Jump to content

Mantis shrimp

From Wikipedia, the free encyclopedia
(Redirected from Unipeltata)

Mantis shrimp
Temporal range: Carboniferous–Recent
Odontodactylus scyllarus (Red Mantis Shrimp)
Lysiosquillina maculata (Zebra Mantis Shrimp)
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Malacostraca
Subclass: Hoplocarida
Order: Stomatopoda
Latreille, 1817
Subdivisions[1]

Mantis shrimp are carnivorous marine crustaceans of the order Stomatopoda (from Ancient Greek στόμα (stóma) 'mouth' and ποδός (podós) 'foot'). Stomatopods branched off from other members of the class Malacostraca around 400 million years ago.[2] Mantis shrimp typically grow to around 10 cm (3.9 in) in length, while a few can reach up to 38 cm (15 in).[3] A mantis shrimp's carapace covers only the rear part of the head and the first four segments of the thorax. Varieties range in colour from shades of brown to vivid colours, with more than 520 species of mantis shrimp known. They are among the most important predators in many shallow, tropical and subtropical marine habitats. However, despite being common, they are poorly understood, as many species spend most of their lives sheltering in burrows and holes.[4]

Called "sea locusts" by ancient Assyrians, "prawn killers" in Australia,[5] and now sometimes referred to as "thumb splitters" due to their ability to inflict painful wounds if handled incautiously,[6] mantis shrimp have powerful raptorial appendages that are used to attack and kill prey either by spearing, stunning, or dismembering. Some mantis shrimp species have specialised calcified 'clubs' that can strike with great power, while others have sharp forelimbs used to seize the prey (hence the term "mantis" in their common name).

Ecology

[edit]

About 520 species of mantis shrimp have been discovered worldwide; all living species are in the suborder Unipeltata, which arose around 250 million years ago.[2][7]

These aggressive and typically solitary sea creatures spend most of their time hiding in rock formations or burrowing intricate passageways in the seabed. They rarely exit their homes except to feed and relocate, and can be diurnal, nocturnal, or crepuscular (active at twilight), depending on the species. Unlike most crustaceans, they sometimes hunt, chase, and kill prey. Although some live in temperate seas, most species live in tropical and subtropical waters in the Indian and Pacific Oceans between eastern Africa and Hawaii.

Habitat

[edit]
Odontodactylus latirostris at Wakatobi National Park Sulawesi

Mantis shrimp live in burrows where they spend the majority of their time.[8] The spearing species build their habitat in soft sediments and the smashing species make burrows in hard substrata or coral cavities.[8] These two habitats are crucial for their ecology since they use burrows as sites for retreat and as locations for consuming their prey.[8] Burrows and coral cavities are also used as sites for mating and for keeping their eggs safe.[8] Stomatopod body size undergoes periodic growth which necessitates finding a new cavity or burrow that will fit the animal's new diameter.[8] Some spearing species can modify their pre-established habitat if the burrow is made of silt or mud, which can be expanded.[8]

Claws

[edit]
Squilla mantis, showing the spearing appendages
Strike mechanics and spearing movement of the 2nd maxilliped (raptorial claw, ballistic claw) of mantis shrimp

The mantis shrimp's second pair of thoracic appendages has been highly adapted for powerful close-range combat. These claws can accelerate at a rate comparable to that of a 0.22 caliber bullet when fired, having around 1500 newtons of force with each swing/attack.[9] The appendage differences divide mantis shrimp into two main types: those that hunt by impaling their prey with spear-like structures and those that smash prey with a powerful blow from a heavily mineralised club-like appendage. A considerable amount of damage can be inflicted after impact with these robust, hammer-like claws. This club is further divided into three subregions: the impact region, the periodic region, and the striated region. Mantis shrimp are commonly separated into distinct groups (most are categorized as either spearers or smashers but there are some outliers)[10] as determined by the type of claws they possess:

  • Smashers possess a much more developed club and a more rudimentary spear (which is nevertheless quite sharp and still used in fights between their own kind); the club is used to bludgeon and smash their meals apart. The inner aspect of the terminal portion of the appendage can also possess a sharp edge, used to cut prey while the mantis shrimp swims.
  • Spearers are armed with spiny appendages - the spines having barbed tips - used to stab and snag prey. These raptorial appendages resemble those of praying mantids, hence the common name of these crustaceans.
  • Hatchet: A primitive appendage that only a few species have. This body plan is largely unresearched.[11][12][13]
  • Spike Smashers (hammers or primitive smashers): possibly the "missing link" to relate the two most common (spear and smasher) to each other. Very uncommon and even less studied than the hatchet type.[11][12][14]

Both types strike by rapidly unfolding and swinging their raptorial claws at the prey, and can inflict serious damage on victims significantly greater in size than themselves. In smashers, these two weapons are employed with blinding quickness, with an acceleration of 10,400 g (102,000 m/s2 or 335,000 ft/s2) and speeds of 23 m/s (83 km/h; 51 mph) from a standing start.[15] Because they strike so rapidly, they generate vapor-filled bubbles in the water between the appendage and the striking surface—known as cavitation bubbles.[15] The collapse of these cavitation bubbles produces measurable forces on their prey in addition to the instantaneous forces of 1,500 newtons that are caused by the impact of the appendage against the striking surface, which means that the prey is hit twice by a single strike; first by the claw and then by the collapsing cavitation bubbles that immediately follow.[16] Even if the initial strike misses the prey, the resulting shock wave can be enough to stun or kill.

Smashers use this ability to attack crabs, snails, rock oysters, and other molluscs, their blunt clubs enabling them to crack the shells of their prey into pieces. Spearers, however, prefer the meat of softer animals, such as fish and cephalopods, which their barbed claws can more easily slice and snag.

The appendages are being studied as a microscale analogue for new macroscale material structures.[17]

Eyes

[edit]
The front of Lysiosquillina maculata, showing the stalked eyes

The eyes of the mantis shrimp are mounted on mobile stalks and can move independently of each other. The extreme mobility allows them to be rotated in all three dimensions, yet the position of their eyes has shown to have no effect on the perception of their surroundings.[18] They are thought to have the most complex eyes in the animal kingdom and have the most complex front-end for any visual system ever discovered.[19][20][21]

Compared with the three types of photoreceptor cell that humans possess in their eyes, the eyes of a mantis shrimp have between 12 and 16 types of photoreceptor cells. Furthermore, some of these stomatopods can tune the sensitivity of their long wavelength colour vision to adapt to their environment.[22] This phenomenon, called "spectral tuning", is species-specific.[23] Cheroske et al. did not observe spectral tuning in Neogonodactylus oerstedii, the species with the most monotonous natural photic environment. In N. bredini, a species with a variety of habitats ranging from a depth of 5 to 10 m (although it can be found down to 20 m below the surface), spectral tuning was observed, but the ability to alter wavelengths of maximum absorbance was not as pronounced as in N. wennerae, a species with much higher ecological/photic habitat diversity. The diversity of spectral tuning in Stomatopoda is also hypothesised to be directly linked to mutations in the retinal binding pocket of the opsin.[24]

Despite the impressive range of wavelengths that mantis shrimp have the ability to see, they do not have the ability to discriminate wavelengths less than 25 nm apart.[clarification needed] It is suggested that not discriminating between closely positioned wavelengths allows these organisms to make determinations of its surroundings with little processing delay. Having little delay in evaluating surroundings is important for mantis shrimp, since they are territorial and frequently in combat.[25] However, some mantis shrimp have been found capable of distinguishing between high-saturation and low-saturation colors.[26]

The huge diversity seen in mantis shrimp photoreceptors likely comes from ancient gene duplication events.[27][28] One consequence of this duplication is the lack of correlation between opsin transcript number and physiologically expressed photoreceptors.[27] One species may have six different opsin genes, but only express one spectrally distinct photoreceptor. Over the years, some mantis shrimp species have lost the ancestral phenotype, although some still maintain 16 distinct photoreceptors and four light filters. Species that live in a variety of photic environments have high selective pressure for photoreceptor diversity, and maintain ancestral phenotypes better than species that live in murky waters or are primarily nocturnal.[27][29]

Description

[edit]
Close-up of a mantis shrimp showing the structure of the eyes. The three dark spots are pseudopupils, indicating the ommatidia that are pointing towards the camera.
Close up of Oratosquilla oratoria eyes

Each compound eye is made up of tens of thousands of ommatidia, clusters of photoreceptor cells.[20] Each eye consists of two flattened hemispheres separated by parallel rows of specialised ommatidia, collectively called the midband. The number of omatidial rows in the midband ranges from two to six.[19][20] This divides the eye into three regions. This configuration enables mantis shrimp to see objects that are near the mid-plane of an eye with three parts of the same eye (as can be seen in some photos showing three pseudopupils in one eye). In other words, each eye possesses trinocular vision, and therefore depth perception, for objects near its mid-plane. The upper and lower hemispheres are used primarily for recognition of form and motion, like the eyes of many other crustaceans.[19]

Mantis shrimp can perceive wavelengths of light ranging from deep ultraviolet (300 nm) to far-red (720 nm) and polarised light.[20][25] In mantis shrimp in the superfamilies Gonodactyloidea, Lysiosquilloidea, and Hemisquilloidea, the midband is made up of six ommatidial rows. Rows 1 to 4 process colours, while rows 5 and 6 detect circularly or linearly polarised light. Twelve types of photoreceptor cells are in rows 1 to 4, four of which detect ultraviolet light.[19][20][25][30]

Rows 1 to 4 of the midband are specialised for colour vision, from deep ultraviolet to far red. Their UV vision can detect five different frequency bands in the deep ultraviolet. To do this, they use two photoreceptors in combination with four different colour filters.[31][32] They are currently believed insensitive to infrared light.[33] The optical elements in these rows have eight different classes of visual pigments and the rhabdom (area of eye that absorbs light from a single direction) is divided into three different pigmented layers (tiers), each for different wavelengths. The three tiers in rows 2 and 3 are separated by colour filters (intrarhabdomal filters) that can be divided into four distinct classes, two classes in each row. Each consists of a tier, a colour filter of one class, a tier again, a colour filter of another class, and then a last tier. These colour filters allow the mantis shrimp to see with diverse colour vision. Without the filters, the pigments themselves range only a small segment of the visual spectrum, about 490 to 550 nm.[27] Rows 5 and 6 are also segregated into different tiers, but have only one class of visual pigment, the ninth class, and are specialised for polarisation vision. Depending upon the species, they can detect circularly polarised light, linearly polarised light, or both. A tenth class of visual pigment is found in the upper and lower hemispheres of the eye.[19]

Some species have at least 16 photoreceptor types, which are divided into four classes (their spectral sensitivity is further tuned by colour filters in the retinas), 12 for colour analysis in the different wavelengths (including six which are sensitive to ultraviolet light[31][34]) and four for analysing polarised light. By comparison, most humans have only four visual pigments, of which three are dedicated to see colour, and human lenses block ultraviolet light. The visual information leaving the retina seems to be processed into numerous parallel data streams leading into the brain, greatly reducing the analytical requirements at higher levels.[35]

The midband covers only about 5 to 10° of the visual field at any given instant, but like most crustaceans, mantis shrimps' eyes are mounted on stalks. In mantis shrimps, the movement of the stalked eye is unusually free, and can be driven up to 70° in all possible axes of movement by eight eyecup muscles divided into six functional groups. By using these muscles to scan the surroundings with the midband, they can add information about forms, shapes, and landscape, which cannot be detected by the upper and lower hemispheres of the eyes. They can also track moving objects using large, rapid eye movements where the two eyes move independently. By combining different techniques, including movements in the same direction, the midband can cover a very wide range of the visual field.[citation needed]

Polarized light

[edit]

Six species of mantis shrimp have been reported to be able to detect circularly polarised light, which has not been documented in any other animal, and whether it is present across all species is unknown.[36][37][38] They perform this feat by converting circularly polarized light into linearly polarized light via quarter-waveplates formed from stacks of microvilli. Some of their biological quarter-waveplates perform more uniformly over the visual spectrum than any current man-made polarising optics, and this could inspire new types of optical media that would outperform early 21st century Blu-ray Disc technology.[39][40]

The species Gonodactylus smithii is the only organism known to simultaneously detect the four linear and two circular polarisation components required to measure all four Stokes parameters, which yield a full description of polarisation. It is thus believed to have optimal polarisation vision.[37][41] It is the only animal known to have dynamic polarisation vision. This is achieved by rotational eye movements to maximise the polarisation contrast between the object in focus and its background.[42] Since each eye moves independently from the other, it creates two separate streams of visual information.[43]

Suggested advantages of visual system

[edit]
Close-up of the trinocular vision of Pseudosquilla ciliata

What advantage sensitivity to polarisation confers is unclear; however, polarisation vision is used by other animals for sexual signaling and secret communication that avoids the attention of predators.[44] This mechanism could provide an evolutionary advantage; it only requires small changes to the cell in the eye and could easily lead to natural selection.[45]

The eyes of mantis shrimps may enable them to recognise different types of coral, prey species (which are often transparent or semitransparent), or predators, such as barracuda, which have shimmering scales. Alternatively, the manner in which they hunt (very rapid movements of the claws) may require very accurate ranging information, which would require accurate depth perception.

During mating rituals, mantis shrimps actively fluoresce, and the wavelength of this fluorescence matches the wavelengths detected by their eye pigments.[46] Females are only fertile during certain phases of the tidal cycle; the ability to perceive the phase of the moon may, therefore, help prevent wasted mating efforts. It may also give these shrimps information about the size of the tide, which is important to species living in shallow water near the shore.

The capacity to see UV light may enable observation of otherwise hard-to-detect prey on coral reefs.[34]

Researchers suspect that the broader variety of photoreceptors in the eyes of mantis shrimps allows visual information to be preprocessed by the eyes instead of the brain, which would otherwise have to be larger to deal with the complex task of opponent process colour perception used by other species, thus requiring more time and energy. While the eyes themselves are complex and not yet fully understood, the principle of the system appears to be simple.[47] It has a similar set of sensitivities to the human visual system, but works in the opposite manner. In the human brain, the inferior temporal cortex has a huge number of colour-specific neurons, which process visual impulses from the eyes to extract colour information. The mantis shrimp instead uses the different types of photoreceptors in its eyes to perform the same function as the human brain neurons, resulting in a hardwired and more efficient system for an animal that requires rapid colour identification. Humans have fewer types of photoreceptors, but more colour-tuned neurons, while mantis shrimp appear to have fewer colour neurons and more classes of photoreceptors.[48]

However, a study from 2022 failed to find unequivocal evidence for a solely "barcode"-like visual system as described above. Stomatopods of the species Haptosquilla trispinosa were able to distinguish high and low-saturation colors from grey, contravening Thoen and colleagues.[26][25] It may be that some combination of color opponency and photoreceptor activation comparison/barcode analysis is present.[26]

The shrimps use a form of reflector of polarised light not seen in nature or human technology before. It allows the manipulation of light across the structure rather than through its depth, the typical way polarisers work. This allows the structure to be both small and microscopically thin, and still be able to produce big, bright, colourful polarised signals.[49]

Behavior

[edit]
Drawing of a mantis shrimp by Richard Lydekker, 1896

Mantis shrimp are long-lived and exhibit complex behaviour, such as ritualised fighting. Some species use fluorescent patterns on their bodies for signalling with their own and maybe even other species, expanding their range of behavioural signals. They can learn and remember well, and are able to recognise individual neighbours with which they frequently interact. They can recognise them by visual signs and even by individual smell. Many have developed complex social behaviours to defend their space from rivals.

In a lifetime, they can have as many as 20 or 30 breeding episodes. Depending on the species, the eggs can be laid and kept in a burrow, or they can be carried around under the female's tail until they hatch. Also depending on the species, males and females may come together only to mate, or they may bond in monogamous, long-term relationships.[50]

In the monogamous species, the mantis shrimps remain with the same partner up to 20 years. They share the same burrow and may be able to coordinate their activities. Both sexes often take care of the eggs (bi-parental care). In Pullosquilla and some species in Nannosquilla, the female lays two clutches of eggs – one that the male tends and one that the female tends. In other species, the female looks after the eggs while the male hunts for both of them. After the eggs hatch, the offspring may spend up to three months as plankton.

Although stomatopods typically display the standard types of movement seen in true shrimp and lobsters, one species, Nannosquilla decemspinosa, has been observed flipping itself into a crude wheel. The species lives in shallow, sandy areas. At low tides, N. decemspinosa is often stranded by its short rear legs, which are sufficient for movement when the body is supported by water, but not on dry land. The mantis shrimp then performs a forward flip in an attempt to roll towards the next tide pool. N. has been observed to roll repeatedly for 2 m (6.6 ft), but specimens typically travel less than 1 m (3.3 ft).[51]

Culinary uses

[edit]
Mantis shrimp caught at Hậu Lộc, Thanh Hóa, Vietnam

The mantis shrimp is eaten by a variety of cultures. In Japanese cuisine, the mantis shrimp species Oratosquilla oratoria, called shako (蝦蛄), is eaten boiled as a sushi topping, and occasionally raw as sashimi.

Mantis shrimps are also abundant along Vietnam's coast, known in Vietnamese as bề bề, tôm tích or tôm tít. In regions such as Nha Trang, they are called bàn chải, named for its resemblance to a scrub brush. The shrimp can be steamed, boiled, grilled, or dried, used with pepper, salt and lime, fish sauce and tamarind, or fennel.[52]

Drying mantis shrimp at Gò Công, Tiền Giang, Việt Nam.

In Cantonese cuisine, the mantis shrimp is known as "urinating shrimp" (Chinese: 瀨尿蝦; pinyin: lài niào xiā; Jyutping: laai6 niu6 haa1) because of their tendency to shoot a jet of water when picked up. After cooking, their flesh is closer to that of lobsters than that of shrimp, and like lobsters, their shells are quite hard and require some pressure to crack. One common preparation is first deep-frying, then stir-frying with garlic and chili peppers. They may also be boiled or steamed.[citation needed]

In the Mediterranean countries, the mantis shrimp Squilla mantis is a common seafood, especially on the Adriatic coasts (canocchia) and the Gulf of Cádiz (galera).[citation needed]

In the Philippines, the mantis shrimp is known as tatampal, hipong-dapa, pitik-pitik, or alupihang-dagat, and is cooked and eaten like any other shrimp.[citation needed]

In Kiribati, mantis shrimp called te waro in Gilbertese are abundant and are eaten boiled. In Hawaii, some mantis shrimp have grown unusually large in the contaminated water of the Grand Ala Wai Canal in Waikiki. The dangers normally associated with consuming seafood caught in contaminated waters are present in these mantis shrimp.[3]

Aquaria

[edit]
Peacock mantis shrimp

Some saltwater aquarists keep stomatopods in captivity.[53] The peacock mantis is especially colourful and desired in the trade.

While some aquarists value mantis shrimps, others consider them harmful pests, because they are voracious predators, eating other desirable inhabitants of the tank. Additionally, some rock-burrowing species can do more damage to live rock than the fishkeeper would prefer.

The live rock with mantis shrimp burrows is considered useful by some in the marine aquarium trade and is often collected. A piece of live rock not uncommonly conveys a live mantis shrimp into an aquarium. Once inside the tank, it may feed on fish and other inhabitants, and is notoriously difficult to catch when established in a well-stocked tank.[54] While there are accounts of this shrimp breaking glass tanks, they are rare and are usually the result of the shrimp being kept in too small a tank. While stomatopods do not eat coral, smashers can damage it if they try to make a home within it.[55]

Evolutionary history

[edit]
Reconstruction of Daidal, a primitive Carboniferous mantis shrimp

Although the Devonian Eopteridae have been suggested to be early stomatopods, their fragmentary known remains make the referral uncertain.[56] The oldest unambiguous stem-group mantis shrimp date to the Carboniferous (359-300 million years ago).[56][57] Stem-group mantis shrimp are assigned to two major groups the Palaeostomatopodea and the Archaeostomatopodea, the latter of which are more closely related to modern mantis shrimp, which are assigned to the clade Unipeltata.[56] The oldest members of Unipeltata date to the Triassic.[57]

Example species

[edit]

A large number of mantis shrimp species were first scientifically described by one carcinologist, Raymond B. Manning; the collection of stomatopods he amassed is the largest in the world, covering 90% of the known species whilst 10% are still unknown.[58]

See also

[edit]

References

[edit]
  1. ^ Joel W. Martin & George E. Davis (2001). An Updated Classification of the Recent Crustacea (PDF). Natural History Museum of Los Angeles County. p. 132. Archived from the original (PDF) on 2013-05-12. Retrieved 2009-12-14.
  2. ^ a b Van Der Wal, Cara; Ahyong, Shane T.; Ho, Simon Y. W.; Lo, Nathan (21 September 2017). "The evolutionary history of Stomatopoda (Crustacea: Malacostraca) inferred from molecular data". PeerJ. 5: e3844. doi:10.7717/peerj.3844. PMC 5610894. PMID 28948111.
  3. ^ a b James Gonser (February 15, 2003). "Large shrimp thriving in Ala Wai Canal muck". The Honolulu Advertiser. Archived from the original on November 11, 2020. Retrieved July 20, 2006.
  4. ^ Ross Piper (2007). Extraordinary Animals: An Encyclopedia of Curious and Unusual Animals. Greenwood Press. ISBN 978-0-313-33922-6.
  5. ^ "Mantis shrimp". Queensland Museum. Archived from the original on January 21, 2021.
  6. ^ Gilbert L. Voss (2002). "Order Stomatopoda: Mantis shrimp or thumb splitters". Seashore Life of Florida and the Caribbean. Dover pictorial archive series. Courier Dover Publications. pp. 120–122. ISBN 978-0-486-42068-4.
  7. ^ "Stomatopoda". Tree of Life Web Project. January 1, 2002. Archived from the original on October 2, 2022. Retrieved August 26, 2007.
  8. ^ a b c d e f Mead, K.; Caldwell, R. (2001). "Mantis Shrimp: Olfactory Apparatus and Chemosensory Behavior". In Breithaupt, T.; Thiel, M. (eds.). Chemical Communication in Crustaceans. Chile: Springer. p. 219. ISBN 9780387771014.
  9. ^ "How the Mantis Shrimp Packs its Punch | Biomechanics in the Wild".
  10. ^ "Why are Mantis Shrimp so Awesome?". California Academy of Sciences. Archived from the original on 2022-08-10. Retrieved 2022-07-21.
  11. ^ a b "How mantis shrimp evolved many shapes with same powerful punch". phys.org. Archived from the original on 2022-07-21. Retrieved 2022-07-21.
  12. ^ a b "Roy's List of Stomatopods for the Aquarium". ucmp.berkeley.edu. Archived from the original on 2022-08-23. Retrieved 2022-07-21.
  13. ^ "a_derijardi". ucmp.berkeley.edu. Archived from the original on 2022-01-31. Retrieved 2022-07-21.
  14. ^ "h_californiensis". ucmp.berkeley.edu. Archived from the original on 2023-04-18. Retrieved 2022-07-21.
  15. ^ a b S. N. Patek, W. L. Korff & R. L. Caldwell (2004). "Deadly strike mechanism of a mantis shrimp" (PDF). Nature. 428 (6985): 819–820. Bibcode:2004Natur.428..819P. doi:10.1038/428819a. PMID 15103366. S2CID 4324997. Archived from the original (PDF) on 2021-01-26. Retrieved 2017-05-02.
  16. ^ S. N. Patek & R. L. Caldwell (2005). "Extreme impact and cavitation forces of a biological hammer: strike forces of the peacock mantis shrimp". Journal of Experimental Biology. 208 (19): 3655–3664. doi:10.1242/jeb.01831. PMID 16169943.
  17. ^ "Mantis shrimp inspires next generation of ultra-strong materials". Space Daily. June 1, 2016. Archived from the original on May 24, 2021. Retrieved May 13, 2020.
  18. ^ Daly, Ilse M.; How, Martin J.; Partridge, Julian C.; Roberts, Nicholas W. (May 16, 2018). "Complex gaze stabilization in mantis shrimp". Proceedings of the Royal Society B: Biological Sciences. 285 (1878): 20180594. doi:10.1098/rspb.2018.0594. PMC 5966611. PMID 29720419.
  19. ^ a b c d e Cronin, Thomas W.; Bok, Michael J.; Marshall, N. Justin; Caldwell, Roy L. (19 February 2014). "Filtering and polychromatic vision in mantis shrimps: themes in visible and ultraviolet vision". Philosophical Transactions of the Royal Society B: Biological Sciences. 369 (1636): 20130032. doi:10.1098/rstb.2013.0032. PMC 3886321. PMID 24395960.
  20. ^ a b c d e Franklin, Amanda M. (September 4, 2013). "Mantis shrimp have the world's best eyes – but why?". The Conversation. Archived from the original on July 5, 2018. Retrieved July 5, 2018.
  21. ^ Milius, Susan (2012). "Mantis shrimp flub color vision test". Science News. 182 (6): 11. doi:10.1002/scin.5591820609. JSTOR 23351000.
  22. ^ Cronin, Thomas W. (2001). "Sensory adaptation: Tunable colour vision in a mantis shrimp". Nature. 411 (6837): 547–8. Bibcode:2001Natur.411..547C. doi:10.1038/35079184. PMID 11385560. S2CID 205017718.
  23. ^ Cheroske, Alexander G.; Barber, Paul H.; Cronin, Thomas W. (2006). "Evolutionary variation in the expression of phenotypically plastic color vision in Caribbean mantis shrimps, genus Neogonodactylus" (PDF). Marine Biology. 150 (2): 213–220. Bibcode:2006MarBi.150..213C. doi:10.1007/s00227-006-0313-5. hdl:1912/1391. S2CID 40203342. Archived from the original on 2024-01-04. Retrieved 2019-09-02.
  24. ^ Porter, Megan L.; Bok, Michael J.; Robinson, Phyllis R.; Cronin, Thomas W. (1 May 2009). "Molecular diversity of visual pigments in Stomatopoda (Crustacea)". Visual Neuroscience. 26 (3): 255–265. doi:10.1017/S0952523809090129. PMID 19534844. S2CID 6516816.
  25. ^ a b c d Thoen, Hanne H.; How, Martin J.; Chiou, Tsyr-Huei; Marshall, Nicholas Justin (January 24, 2014). "A Different Form of Color Vision in Mantis Shrimp". Science. 334 (6169): 411–413. Bibcode:2014Sci...343..411T. doi:10.1126/science.1245824. PMID 24458639. S2CID 31784941.
  26. ^ a b c Streets, Amy; England, Hayley; Marshall, Justin (2022-03-15). "Colour vision in stomatopod crustaceans: more questions than answers". Journal of Experimental Biology. 225 (6). doi:10.1242/jeb.243699. ISSN 0022-0949. PMC 9001920. PMID 35224643.
  27. ^ a b c d "The molecular genetics and evolution of colour and polarization vision in stomatopod crustaceans". Ophthalmic Physiology. 30.
  28. ^ Porter, Megan L.; Speiser, Daniel I.; Zaharoff, Alexander K.; Caldwell, Roy L.; Cronin, Thomas W.; Oakley, Todd H. (2013). "The Evolution of Complexity in the Visual Systems of Stomatopods: Insights from Transcriptomics". Integrative and Comparative Biology. 53 (1): 39–49. doi:10.1093/icb/ict060. PMID 23727979.
  29. ^ "Evolution of anatomical and physiological specialisation in the compound eyes of stomatopod crustaceans". Journal of Experimental Biology. 213.
  30. ^ Marshall, Nicholas Justin; Oberwinkler, Johannes (October 28, 1999). "Ultraviolet vision: the colourful world of the mantis shrimp". Nature. 401 (6756): 873–874. Bibcode:1999Natur.401..873M. doi:10.1038/44751. PMID 10553902. S2CID 4360184.
  31. ^ a b Michael Bok; Megan Porter; Allen Place; Thomas Cronin (2014). "Biological Sunscreens Tune Polychromatic Ultraviolet Vision in Mantis Shrimp". Current Biology. 24 (14): 1636–42. Bibcode:2014CBio...24.1636B. doi:10.1016/j.cub.2014.05.071. PMID 24998530.
  32. ^ Mantis shrimp wear tinted shades to see UV light Archived 2014-11-22 at the Wayback Machine. Latimes.com (2014-07-05). Retrieved on 2015-10-21.
  33. ^ David Cowles; Jaclyn R. Van Dolson; Lisa R. Hainey; Dallas M. Dick (2006). "The use of different eye regions in the mantis shrimp Hemisquilla californiensis Stephenson, 1967 (Crustacea: Stomatopoda) for detecting objects". Journal of Experimental Marine Biology and Ecology. 330 (2): 528–534. Bibcode:2006JEMBE.330..528C. doi:10.1016/j.jembe.2005.09.016.
  34. ^ a b DuRant, Hassan (3 July 2014). "Mantis shrimp use 'nature's sunblock' to see UV". sciencemag.org. Archived from the original on 25 April 2023. Retrieved 5 July 2014.
  35. ^ Cronin, Thomas W.; Marshall, Justin (2001). "Parallel processing and image analysis in the eyes of mantis shrimps". The Biological Bulletin. 200 (2): 177–183. doi:10.2307/1543312. JSTOR 1543312. PMID 11341580. S2CID 12381929. Archived from the original on 2020-06-19. Retrieved 2021-05-24.
  36. ^ Chiou, Tsyr-Huei; Kleinlogel, Sanja; Cronin, Tom; Caldwell, Roy; Loeffler, Birte; Siddiqi, Afsheen; Goldzien, Alan; Marshall, Justin (March 25, 2008). "Circular polarization vision in a stomatopod crustacean". Current Biology. 18 (6): 429–434. Bibcode:2008CBio...18..429C. doi:10.1016/j.cub.2008.02.066. PMID 18356053. S2CID 6925705.
  37. ^ a b Kleinlogel, Sonja; White, Andrew (2009). "The secret world of shrimps: polarisation vision at its best". PLoS ONE. 3 (5): e2190. arXiv:0804.2162. Bibcode:2008PLoSO...3.2190K. doi:10.1371/journal.pone.0002190. PMC 2377063. PMID 18478095.
  38. ^ Templin, Rachel M.; How, Martin J.; Roberts, Nicholas W.; Chiou, Tsyr-Huei; Marshall, Justin (15 September 2017). "Circularly polarized light detection in stomatopod crustaceans: a comparison of photoreceptors and possible function in six species". The Journal of Experimental Biology. 220 (18): 3222–3230. doi:10.1242/jeb.162941. hdl:1983/1f1c982f-9a88-4184-b59a-2cebd73ec818. PMID 28667244.
  39. ^ Roberts, Nicholas W.; Chiou, Tsyr-Huei; Marshall, Nicholas Justin; Cronin, Thomas W. (2009). "A biological quarter-wave retarder with excellent achromaticity in the visible wavelength region". Nature Photonics. 3 (11): 641–644. Bibcode:2009NaPho...3..641R. doi:10.1038/nphoton.2009.189.
  40. ^ Lee, Chris (November 1, 2009). "A crustacean eye that rivals the best optical equipment". Nobel Intent. Ars Technica. Archived from the original on April 5, 2012. Retrieved June 14, 2017.
  41. ^ Minard, Anne (May 19, 2008). ""Weird beastie" shrimp have super-vision". National Geographic Society. Archived from the original on May 27, 2008.
  42. ^ Daly, Ilse M.; How, Martin J.; Partridge, Julian C.; Roberts, Nicholas W. (2018-05-16). "Complex gaze stabilization in mantis shrimp". Proceedings of the Royal Society B: Biological Sciences. 285 (1878): 20180594. doi:10.1098/rspb.2018.0594. PMC 5966611. PMID 29720419.
  43. ^ "Mantis shrimp have perfected the eye roll to see things we can't imagine". Newsweek. 14 July 2016. Archived from the original on 6 February 2017. Retrieved 6 February 2017.
  44. ^ How, M. J.; Porter, M. L.; Radford, A. N.; Feller, K. D.; Temple, S. E.; Caldwell, R. L.; Marshall, N. J.; Cronin, T. W.; Roberts, N. W. (7 August 2014). "Out of the blue: the evolution of horizontally polarized signals in Haptosquilla (Crustacea, Stomatopoda, Protosquillidae)". Journal of Experimental Biology. 217 (19): 3425–3431. doi:10.1242/jeb.107581. hdl:11603/13393. PMID 25104760.
  45. ^ "Mantis shrimps could show us the way to a better DVD" (Press release). University of Bristol. 25 October 2009. Archived from the original on 31 October 2020. Retrieved May 13, 2020.
  46. ^ C. H. Mazel; T. W. Cronin; R. L. Caldwell; N. J. Marshall (2004). "Fluorescent enhancement of signaling in a mantis shrimp". Science. 303 (5654): 51. doi:10.1126/science.1089803. PMID 14615546. S2CID 35009047.
  47. ^ Morrison, Jessica (23 January 2014). "Mantis shrimp's super colour vision debunked". Nature. doi:10.1038/nature.2014.14578. S2CID 191386729.
  48. ^ Macknik, Stephen L. (March 20, 2014). "Parallels between Shrimp and Human Color Vision". Scientific American Blog Network. Archived from the original on May 25, 2020. Retrieved May 13, 2020.
  49. ^ New type of optical material discovered in the secret language of the mantis shrimp Archived 2016-03-07 at the Wayback Machine. Bristol University (17 February 2016)
  50. ^ "Sharing the job: monogamy and parental care". University of California, Berkeley. Archived from the original on 2009-09-14. Retrieved 2009-11-13.
  51. ^ Caldwell, Roy L. (1979). "A unique form of locomotion in a stomatopod – backward somersaulting". Nature. 282 (5734): 71–73. Bibcode:1979Natur.282...71C. doi:10.1038/282071a0. S2CID 4311328.
  52. ^ "Tôm tít – Đặc sản miền sông nước" (in Vietnamese). Dinh dưỡng. October 1, 2009. Archived from the original on August 16, 2012. Retrieved January 8, 2011.
  53. ^ A Load of Learnin' About Mantis Shrimps Archived 2011-07-15 at the Wayback Machine, by James Fatherree, in ReefKeeping Archived 2014-02-19 at the Wayback Machine online magazine.
  54. ^ Nick Dakin (2004). The Marine Aquarium. London: Andromeda. ISBN 978-1-902389-67-7.
  55. ^ April Holladay (September 1, 2006). "Shrimp spring into shattering action". USA Today. Archived from the original on 2012-06-30. Retrieved 2017-09-04.
  56. ^ a b c Van Der Wal, Cara; Ahyong, Shane T.; Ho, Simon Y.W.; Lo, Nathan (2017-09-21). "The evolutionary history of Stomatopoda (Crustacea: Malacostraca) inferred from molecular data". PeerJ. 5: e3844. doi:10.7717/peerj.3844. ISSN 2167-8359. PMC 5610894. PMID 28948111.
  57. ^ a b Smith, C.P.A.; Aubier, P.; Charbonnier, S.; Laville, T.; Olivier, N.; Escarguel, G.; Jenks, J.F.; Bylund, K.G.; Fara, E.; Brayard, A. (2023-03-31). "Closing a major gap in mantis shrimp evolution - first fossils of Stomatopoda from the Triassic". Bulletin of Geosciences: 95–110. doi:10.3140/bull.geosci.1864. ISSN 1802-8225. Archived from the original on 2023-06-06. Retrieved 2023-05-23.
  58. ^ Paul F. Clark & Frederick R. Schram (2009). "Raymond B. Manning: an appreciation". Journal of Crustacean Biology. 29 (4): 431–457. doi:10.1651/09-3158.1. S2CID 85803151.
[edit]