to execute elaborate turns. As a result, median-paired fin swimming is well adapted for high maneuverability and is often seen in smaller fish that require elaborate escape patterns.[12]

The habitats occupied by fishes are often related to their swimming capabilities. On coral reefs, the faster-swimming fish species typically live in wave-swept habitats subject to fast water flow speeds, while the slower fishes live in sheltered habitats with low levels of water movement.[13]

Fish do not rely exclusively on one locomotor mode, but are rather locomotor generalists,[2] choosing among and combining behaviors from many available behavioral techniques. Predominantly body-caudal fin swimmers often incorporate movement of their pectoral, anal, and dorsal fins as an additional stabilizing mechanism at slower speeds,[14] but hold them close to their body at high speeds to improve streamlining and reducing drag.[2] Zebrafish have even been observed to alter their locomotor behavior in response to changing hydrodynamic influences throughout growth and maturation.[15]

Flight edit

See also: flying fish and flying and gliding animals

The transition of predominantly swimming locomotion directly to flight has evolved in a single family of marine fish, the Exocoetidae. Flying fish are not true fliers in the sense that they do not execute powered flight. Instead, these species glide directly over the surface of the ocean water without ever flapping their "wings." Flying fish have evolved abnormally large pectoral fins that act as airfoils and provide lift when the fish launches itself out of the water. Additional forward thrust and steering forces are created by dipping the hypocaudal (i.e. bottom) lobe of their caudal fin into the water and vibrating it very quickly, in contrast to diving birds in which these forces are produced by the same locomotor module used for propulsion. Of the 64 extant species of flying fish, only two distinct body plans exist, each of which optimizes two different behaviors.[16][17]

 
Flying fish gain sufficient lift to glide above the water thanks to their enlarged pectoral fins.

Tradeoffs edit

While most fish have caudal fins with evenly sized lobes (i.e. homocaudal), flying fish have an enlarged ventral lobe (i.e. hypocaudal) which facilitates dipping only a portion of the tail back onto the water for additional thrust production and steering.[17]

Because flying fish are primarily aquatic animals, their body density must be close to that of water for buoyancy stability. This primary requirement for swimming, however, means that flying fish are heavier (have a larger mass) than other habitual fliers, resulting in higher wing loading and lift to drag ratios for flying fish compared to a comparably sized bird.[16] Differences in wing area, wing span, wing loading, and aspect ratio have been used to classify flying fish into two distinct classifications based on these different aerodynamic designs.[16]

Biplane body plan edit

In the biplane or Cypselurus body plan, both the pectoral and pelvic fins are enlarged to provide lift during flight.[16] These fish also tend to have "flatter" bodies which increase the total lift-producing area, thus allowing them to "hang" in the air better than more streamlined shapes.[17] As a result of this high lift production, these fish are excellent gliders and are well adapted for maximizing flight distance and duration.

Comparatively, Cypselurus flying fish have lower wing loading and smaller aspect ratios (i.e. broader wings) than their Exocoetus monoplane counterparts, which contributes to their ability to fly for longer distances than fish with this alternative body plan. Flying fish with the biplane design take advantage of their high lift production abilities when launching from the water by utilizing a "taxiing glide" in which the hypocaudal lobe remains in the water to generate thrust even after the trunk clears the water's surface and the wings are opened with a small angle of attack for lift generation.[16]

 
In the monoplane body plan of Exocoetus, only the pectoral fins are abnormally large, while the pelvic fins are small.

Monoplane body plan edit

In the Exocoetus or monoplane body plan, only the pectoral fins are enlarged to provide lift. Fish with this body plan tend to have a more streamlined body, higher aspect ratios (long, narrow wings), and higher wing loading than fish with the biplane body plan, making these fish well adapted for higher flying speeds. Flying fish with a monoplane body plan demonstrate different launching behaviors from their biplane counterparts. Instead of extending their duration of thrust production, monoplane fish launch from the water at high speeds at a large angle of attack (sometimes up to 45 degrees).[16] In this way, monoplane fish are taking advantage of their adaptation for high flight speed, while fish with biplane designs exploit their lift production abilities during takeoff.

Walking edit

Main article: Walking fish
Alticus arnoldorum hopping
Alticus arnoldorum climbing up a vertical piece of Plexiglas

A "walking fish" is a fish that is able to travel over land for extended periods of time. Some other cases of nonstandard fish locomotion include fish "walking" along the sea floor, such as the handfish or frogfish.

Most commonly, walking fish are amphibious fish. Able to spend longer times out of water, these fish may use a number of means of locomotion, including springing, snake-like lateral undulation, and tripod-like walking. The mudskippers are probably the best land-adapted of contemporary fish and are able to spend days moving about out of water and can even climb mangroves, although to only modest heights.[18] The Climbing gourami is often specifically referred to as a "walking fish", although it does not actually "walk", but rather moves in a jerky way by supporting itself on the extended edges of its gill plates and pushing itself by its fins and tail. Some reports indicate that it can also climb trees.[19]

There are a number of fish that are less adept at actual walking, such as the walking catfish. Despite being known for "walking on land", this fish usually wriggles and may use its pectoral fins to aid in its movement. Walking Catfish have a respiratory system that allows them to live out of water for several days. Some are invasive species. A notorious case in the United States is the Northern snakehead.[20] Polypterids have rudimentary lungs and can also move about on land, though rather clumsily. The Mangrove rivulus can survive for months out of water and can move to places like hollow logs.[21][22][23][24]

 
Ogcocephalus parvus

There are some species of fish that can "walk" along the sea floor but not on land; one such animal is the flying gurnard (it does not actually fly, and should not be confused with flying fish). The batfishes of the family Ogcocephalidae (not to be confused with batfish of Ephippidae) are also capable of walking along the sea floor. Bathypterois grallator, also known as a "tripodfish", stands on its three fins on the bottom of the ocean and hunts for food.[25] The African lungfish (P. annectens) can use its fins to "walk" along the bottom of its tank in a manner similar to the way amphibians and land vertebrates use their limbs on land. [26][27][28]

Burrowing edit

Many fishes, particularly eel-shaped fishes such as true eels, moray eels, and spiny eels, are capable of burrowing through sand or mud.[29] Ophichthids, the snake eels, are capable of burrowing either forwards or backwards.[30]

In larvae edit

Swimming edit

 
Salmon larva emerging from its egg

Fish larvae, like many adult fishes, swim by undulating their body. The swimming speed varies proportionally with the size of the animals, in that smaller animals tend to swim at lower speeds than larger animals. The swimming mechanism is controlled by the flow regime of the larvae. Reynolds number (Re) is defined as the ratio of inertial force to viscous force. Smaller organisms are affected more by viscous forces, like friction, and swim at a smaller Reynolds number. Larger organisms use a larger proportion of inertial forces, like pressure, to swim, at a higher Reynolds number.[31]

The larvae of ray finned fishes, the Actinopterygii, swim at a quite large range of Reynolds number (Re ≈10 to 900). This puts them in an intermediate flow regime where both inertial and viscous forces play an important role. As the size of the larvae increases, the use of pressure forces to swim at higher Reynolds number increases.

Undulatory swimmers generally shed at least two types of wake: Carangiform swimmers shed connected vortex loops and Anguilliform swimmers shed individual vortex rings. These vortex rings depend upon the shape and arrangement of the trailing edge from which the vortices are shed. These patterns depend upon the swimming speed, ratio of swimming speed to body wave speed and the shape of body wave.[31]

A spontaneous bout of swimming has three phases. The first phase is the start or acceleration phase: In this phase the larva tends to rotate its body to make a 'C' shape which is termed the preparatory stroke. It then pushes in the opposite direction to straighten its body, which is called a propulsive stroke, or a power stroke, which powers the larva to move forward. The second phase is cyclic swimming. In this phase, the larva swims with an approximately constant speed. The last phase is deceleration. In this phase, the swimming speed of the larva gradually slows down to a complete stop. In the preparatory stroke, due to the bending of the body, the larva creates 4 vortices around its body, and 2 of those are shed in the propulsive stroke.[31] Similar phenomena can be seen in the deceleration phase. However, in the vortices of the deceleration phase, a large area of elevated vorticity can be seen compared to the starting phase.

The swimming abilities of larval fishes are important for survival. This is particularly true for the larval fishes with higher metabolic rate and smaller size which makes them more susceptible to predators. The swimming ability of a reef fish larva helps it to settle at a suitable reef and for locating its home as it is often isolated from its home reef in search of food. Hence the swimming speed of reef fish larvae are quite high (≈12 cm/s - 100 cm/s) compared to other larvae.[32][33] The swimming speeds of larvae from the same families at the two locations are relatively similar.[32] However, the variation among individuals is quite large. At the species level, length is significantly related to swimming ability. However, at the family level, only 16% of variation in swimming ability can be explained by length.[32] There is also a negative correlation between the fineness ratio (length of body to maximum width) and the swimming ability of reef fish larvae. This suggests a minimization of overall drag and maximization of volume. Reef fish larvae differ significantly in their critical swimming speed abilities among taxa which leads to high variability in sustainable swimming speed.[34] This again leads to sustainable variability in their ability to alter dispersal patterns, overall dispersal distances and control their temporal and spatial patterns of settlement.[35]

Hydrodynamics edit

Small undulatory swimmers such as fish larvae experience both inertial and viscous forces, the relative importance of which is indicated by Reynolds number (Re). Reynolds number is proportional to body size and swimming speed. The swimming performance of a larva increases between 2–5 days post fertilization. Compared with adults, larval fish experience relatively high viscous force. To enhance thrust to an equal level with the adults, it increases its tail beat frequency and thus amplitude. In zebrafish, tail beat frequency increases over larval age to 95 Hz in 3 days post fertilization from 80 Hz in 2 days post fertilization. This higher frequency leads to higher swimming speed, thus reducing predation and increasing prey catching ability when they start feeding at around 5 days post fertilization. The vortex shedding mechanics changes with the flow regime in an inverse non-linear way. Strouhal number is a design parameter for the vortex shedding mechanism. It can be defined as a ratio of the product of tail beat frequency with amplitude with the mean swimming speed.[36] Reynolds number (Re) is the main deciding criteria of a flow regime. It has been observed over different type of larval experiments that, slow larvae swims at higher Strouhal number but lower Reynolds number. However, the faster larvae swims distinctively at opposite conditions, that is, at lower Strouhal number but higher Reynolds number. Strouhal number is constant over similar speed ranged adult fishes. Strouhal number does not only depend on the small size of the swimmers, but also dependent to the flow regime. As in fishes which swim in viscous or high-friction flow regime, would create high body drag which will lead to higher Strouhal number. Whereas, in high viscous regime, the adults swim at lower stride length which leads to lower tail beat frequency and lower amplitude. This leads to higher thrust for same displacement or higher propulsive force, which unanimously reduces the Reynolds number.[37]

Larval fishes start feeding at 5–7 days post fertilization. And they experience extreme mortality rate (≈99%) in the few days after feeding starts. The reason for this 'Critical Period' (Hjort-1914) is mainly hydrodynamic constraints. Larval fish fail to eat even if there are enough prey encounters. One of the primary determinants of feeding success is the size of larval body. The smaller larvae function in a lower Reynolds number (Re) regime. As the age increases, the size of the larvae increases, which leads to higher swimming speed and increased Reynolds number. It has been observed through many experiments that the Reynolds number of successful strikes (Re~200) is much higher than the Reynolds number of failed strikes (Re~20).[38][39] Numerical analysis of suction feeding at a low Reynolds number concluded that around 40% energy invested in mouth opening is lost to frictional forces rather than contributing to accelerating the fluid towards mouth.[40] Ontogenetic improvement in the sensory system, coordination and experiences are non-significant relationship while determining feeding success of larvae [39] A successful strike positively depends upon the peak flow speed or the speed of larvae at the time of strike. The peak flow speed is also dependent on the gape speed or the speed of opening the buccal cavity to capture food. As the larva ages, its body size increase and its gape speed also increase, which cumulatively increase the successful strike outcomes.[39]

The ability of a larval prey to survive an encounter with predator totally depends on its ability to sense and evade the strike. Adult fishes exhibit rapid suction feeding strikes as compared to larval fishes. Sensitivity of larval fish to velocity and flow fields provides the larvae a critical defense against predation. Though many prey use their visual system to detect and evade predators when there is light, it is hard for the prey to detect predators at night, which leads to a delayed response to the attack. There is a mechano-sensory system in fishes to identify the different flow generated by different motion surrounding the water and between the bodies called as lateral line system.[41] After detecting a predator, a larva evades its strike by 'fast start' or 'C' response. A swimming fish disturbs a volume of water ahead of its body with a flow velocity that increases with the proximity to the body. This particular phenomenon is sometimes called a bow wave.[42] The timing of the 'C' start response affects escape probability inversely. Escape probability increases with the distance from the predator at the time of strike. In general, prey successfully evade a predator strike from an intermediate distance (3–6 mm) from the predator.[41]

Behavior edit

Objective quantification is complicated in higher vertebrates by the complex and diverse locomotor repertoire and neural system. However, the relative simplicity of a juvenile brain and simple nervous system of fishes with fundamental neuronal pathways allows zebrafish larvae to be an apt model to study the interconnection between locomotor repertoire and neuronal system of a vertebrate. Behavior represents the unique interface between intrinsic and extrinsic forces that determine an organism's health and survival.[43] Larval zebrafish perform many locomotor behavior such as escape response, prey tracking, optomotor response etc. These behaviors can be categorized with respect to body position as ‘C’-starts, ‘J’-turns, slow scoots, routine turns etc. Fish larvae respond to abrupt changes in illumination with distinct locomotor behavior. The larvae show high locomotor activity during periods of bright light compared to dark. This behavior can direct towards the idea of searching food in light whereas the larvae do not feed in dark.[44] Also light exposure directly manipulates the locomotor activities of larvae throughout circadian period of light and dark with higher locomotor activity in light condition than in dark condition which is very similar as seen in mammals. Following the onset of darkness, larvae shows hyperactive scoot motion prior to a gradual drop off. This behavior could possibly be linked to find a shelter before nightfall. Also larvae can treat this sudden nightfall as under debris and the hyperactivity can be explained as the larvae navigation back to illuminated areas.[44] Prolonged dark period can reduce the light-dark responsiveness of larvae. Following light extinction, larvae execute large angle turns towards the vanished light source, which explains the navigational response of a larva.[44] Acute ethanol exposure reduce visual sensitivity of larvae causing a latency to respond in light and dark period change.[43]

See also edit

  • Aquatic locomotion – biologically propelled motion through a liquid medium; in contrast of passive swimming (floating); involves the expenditure of energy to travel to a desired location
  • Microswimmer
  • Role of skin in locomotion – Use of the integumentary system in animal movement
  • Tradeoffs for locomotion in air and water – Comparison of swimming and flying, evolution and biophysics
  • Undulatory locomotion – motion characterized by wave-like movement patterns that act to propel an animal forward. eg: crawling in snakes, or swimming in the lamprey. Typically utilized by limbless animals

References edit

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  30. ^ Allen, Gerry (1999). Marine Fishes of Southeast Asia: A Field Guide for Anglers and Divers. Tuttle Publishing. p. 56. ISBN 978-1-4629-1707-5. many have a bony, sharp tail and are equally adept at burrowing forward or backward.
  31. ^ a b c ‘Flow Patterns Of Larval Fish: Undulatory Swimming in the Intermediate Flow Regime’ by Ulrike K. Müller, Jos G. M. van den Boogaart and Johan L. van Leeuwen. Journal of Experimental Biology 2008 211: 196–205; doi: 10.1242/jeb.005629
  32. ^ a b c "Critical Swimming Speeds of Late-Stage Coral Reef Fish Larvae: Variation within Species, Among Species and Between Locations" by Fisher, R., Leis, J.M., Clark, D.L.in Marine Biology (2005) 147: 1201. https://doi.org/10.1007/s00227-005-0001-x,
  33. ^ "Development of Swimming Abilities in Reef Fish Larvae" by Rebecca Fisher, David R. Bellwood, Suresh D. Job in Marine Ecology-progress Series - MAR ECOL-PROGR SER. 202. 163-173. 10.3354/meps202163
  34. ^ ‘Maximum Sustainable Swimming Speeds Of Late-Stage Larvae Of Nine Species Of Reef Fishes’ by Rebecca Fisher, Shaun K.Wilson in Journal of Experimental Marine Biology and Ecology, Volume 312, Issue 1, 2004, Pages 171–186, ISSN 0022-0981, https://doi.org/10.1016/j.jembe.2004.06.009
  35. ^ 'Development of Swimming Abilities in Reef Fish Larvae' by Rebecca Fisher, David R. Bellwood, Suresh D. Job in Marine Ecology-progress Series - MAR ECOL-PROGR SER. 202. 163-173. 10.3354/meps202163
  36. ^ van Leeuwen, Johan L.; Voesenek, Cees J.; Müller, Ulrike K. (2015). "How body torque and Strouhal number change with swimming speed and developmental stage in larval zebrafish". Journal of the Royal Society Interface. 12 (110). The Royal Society: 20150479. doi:10.1098/rsif.2015.0479. ISSN 1742-5689. PMC 4614456. PMID 26269230.
  37. ^ 'How body torque and Strouhal number change with swimming speed and developmental stage in larval zebrafish' by Johan L. van Leeuwen, Cees J. Voesenek and Ulrike K. Müller in J. R. Soc. Interface 2015 12 20150479; DOI: 10.1098/rsif.2015.0479. 6 September 2015
  38. ^ China, Victor; Holzman, Roi (19 May 2014). "Hydrodynamic starvation in first-feeding larval fishes". Proceedings of the National Academy of Sciences. 111 (22): 8083–8088. Bibcode:2014PNAS..111.8083C. doi:10.1073/pnas.1323205111. ISSN 0027-8424. PMC 4050599. PMID 24843180.
  39. ^ a b c China, Victor; Levy, Liraz; Liberzon, Alex; Elmaliach, Tal; Holzman, Roi (26 April 2017). "Hydrodynamic regime determines the feeding success of larval fish through the modulation of strike kinematics". Proceedings of the Royal Society B: Biological Sciences. 284 (1853). The Royal Society: 20170235. doi:10.1098/rspb.2017.0235. ISSN 0962-8452. PMC 5413926. PMID 28446697.
  40. ^ Drost, M. R.; Muller, M.; Osse, J. W. M. (23 August 1988). "A quantitative hydrodynamical model of suction feeding in larval fishes: the role of frictional forces". Proceedings of the Royal Society of London. Series B. Biological Sciences. 234 (1276). The Royal Society: 263–281. Bibcode:1988RSPSB.234..263D. doi:10.1098/rspb.1988.0048. ISSN 0080-4649. S2CID 86188901.
  41. ^ a b Stewart, William J.; Cardenas, Gilberto S.; McHenry, Matthew J. (1 February 2013). "Zebrafish larvae evade predators by sensing water flow". Journal of Experimental Biology. 216 (3). The Company of Biologists: 388–398. doi:10.1242/jeb.072751. ISSN 1477-9145. PMID 23325859.
  42. ^ Ferry-Graham, Lara A.; Wainwright, Peter C.; Lauder, George V. (2003). "Quantification of flow during suction feeding in bluegill sunfish". Zoology. 106 (2). Elsevier: 159–168. doi:10.1078/0944-2006-00110. ISSN 0944-2006. PMID 16351901.
  43. ^ a b ‘Locomotion In Larval Zebrafish: Influence of Time of Day, Lighting and Ethanol’ by R.C. MacPhail, J. Brooks, D.L. Hunter, B. Padnos a, T.D. Irons, S. Padilla in Neurotoxicology. 30. 52-8. 10.1016/j.neuro.2008.09.011.
  44. ^ a b c ‘Modulation of Locomotor Activity in Larval Zebrafish During Light Adaptation’ by Harold A. Burgess and Michael Granato. In Journal of Experimental Biology 2007 210: 2526–2539; doi: 10.1242/jeb.003939

Further reading edit

  • Alexander, R. McNeill (2003) Principles of Animal Locomotion. Princeton University Press. ISBN 0-691-08678-8.
  • Eloy, Christophe (2013). "On the best design for undulatory swimming". Journal of Fluid Mechanics. 717: 48–89. Bibcode:2013JFM...717...48E. doi:10.1017/jfm.2012.561. S2CID 56438579.
  • Lauder, GV; Nauen, JC; Drucker, EG (2002). "Experimental Hydrodynamics and Evolution: Function of Median Fins in Ray-finned Fishes". Integr. Comp. Biol. 42 (5): 1009–1017. doi:10.1093/icb/42.5.1009. PMID 21680382.
  • Videler JJ (1993) Fish Swimming Springer. ISBN 9780412408601.
  • Vogel, Steven (1994) Life in Moving Fluid: The Physical Biology of Flow. Princeton University Press. ISBN 0-691-02616-5 (particularly pp. 115–117 and pp. 207–216 for specific biological examples swimming and flying respectively)
  • Wu, Theodore, Y.-T., Brokaw, Charles J., Brennen, Christopher, Eds. (1975) Swimming and Flying in Nature. Volume 2, Plenum Press. ISBN 0-306-37089-1 (particularly pp. 615–652 for an in depth look at fish swimming)

External links edit

  • How fish swim: study solves muscle mystery

January 01, 1970
fish, locomotion, various, types, animal, locomotion, used, fish, principally, swimming, this, achieved, different, groups, fish, variety, mechanisms, propulsion, most, often, wave, like, lateral, flexions, fish, body, tail, water, various, specialised, fish, . Fish locomotion is the various types of animal locomotion used by fish principally by swimming This is achieved in different groups of fish by a variety of mechanisms of propulsion most often by wave like lateral flexions of the fish s body and tail in the water and in various specialised fish by motions of the fins The major forms of locomotion in fish are Anguilliform in which a wave passes evenly along a long slender body Sub carangiform in which the wave increases quickly in amplitude towards the tail Carangiform in which the wave is concentrated near the tail which oscillates rapidly Thunniform rapid swimming with a large powerful crescent shaped tail and Ostraciiform with almost no oscillation except of the tail fin Fish like these yellowfin tuna use many different mechanisms to propel themselves through water More specialized fish include movement by pectoral fins with a mainly stiff body opposed sculling with dorsal and anal fins as in the sunfish and movement by propagating a wave along the long fins with a motionless body as in the knifefish or featherbacks In addition some fish can variously walk i e crawl over land using the pectoral and pelvic fins burrow in mud leap out of the water and even glide temporarily through the air Contents 1 Swimming 1 1 Mechanism 1 2 Body caudal fin propulsion 1 2 1 Anguilliform 1 2 2 Subcarangiform 1 2 3 Carangiform 1 2 4 Thunniform 1 2 5 Ostraciiform 1 3 Median paired fin propulsion 1 3 1 Rajiform 1 3 2 Diodontiform 1 3 3 Amiiform 1 3 4 Gymnotiform 1 3 5 Balistiform 1 3 6 Oscillatory 1 3 6 1 Tetraodontiform 1 3 6 2 Labriform 1 4 Dynamic lift 1 5 Hydrodynamics 1 5 1 Body caudal fin 1 6 Adaptation 2 Flight 2 1 Tradeoffs 2 2 Biplane body plan 2 3 Monoplane body plan 3 Walking 4 Burrowing 5 In larvae 5 1 Swimming 5 2 Hydrodynamics 5 3 Behavior 6 See also 7 References 8 Further reading 9 External linksSwimming editMechanism edit Further information Fish fin nbsp Fins used for locomotion 1 pectoral fins paired 2 pelvic fins paired 3 dorsal fin 4 adipose fin 5 anal fin 6 caudal tail fin Fish swim by exerting force against the surrounding water There are exceptions but this is normally achieved by the fish contracting muscles on either side of its body in order to generate waves of flexion that travel the length of the body from nose to tail generally getting larger as they go along The vector forces exerted on the water by such motion cancel out laterally but generate a net force backwards which in turn pushes the fish forward through the water Most fishes generate thrust using lateral movements of their body and caudal fin but many other species move mainly using their median and paired fins The latter group swim slowly but can turn rapidly as is needed when living in coral reefs for example But they can not swim as fast as fish using their bodies and caudal fins 1 2 nbsp Skeletal anatomy of Tilapia 3 Consider the tilapia shown in the diagram Like most fish the tilapia has a streamlined body shape reducing water resistance to movement and enabling the tilapia to cut easily through water Its head is inflexible which helps it maintain forward thrust 3 Its scales overlap and point backwards allowing water to pass over the fish without unnecessary obstruction Water friction is further reduced by mucus which tilapia secrete over their body 3 nbsp Like a plane or submarine a fish has six degrees of freedom The backbone is flexible allowing muscles to contract and relax rhythmically and bring about undulating movement 3 A swim bladder provides buoyancy which helps the fish adjust its vertical position in the water column A lateral line system allows it to detect vibrations and pressure changes in water helping the fish to respond appropriately to external events 3 Well developed fins are used for maintaining balance braking and changing direction The pectoral fins act as pivots around which the fish can turn rapidly and steer itself The paired pectoral and pelvic fins control pitching while the unpaired dorsal and anal fins reduce yawing and rolling The caudal fin provides raw power for propelling the fish forward 3 Body caudal fin propulsion edit There are five groups that differ in the fraction of their body that is displaced laterally 1 Anguilliform edit Anguilliform and Anguilliforms redirect here For Anguilliformes the order of ray finned fishes see Eel nbsp Eels propagate a more or less constant sized flexion wave along their slender bodies In the anguilliform group containing some long slender fish such as eels there is little increase in the amplitude of the flexion wave as it passes along the body 1 4 Subcarangiform edit The subcarangiform group has a more marked increase in wave amplitude along the body with the vast majority of the work being done by the rear half of the fish In general the fish body is stiffer making for higher speed but reduced maneuverability Trout use sub carangiform locomotion 1 Carangiform edit Carangiform and Carangiforms redirect here For the order of ray finned fishes see Carangiformes The carangiform group named for the Carangidae are stiffer and faster moving than the previous groups The vast majority of movement is concentrated in the very rear of the body and tail Carangiform swimmers generally have rapidly oscillating tails 1 Thunniform edit nbsp Tunas such as the bluefin swim fast with their large crescent shaped tails The thunniform group contains high speed long distance swimmers and is characteristic of tunas 5 and is also found in several lamnid sharks 6 Here virtually all the sideways movement is in the tail and the region connecting the main body to the tail the peduncle The tail itself tends to be large and crescent shaped 1 Ostraciiform edit The ostraciiform group have no appreciable body wave when they employ caudal locomotion Only the tail fin itself oscillates often very rapidly to create thrust This group includes Ostraciidae 1 Median paired fin propulsion edit nbsp Boxfish use median paired fin swimming as they are not well streamlined and use primarily their pectoral fins to produce thrust See also Batoid locomotion Not all fish fit comfortably in the above groups Ocean sunfish for example have a completely different system the tetraodontiform mode and many small fish use their pectoral fins for swimming as well as for steering and dynamic lift Fish in the order Gymnotiformes possess electric organs along the length of their bodies and swim by undulating an elongated anal fin while keeping the body still presumably so as not to disturb the electric field that they generate Many fish swim using combined behavior of their two pectoral fins or both their anal and dorsal fins Different types of Median paired fin propulsion can be achieved by preferentially using one fin pair over the other and include rajiform diodontiform amiiform gymnotiform and balistiform modes 2 Rajiform edit Rajiform locomotion is characteristic of rays and skates when thrust is produced by vertical undulations along large well developed pectoral fins 2 Diodontiform edit nbsp Porcupine fish here Diodon holocanthus swim by undulating their pectoral fins Diodontiform locomotion propels the fish propagating undulations along large pectoral fins as seen in the porcupinefish Diodontidae 2 Amiiform edit Amiiform and Amiiforms redirect here For the order of bowfin fishes see Amiiformes Amiiform locomotion consists of undulations of a long dorsal fin while the body axis is held straight and stable as seen in the bowfin 2 Gymnotiform edit Gymnotiform and Gymnotiforms redirect here For the order of teleost bony fishes commonly known as the Neotropical or South American knifefish see Gymnotiformes nbsp Gymnotus maintains a straight back while swimming to avoid disturbing its electric sense Gymnotiform locomotion consists of undulations of a long anal fin essentially upside down amiiform seen in the South American knifefish Gymnotiformes 2 Balistiform edit In balistiform locomotion both anal and dorsal fins undulate It is characteristic of the family Balistidae triggerfishes It may also be seen in the Zeidae 2 Oscillatory edit Oscillation is viewed as pectoral fin based swimming and is best known as mobuliform locomotion The motion can be described as the production of less than half a wave on the fin similar to a bird wing flapping Pelagic stingrays such as the manta cownose eagle and bat rays use oscillatory locomotion 7 Tetraodontiform edit In tetraodontiform locomotion the dorsal and anal fins are flapped as a unit either in phase or exactly opposing one another as seen in the Tetraodontiformes boxfishes and pufferfishes The ocean sunfish displays an extreme example of this mode 2 Labriform edit In labriform locomotion seen in the wrasses Labriformes oscillatory movements of pectoral fins are either drag based or lift based Propulsion is generated either as a reaction to drag produced by dragging the fins through the water in a rowing motion or via lift mechanisms 2 8 Dynamic lift edit nbsp Sharks are denser than water and must swim continually to maintain depth using dynamic lift from their pectoral fins Bone and muscle tissues of fish are denser than water To maintain depth bony fish increase buoyancy by means of a gas bladder Alternatively some fish store oils or lipids for this same purpose Fish without these features use dynamic lift instead It is done using their pectoral fins in a manner similar to the use of wings by airplanes and birds As these fish swim their pectoral fins are positioned to create lift which allows the fish to maintain a certain depth The two major drawbacks of this method are that these fish must stay moving to stay afloat and that they are incapable of swimming backwards or hovering 9 10 Hydrodynamics edit Similarly to the aerodynamics of flight powered swimming requires animals to overcome drag by producing thrust Unlike flying however swimming animals often do not need to supply much vertical force because the effect of buoyancy can counter the downward pull of gravity allowing these animals to float without much effort While there is great diversity in fish locomotion swimming behavior can be classified into two distinct modes based on the body structures involved in thrust production Median Paired Fin MPF and Body Caudal Fin BCF Within each of these classifications there are numerous specifications along a spectrum of behaviours from purely undulatory to entirely oscillatory In undulatory swimming modes thrust is produced by wave like movements of the propulsive structure usually a fin or the whole body Oscillatory modes on the other hand are characterized by thrust produced by swiveling of the propulsive structure on an attachment point without any wave like motion 2 Body caudal fin edit source source source source source source Sardines use body caudal fin propulsion to swim holding their pectoral dorsal and anal fins flat against the body creating a more streamlined body to reduce drag Most fish swim by generating undulatory waves that propagate down the body through the caudal fin This form of undulatory locomotion is termed body caudal fin BCF swimming on the basis of the body structures used it includes anguilliform sub carangiform carangiform and thunniform locomotory modes as well as the oscillatory ostraciiform mode 2 11 Adaptation edit Similar to adaptation in avian flight swimming behaviors in fish can be thought of as a balance of stability and maneuverability 12 Because body caudal fin swimming relies on more caudal body structures that can direct powerful thrust only rearwards this form of locomotion is particularly effective for accelerating quickly and cruising continuously 2 11 body caudal fin swimming is therefore inherently stable and is often seen in fish with large migration patterns that must maximize efficiency over long periods Propulsive forces in median paired fin swimming on the other hand are generated by multiple fins located on either side of the body that can be coordinated to execute elaborate turns As a result median paired fin swimming is well adapted for high maneuverability and is often seen in smaller fish that require elaborate escape patterns 12 The habitats occupied by fishes are often related to their swimming capabilities On coral reefs the faster swimming fish species typically live in wave swept habitats subject to fast water flow speeds while the slower fishes live in sheltered habitats with low levels of water movement 13 Fish do not rely exclusively on one locomotor mode but are rather locomotor generalists 2 choosing among and combining behaviors from many available behavioral techniques Predominantly body caudal fin swimmers often incorporate movement of their pectoral anal and dorsal fins as an additional stabilizing mechanism at slower speeds 14 but hold them close to their body at high speeds to improve streamlining and reducing drag 2 Zebrafish have even been observed to alter their locomotor behavior in response to changing hydrodynamic influences throughout growth and maturation 15 Flight editSee also flying fish and flying and gliding animals The transition of predominantly swimming locomotion directly to flight has evolved in a single family of marine fish the Exocoetidae Flying fish are not true fliers in the sense that they do not execute powered flight Instead these species glide directly over the surface of the ocean water without ever flapping their wings Flying fish have evolved abnormally large pectoral fins that act as airfoils and provide lift when the fish launches itself out of the water Additional forward thrust and steering forces are created by dipping the hypocaudal i e bottom lobe of their caudal fin into the water and vibrating it very quickly in contrast to diving birds in which these forces are produced by the same locomotor module used for propulsion Of the 64 extant species of flying fish only two distinct body plans exist each of which optimizes two different behaviors 16 17 nbsp Flying fish gain sufficient lift to glide above the water thanks to their enlarged pectoral fins Tradeoffs edit While most fish have caudal fins with evenly sized lobes i e homocaudal flying fish have an enlarged ventral lobe i e hypocaudal which facilitates dipping only a portion of the tail back onto the water for additional thrust production and steering 17 Because flying fish are primarily aquatic animals their body density must be close to that of water for buoyancy stability This primary requirement for swimming however means that flying fish are heavier have a larger mass than other habitual fliers resulting in higher wing loading and lift to drag ratios for flying fish compared to a comparably sized bird 16 Differences in wing area wing span wing loading and aspect ratio have been used to classify flying fish into two distinct classifications based on these different aerodynamic designs 16 Biplane body plan edit In the biplane or Cypselurus body plan both the pectoral and pelvic fins are enlarged to provide lift during flight 16 These fish also tend to have flatter bodies which increase the total lift producing area thus allowing them to hang in the air better than more streamlined shapes 17 As a result of this high lift production these fish are excellent gliders and are well adapted for maximizing flight distance and duration Comparatively Cypselurus flying fish have lower wing loading and smaller aspect ratios i e broader wings than their Exocoetus monoplane counterparts which contributes to their ability to fly for longer distances than fish with this alternative body plan Flying fish with the biplane design take advantage of their high lift production abilities when launching from the water by utilizing a taxiing glide in which the hypocaudal lobe remains in the water to generate thrust even after the trunk clears the water s surface and the wings are opened with a small angle of attack for lift generation 16 nbsp In the monoplane body plan of Exocoetus only the pectoral fins are abnormally large while the pelvic fins are small Monoplane body plan edit In the Exocoetus or monoplane body plan only the pectoral fins are enlarged to provide lift Fish with this body plan tend to have a more streamlined body higher aspect ratios long narrow wings and higher wing loading than fish with the biplane body plan making these fish well adapted for higher flying speeds Flying fish with a monoplane body plan demonstrate different launching behaviors from their biplane counterparts Instead of extending their duration of thrust production monoplane fish launch from the water at high speeds at a large angle of attack sometimes up to 45 degrees 16 In this way monoplane fish are taking advantage of their adaptation for high flight speed while fish with biplane designs exploit their lift production abilities during takeoff Walking editMain article Walking fish source source source source source Alticus arnoldorum hopping source source source source source Alticus arnoldorum climbing up a vertical piece of Plexiglas A walking fish is a fish that is able to travel over land for extended periods of time Some other cases of nonstandard fish locomotion include fish walking along the sea floor such as the handfish or frogfish Most commonly walking fish are amphibious fish Able to spend longer times out of water these fish may use a number of means of locomotion including springing snake like lateral undulation and tripod like walking The mudskippers are probably the best land adapted of contemporary fish and are able to spend days moving about out of water and can even climb mangroves although to only modest heights 18 The Climbing gourami is often specifically referred to as a walking fish although it does not actually walk but rather moves in a jerky way by supporting itself on the extended edges of its gill plates and pushing itself by its fins and tail Some reports indicate that it can also climb trees 19 There are a number of fish that are less adept at actual walking such as the walking catfish Despite being known for walking on land this fish usually wriggles and may use its pectoral fins to aid in its movement Walking Catfish have a respiratory system that allows them to live out of water for several days Some are invasive species A notorious case in the United States is the Northern snakehead 20 Polypterids have rudimentary lungs and can also move about on land though rather clumsily The Mangrove rivulus can survive for months out of water and can move to places like hollow logs 21 22 23 24 nbsp Ogcocephalus parvus There are some species of fish that can walk along the sea floor but not on land one such animal is the flying gurnard it does not actually fly and should not be confused with flying fish The batfishes of the family Ogcocephalidae not to be confused with batfish of Ephippidae are also capable of walking along the sea floor Bathypterois grallator also known as a tripodfish stands on its three fins on the bottom of the ocean and hunts for food 25 The African lungfish P annectens can use its fins to walk along the bottom of its tank in a manner similar to the way amphibians and land vertebrates use their limbs on land 26 27 28 Burrowing editMany fishes particularly eel shaped fishes such as true eels moray eels and spiny eels are capable of burrowing through sand or mud 29 Ophichthids the snake eels are capable of burrowing either forwards or backwards 30 In larvae editSwimming edit nbsp Salmon larva emerging from its egg Fish larvae like many adult fishes swim by undulating their body The swimming speed varies proportionally with the size of the animals in that smaller animals tend to swim at lower speeds than larger animals The swimming mechanism is controlled by the flow regime of the larvae Reynolds number Re is defined as the ratio of inertial force to viscous force Smaller organisms are affected more by viscous forces like friction and swim at a smaller Reynolds number Larger organisms use a larger proportion of inertial forces like pressure to swim at a higher Reynolds number 31 The larvae of ray finned fishes the Actinopterygii swim at a quite large range of Reynolds number Re 10 to 900 This puts them in an intermediate flow regime where both inertial and viscous forces play an important role As the size of the larvae increases the use of pressure forces to swim at higher Reynolds number increases Undulatory swimmers generally shed at least two types of wake Carangiform swimmers shed connected vortex loops and Anguilliform swimmers shed individual vortex rings These vortex rings depend upon the shape and arrangement of the trailing edge from which the vortices are shed These patterns depend upon the swimming speed ratio of swimming speed to body wave speed and the shape of body wave 31 A spontaneous bout of swimming has three phases The first phase is the start or acceleration phase In this phase the larva tends to rotate its body to make a C shape which is termed the preparatory stroke It then pushes in the opposite direction to straighten its body which is called a propulsive stroke or a power stroke which powers the larva to move forward The second phase is cyclic swimming In this phase the larva swims with an approximately constant speed The last phase is deceleration In this phase the swimming speed of the larva gradually slows down to a complete stop In the preparatory stroke due to the bending of the body the larva creates 4 vortices around its body and 2 of those are shed in the propulsive stroke 31 Similar phenomena can be seen in the deceleration phase However in the vortices of the deceleration phase a large area of elevated vorticity can be seen compared to the starting phase The swimming abilities of larval fishes are important for survival This is particularly true for the larval fishes with higher metabolic rate and smaller size which makes them more susceptible to predators The swimming ability of a reef fish larva helps it to settle at a suitable reef and for locating its home as it is often isolated from its home reef in search of food Hence the swimming speed of reef fish larvae are quite high 12 cm s 100 cm s compared to other larvae 32 33 The swimming speeds of larvae from the same families at the two locations are relatively similar 32 However the variation among individuals is quite large At the species level length is significantly related to swimming ability However at the family level only 16 of variation in swimming ability can be explained by length 32 There is also a negative correlation between the fineness ratio length of body to maximum width and the swimming ability of reef fish larvae This suggests a minimization of overall drag and maximization of volume Reef fish larvae differ significantly in their critical swimming speed abilities among taxa which leads to high variability in sustainable swimming speed 34 This again leads to sustainable variability in their ability to alter dispersal patterns overall dispersal distances and control their temporal and spatial patterns of settlement 35 Hydrodynamics edit Small undulatory swimmers such as fish larvae experience both inertial and viscous forces the relative importance of which is indicated by Reynolds number Re Reynolds number is proportional to body size and swimming speed The swimming performance of a larva increases between 2 5 days post fertilization Compared with adults larval fish experience relatively high viscous force To enhance thrust to an equal level with the adults it increases its tail beat frequency and thus amplitude In zebrafish tail beat frequency increases over larval age to 95 Hz in 3 days post fertilization from 80 Hz in 2 days post fertilization This higher frequency leads to higher swimming speed thus reducing predation and increasing prey catching ability when they start feeding at around 5 days post fertilization The vortex shedding mechanics changes with the flow regime in an inverse non linear way Strouhal number is a design parameter for the vortex shedding mechanism It can be defined as a ratio of the product of tail beat frequency with amplitude with the mean swimming speed 36 Reynolds number Re is the main deciding criteria of a flow regime It has been observed over different type of larval experiments that slow larvae swims at higher Strouhal number but lower Reynolds number However the faster larvae swims distinctively at opposite conditions that is at lower Strouhal number but higher Reynolds number Strouhal number is constant over similar speed ranged adult fishes Strouhal number does not only depend on the small size of the swimmers but also dependent to the flow regime As in fishes which swim in viscous or high friction flow regime would create high body drag which will lead to higher Strouhal number Whereas in high viscous regime the adults swim at lower stride length which leads to lower tail beat frequency and lower amplitude This leads to higher thrust for same displacement or higher propulsive force which unanimously reduces the Reynolds number 37 Larval fishes start feeding at 5 7 days post fertilization And they experience extreme mortality rate 99 in the few days after feeding starts The reason for this Critical Period Hjort 1914 is mainly hydrodynamic constraints Larval fish fail to eat even if there are enough prey encounters One of the primary determinants of feeding success is the size of larval body The smaller larvae function in a lower Reynolds number Re regime As the age increases the size of the larvae increases which leads to higher swimming speed and increased Reynolds number It has been observed through many experiments that the Reynolds number of successful strikes Re 200 is much higher than the Reynolds number of failed strikes Re 20 38 39 Numerical analysis of suction feeding at a low Reynolds number concluded that around 40 energy invested in mouth opening is lost to frictional forces rather than contributing to accelerating the fluid towards mouth 40 Ontogenetic improvement in the sensory system coordination and experiences are non significant relationship while determining feeding success of larvae 39 A successful strike positively depends upon the peak flow speed or the speed of larvae at the time of strike The peak flow speed is also dependent on the gape speed or the speed of opening the buccal cavity to capture food As the larva ages its body size increase and its gape speed also increase which cumulatively increase the successful strike outcomes 39 The ability of a larval prey to survive an encounter with predator totally depends on its ability to sense and evade the strike Adult fishes exhibit rapid suction feeding strikes as compared to larval fishes Sensitivity of larval fish to velocity and flow fields provides the larvae a critical defense against predation Though many prey use their visual system to detect and evade predators when there is light it is hard for the prey to detect predators at night which leads to a delayed response to the attack There is a mechano sensory system in fishes to identify the different flow generated by different motion surrounding the water and between the bodies called as lateral line system 41 After detecting a predator a larva evades its strike by fast start or C response A swimming fish disturbs a volume of water ahead of its body with a flow velocity that increases with the proximity to the body This particular phenomenon is sometimes called a bow wave 42 The timing of the C start response affects escape probability inversely Escape probability increases with the distance from the predator at the time of strike In general prey successfully evade a predator strike from an intermediate distance 3 6 mm from the predator 41 Larvae of different fishes nbsp Atlantic herring eggs with a newly hatched larva nbsp Freshly hatched herring larva in a drop of water compared to a match head nbsp Late stage lanternfish larva nbsp A 9mm long late stage scaldfish larva nbsp Larva of a conger eel 7 6 cm nbsp Bluefin tuna larva nbsp Pacific cod larva nbsp Walleye larva nbsp Common sturgeon larva nbsp Boxfish larva nbsp Ocean sunfish larva 2 7mm Behavior edit Objective quantification is complicated in higher vertebrates by the complex and diverse locomotor repertoire and neural system However the relative simplicity of a juvenile brain and simple nervous system of fishes with fundamental neuronal pathways allows zebrafish larvae to be an apt model to study the interconnection between locomotor repertoire and neuronal system of a vertebrate Behavior represents the unique interface between intrinsic and extrinsic forces that determine an organism s health and survival 43 Larval zebrafish perform many locomotor behavior such as escape response prey tracking optomotor response etc These behaviors can be categorized with respect to body position as C starts J turns slow scoots routine turns etc Fish larvae respond to abrupt changes in illumination with distinct locomotor behavior The larvae show high locomotor activity during periods of bright light compared to dark This behavior can direct towards the idea of searching food in light whereas the larvae do not feed in dark 44 Also light exposure directly manipulates the locomotor activities of larvae throughout circadian period of light and dark with higher locomotor activity in light condition than in dark condition which is very similar as seen in mammals Following the onset of darkness larvae shows hyperactive scoot motion prior to a gradual drop off This behavior could possibly be linked to find a shelter before nightfall Also larvae can treat this sudden nightfall as under debris and the hyperactivity can be explained as the larvae navigation back to illuminated areas 44 Prolonged dark period can reduce the light dark responsiveness of larvae Following light extinction larvae execute large angle turns towards the vanished light source which explains the navigational response of a larva 44 Acute ethanol exposure reduce visual sensitivity of larvae causing a latency to respond in light and dark period change 43 See also editAquatic locomotion biologically propelled motion through a liquid medium in contrast of passive swimming floating involves the expenditure of energy to travel to a desired locationPages displaying wikidata descriptions as a fallback Microswimmer Role of skin in locomotion Use of the integumentary system in animal movement Tradeoffs for locomotion in air and water Comparison of swimming and flying evolution and biophysics Undulatory locomotion motion characterized by wave like movement patterns that act to propel an animal forward eg crawling in snakes or swimming in the lamprey Typically utilized by limbless animalsPages displaying wikidata descriptions as a fallbackReferences edit a b c d e f g Breder CM 1926 The locomotion of fishes Zoologica 4 159 297 a b c d e f g h i j k l m n Sfakiotakis M Lane D M Davies J B C 1999 Review of Fish Swimming Modes for Aquatic Locomotion PDF IEEE Journal of Oceanic Engineering 24 2 237 252 Bibcode 1999IJOE 24 237S doi 10 1109 48 757275 S2CID 17226211 Archived from the original PDF on 2013 12 24 a b c d e f Locomotion in Finned Fish Global e Schools and Communities Initiative GeSCI United Nations Retrieved 7 Sep 2021 nbsp Material was copied from this source which is available under a Creative Commons Attribution 4 0 International License Long Jr J H Shepherd W amp Root R G 1997 Manueuverability and reversible propulsion How eel like fish swim forward and backward using travelling body waves In Proc Special Session on Bio Engineering Research Related to Autonomous Underwater Vehicles 10th Int Symp Unmanned Untethered Submersible Technology pp 118 134 Hawkins JD Sepulveda CA Graham JB Dickson KA 2003 Swimming performance studies on the eastern Pacific bonito Sarda chiliensis a close relative of the tunas family Scombridae II Kinematics The Journal of Experimental Biology 206 16 2749 2758 doi 10 1242 jeb 00496 PMID 12847120 Klimley A Peter 2013 The Biology of Sharks Skates and Rays University of Chicago Press ISBN 978 0 226 44249 5 Lindsey C C 1978 Locomotion In Hoar W S Randall D J eds Fish Physiology Vol 7 Academic Press San Francisco pp 1 100 Fulton CJ Johansen JL Steffensen JF 2013 Energetic extremes in aquatic locomotion by coral reef fishes PLOS ONE 8 1 e54033 Bibcode 2013PLoSO 854033F doi 10 1371 journal pone 0054033 PMC 3541231 PMID 23326566 Bennetta William J 1996 Deep Breathing Archived from the original on 2007 08 14 Retrieved 2007 08 28 Do sharks sleep Flmnh ufl edu 2017 05 02 Archived from the original on 2010 09 18 a b Blake R W 2004 Review Paper Fish functional design and swimming performance Journal of Fish Biology 65 5 1193 1222 doi 10 1111 j 0022 1112 2004 00568 x a b Weihs Daniel 2002 Stability versus Maneuverability in Aquatic Locomotion Integrated and Computational Biology 42 1 127 134 doi 10 1093 icb 42 1 127 PMID 21708701 Fulton C J Bellwood D R Wainwright P C 2005 Wave energy and swimming performance shape coral reef fish assemblages Proceedings of the Royal Society B 272 1565 827 832 doi 10 1098 rspb 2004 3029 PMC 1599856 PMID 15888415 Heatwole S J Fulton C J 2013 Behavioural flexibility in coral reef fishes responding to a rapidly changing environment Marine Biology 160 3 677 689 doi 10 1007 s00227 012 2123 2 S2CID 85119253 McHenry Matthew J Lauder George V 2006 Ontogeny of Form and Function Locomotor Morphology and Drag in Zebrafish Danio rerio Journal of Morphology 267 9 1099 1109 doi 10 1002 jmor 10462 PMID 16752407 S2CID 33343483 a b c d e f Fish F E 1990 Wing design and scaling of flying fish with regard to flight performance J Zool Lond 221 391 403 a b c Fish Frank 1991 On a Fin and a Prayer Scholars 3 1 4 7 Cairns Museum Tour Cairns Kuranda Railway Archived from the original on 2015 01 08 Retrieved 2015 01 08 Climbing Fish Archived from the original on 2009 08 29 Retrieved 2015 02 26 Maryland Suffers Setback in War on Invasive Walking Fish National Geographic News July 12 2002 Shells trees and bottoms Strange places fish live Tropical fish can live for months out of water Reuters 15 November 2007 Fish Lives in Logs Breathing Air for Months at a Time Fish Lives in Logs Breathing Air for Months at a Time Jones AT KJ Sulak 1990 First Central Pacific Plate and Hawaiian Record of the Deep sea Tripod Fish Bathypterois grallator Pisces Chlorophthalmidae PDF Pacific Science 44 3 254 7 Fish uses fins to walk and bound Behavioral evidence for the evolution of walking and bounding before terrestriality in sarcopterygian fishes A Small Step for Lungfish a Big Step for the Evolution of Walking Monks Neale 2006 Brackish Water Fishes TFH pp 223 226 ISBN 978 0 7938 0564 8 Allen Gerry 1999 Marine Fishes of Southeast Asia A Field Guide for Anglers and Divers Tuttle Publishing p 56 ISBN 978 1 4629 1707 5 many have a bony sharp tail and are equally adept at burrowing forward or backward a b c Flow Patterns Of Larval Fish Undulatory Swimming in the Intermediate Flow Regime by Ulrike K Muller Jos G M van den Boogaart and Johan L van Leeuwen Journal of Experimental Biology 2008 211 196 205 doi 10 1242 jeb 005629 a b c Critical Swimming Speeds of Late Stage Coral Reef Fish Larvae Variation within Species Among Species and Between Locations by Fisher R Leis J M Clark D L in Marine Biology 2005 147 1201 https doi org 10 1007 s00227 005 0001 x Development of Swimming Abilities in Reef Fish Larvae by Rebecca Fisher David R Bellwood Suresh D Job in Marine Ecology progress Series MAR ECOL PROGR SER 202 163 173 10 3354 meps202163 Maximum Sustainable Swimming Speeds Of Late Stage Larvae Of Nine Species Of Reef Fishes by Rebecca Fisher Shaun K Wilson in Journal of Experimental Marine Biology and Ecology Volume 312 Issue 1 2004 Pages 171 186 ISSN 0022 0981 https doi org 10 1016 j jembe 2004 06 009 Development of Swimming Abilities in Reef Fish Larvae by Rebecca Fisher David R Bellwood Suresh D Job in Marine Ecology progress Series MAR ECOL PROGR SER 202 163 173 10 3354 meps202163 van Leeuwen Johan L Voesenek Cees J Muller Ulrike K 2015 How body torque and Strouhal number change with swimming speed and developmental stage in larval zebrafish Journal of the Royal Society Interface 12 110 The Royal Society 20150479 doi 10 1098 rsif 2015 0479 ISSN 1742 5689 PMC 4614456 PMID 26269230 How body torque and Strouhal number change with swimming speed and developmental stage in larval zebrafish by Johan L van Leeuwen Cees J Voesenek and Ulrike K Muller in J R Soc Interface 2015 12 20150479 DOI 10 1098 rsif 2015 0479 6 September 2015 China Victor Holzman Roi 19 May 2014 Hydrodynamic starvation in first feeding larval fishes Proceedings of the National Academy of Sciences 111 22 8083 8088 Bibcode 2014PNAS 111 8083C doi 10 1073 pnas 1323205111 ISSN 0027 8424 PMC 4050599 PMID 24843180 a b c China Victor Levy Liraz Liberzon Alex Elmaliach Tal Holzman Roi 26 April 2017 Hydrodynamic regime determines the feeding success of larval fish through the modulation of strike kinematics Proceedings of the Royal Society B Biological Sciences 284 1853 The Royal Society 20170235 doi 10 1098 rspb 2017 0235 ISSN 0962 8452 PMC 5413926 PMID 28446697 Drost M R Muller M Osse J W M 23 August 1988 A quantitative hydrodynamical model of suction feeding in larval fishes the role of frictional forces Proceedings of the Royal Society of London Series B Biological Sciences 234 1276 The Royal Society 263 281 Bibcode 1988RSPSB 234 263D doi 10 1098 rspb 1988 0048 ISSN 0080 4649 S2CID 86188901 a b Stewart William J Cardenas Gilberto S McHenry Matthew J 1 February 2013 Zebrafish larvae evade predators by sensing water flow Journal of Experimental Biology 216 3 The Company of Biologists 388 398 doi 10 1242 jeb 072751 ISSN 1477 9145 PMID 23325859 Ferry Graham Lara A Wainwright Peter C Lauder George V 2003 Quantification of flow during suction feeding in bluegill sunfish Zoology 106 2 Elsevier 159 168 doi 10 1078 0944 2006 00110 ISSN 0944 2006 PMID 16351901 a b Locomotion In Larval Zebrafish Influence of Time of Day Lighting and Ethanol by R C MacPhail J Brooks D L Hunter B Padnos a T D Irons S Padilla in Neurotoxicology 30 52 8 10 1016 j neuro 2008 09 011 a b c Modulation of Locomotor Activity in Larval Zebrafish During Light Adaptation by Harold A Burgess and Michael Granato In Journal of Experimental Biology 2007 210 2526 2539 doi 10 1242 jeb 003939Further reading editAlexander R McNeill 2003 Principles of Animal Locomotion Princeton University Press ISBN 0 691 08678 8 Eloy Christophe 2013 On the best design for undulatory swimming Journal of Fluid Mechanics 717 48 89 Bibcode 2013JFM 717 48E doi 10 1017 jfm 2012 561 S2CID 56438579 Lauder GV Nauen JC Drucker EG 2002 Experimental Hydrodynamics and Evolution Function of Median Fins in Ray finned Fishes Integr Comp Biol 42 5 1009 1017 doi 10 1093 icb 42 5 1009 PMID 21680382 Videler JJ 1993 Fish Swimming Springer ISBN 9780412408601 Vogel Steven 1994 Life in Moving Fluid The Physical Biology of Flow Princeton University Press ISBN 0 691 02616 5 particularly pp 115 117 and pp 207 216 for specific biological examples swimming and flying respectively Wu Theodore Y T Brokaw Charles J Brennen Christopher Eds 1975 Swimming and Flying in Nature Volume 2 Plenum Press ISBN 0 306 37089 1 particularly pp 615 652 for an in depth look at fish swimming External links editHow fish swim study solves muscle mystery Simulated fish locomotion Basic introduction to the basic principles of biologically inspired swimming robots The biomechanics of swimming Retrieved from https en wikipedia org w index php title Fish locomotion amp oldid 1222044276 Labriform, wikipedia, wiki, book, books, library,

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