Temporal range: Devonian–Recent
|A live lined chiton, Tonicella lineata photographed in situ: The anterior end of the animal is to the right.|
They are also sometimes known as sea cradles or "coat-of-mail shells", or more formally as loricates, polyplacophorans, and occasionally as polyplacophores.
Chitons have a dorsal shell, which is composed of eight separate shell plates or valves. These plates overlap somewhat at the front and back edges, and yet articulate well with one another. Because of this, although the plates provide good protection for impacts from above, they nonetheless permit the chiton to flex upward when needed for locomotion over uneven surfaces, and also allow the animal to slowly curl up into a ball when it is dislodged from the underlying surface. The shell plates are surrounded by a structure known as a girdle.
- Habitat 1
- Shell 2.1
- Girdle ornament 2.2
- Internal anatomy 2.3
- Senses 2.4
- Homing ability 3
- Culinary uses 4
Life habits 5
- Reproduction and lifecycle 5.1
- Predators 6
- The largest species 7
- Evolutionary origins 8
- History of scientific investigation 9
- Etymology 10
- Taxonomy 11
- References 12
- External links 13
Chitons live worldwide, in cold water, warm water, and in the tropics. Most chiton species inhabit intertidal or subtidal zones, and do not extend beyond the photic zone.
They live on hard surfaces, such as on or under rocks, or in rock crevices. Some species live quite high in the intertidal zone and are exposed to the air and light for long periods. Others live subtidally. A few species live in deep water, as deep as 6,000 m (20,000 ft).
Chitons are exclusively and fully marine. This is in contrast to the bivalves, which were able to adapt to brackish water and fresh water, and the gastropods which were able to make successful transitions to freshwater and terrestrial environments.
All chitons bear a protective dorsal shell that is divided into eight articulating aragonite valves embedded in the tough muscular girdle that surrounds the chiton's body. Compared with the single or two-piece shells of other molluscs, this arrangement allows chitons to roll into a protective ball when dislodged and to cling tightly to irregular surfaces. In some species the valves are reduced or covered by the girdle tissue.  the valves are variously colored, patterned, smooth, or sculptured.
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The most anterior plate is crescent-shaped, and is known as the cephalic plate (sometimes called a "head plate", despite the absence of a complete head). The most posterior plate is known as the anal plate (sometimes called the "tail plate", although chitons do not have tails.)
The inner layer of each of the six intermediate plates is produced anteriorly as an articulating flange, called the articulamentum. This inner layer may also be produced laterally in the form of notched insertion plates. These function as an attachment of the valve plates to the soft body. A similar series of insertion plates may be attached to the convex anterior border of the cephalic plate or the convex posterior border of the anal plate.
The sculpture of the valves is one of the taxonomic characteristics, along with the granulation or spinulation of the girdle.
After a chiton dies, the individual valves which make up the eight-part shell come apart because the girdle is no longer holding them together, and then the plates sometimes wash up in beach drift. The individual shell plates from a chiton are sometimes known as "butterfly shells" due to their shape.
The girdle may be ornamented with scales or spicules which, like the shell plates, are mineralized with aragonite – although a different mineralization process operates in the spicules to in the teeth or shells (implying an independent evolutionary innovation). This process seems quite simple in comparison to other shell tissue; in some taxa, the crystal structure of the deposited minerals closely resembles the disordered nature of crystals that form inorganically, although more order is visible in other taxa.
The protein component of the scales and sclerites is minuscule in comparison with other biomineralized structures, whereas the total proportion of matrix is 'higher' than in mollusc shells. This implies that polysaccharides make up the bulk of the matrix. The girdle spines often bear length-parallel striations.
The wide form of girdle ornament suggests it serves a secondary role; chitons can survive perfectly well without them. Camouflage or defence are two likely functions.
Spicules are secreted by cells that do not express "engrailed", but these cells are surrounded by engrailed-expressing cells. These neighbouring cells secrete an organic pellicle on the outside of the developing spicule, whose aragonite is deposited by the central cell; subsequent division of this central cell allows larger spines to be secreted in certain taxa. The organic pellicule is found in most polyplacophora (but not 'basal' chitons, such as Hanleya) but is unusual in aplacophora. Developmentally, sclerite-secreting cells arise from pretrochal and postrochal cells: the 1a, 1d, 2a, 2c, 3c and 3d cells. The shell plates arise primarily from the 2d micromere, although 2a, 2b, 2c and sometimes 3c cells also participate in its secretion.
The girdle is often ornamented with spicules, bristles, hairy tufts, spikes, or snake-like scales. The majority of the body is a snail-like foot, but no head or other soft parts beyond the girdle are visible from the dorsal side. The mantle cavity consists of a narrow channel on each side, lying between the body and the girdle. Water enters the cavity through openings either side of the mouth, then flows along the channel to a second, exhalant, opening close to the anus. Multiple gills hang down into the mantle cavity along part or all of the lateral pallial groove, each consisting of a central axis with a number of flattened filaments through which oxygen can be absorbed.
The three-chambered heart is located towards the animal's hind end. Each of the two auricles collects blood from the gills on one side, while the muscular ventricle pumps blood through the aorta and round the body.
The excretory system consists of two nephridia, which connect to the pericardial cavity around the heart, and remove excreta through a pore that opens near the rear of the mantle cavity. The single gonad is located in front of the heart, and releases gametes through a pair of pores just in front of those used for excretion.
- Extensive list of species, classified by families
- Sirenko B.I. New outlook on the system of chitons (Mollusca: Polyplacophora). Venus, 65 (1-2): 27-49, 2006
- Schwabe, E., 2005. A catalogue of recent and fossil chitons (Mollusca: Polyplacophora) addenda. Novapex 6, 89–105.
- Stebbins, T.D., Eernisse, D.J., 2009. Chitons (Mollusca: Polyplacophora) known from benthic monitoring programs in the Southern California Bight. The Festivus 41, 53–100.
- Puchalski, S., Eernisse, D.J., Johnson, C.C., 2008. The effect of sampling bias on the fossil record of chitons (Mollusca, Polyplacophora). American Malacological Bulletin. 25, 87–95.
- Connors, M.J., H. Ehrlich, M. Hog, C. Godeffroy, S. Araya, I. Kallai, D. Gazit, M. Boyce, and C. Ortiz. “Three-Dimensional Structure of the Shell Plate Assembly of the Chiton Tonicella Marmorea and Its Biomechanical Consequences.” Journal of Structural Biology 177, no. 2 (January 10, 2012): 314–328. doi:10.1016/j.jsb.2011.12.019.
- (Thorne. J. M, 1968; Moroz. L, et al, 1993).
- Chelazzi, et al, 1983, 'A comparative study on the movement pattern of two sympatric tropical chitons, Mollusca: Polyplacophora', Marine Biology, vol 74, pp 115-125.; Chelazzi. G, et al, 1990, 'The role of trail folliwing in the homing of intertidal chitons: a comparison between three Acanthopleura spp', Marine Biology, vol 105, pp 445-450.
- (Chelazzi. G, et al, 1987; Thorne. J M, 1968).
- (Chelazzi. G, et al, 1985).
- For a summary, see
- search term Dinoplax accessed 7 April 2010
Class Polyplacophora de Blainville, 1816
Subclass Paleoloricata Bergenhayn, 1955
- Order Chelodida Bergenhayn, 1943
Order Septemchitonida Bergenhayn, 1955
Family Gotlandochitonidae Bergenhayn, 1955
- Gotlandochiton Bergenhayn, 1955
- Family Helminthochitonidae Van Belle, 1975
- Family Septemchitonidae Bergenhayn, 1955
- Family Gotlandochitonidae Bergenhayn, 1955
Subclass Loricata Shumacher, 1817
Order Lepidopleurida Thiele, 1910
Suborder Cymatochitonina Sirenko et Starobogatov, 1977
- Family Acutichitonidae Hoare, Mapes et Atwater, 1983
- Family Cymatochitonidae Sirenko et Starobogatov, 1977
Family Gryphochitonidae Pilsbry, 1900
- Gryphochiton Gray, 1847
Family Lekiskochitonidae Smith et Hoare, 1987
- Lekiskochiton Hoare et Smith, 1984
- Family Permochitonidae Sirenko et Starobogatov, 1977
Suborder Lepidopleurina Thiele, 1910
- Family Abyssochitonidae (synonym:Ferreiraellidae) Dell’ Angelo et Palazzi, 1991
Family Glyptochitonidae Starobogatov et Sirenko, 1975
- Glyptochiton Konninck, 1883
Family Leptochitonidae Dall, 1889
- Colapterochiton Hoare et Mapes, 1985
- Coryssochiton DeBrock, Hoare et Mapes, 1984
- Proleptochiton Sirenko et Starobogatov, 1977
- Schematochiton Hoare, 2002
- Pterochiton (Carpenter MS) Dall, 1882
- Leptochiton Gray, 1847
- Parachiton Thiele, 1909
- Terenochiton Iredale, 1914
- Trachypleura Jaeckel, 1900
- Pseudoischnochiton Ashby, 1930
- Lepidopleurus Risso, 1826
- Hanleyella Sirenko, 1973
- Family Camptochitonidae Sirenko, 1997
Family Nierstraszellidae Sirenko, 1992
- Nierstraszella Sirenko, 1992
- Family Mesochitonidae Dell’ Angelo et Palazzi, 1989
- Family Protochitonidae Ashby, 1925
- Family Hanleyidae Bergenhayn, 1955
- Suborder Cymatochitonina Sirenko et Starobogatov, 1977
Order Chitonida Thiele, 1910
Suborder Chitonina Thiele, 1910
Superfamily Chitonoidea Rafinesque, 1815
Family Ochmazochitonidae Hoare et Smith, 1984
- Ochmazochiton Hoare et Smith, 1984
- Family Ischnochitonidae Dall, 1889
- Family Callistoplacidae Pilsbry, 1893
- Family Chaetopleuridae Plate, 1899
- Family Loricidae Iredale et Hull, 1923
- Family Callochitonidae Plate, 1901
Family Chitonidae Rafinesque, 1815
- Subfamily Chitoninae Rafinesque, 1815
- Subfamily Toniciinae Pilsbry, 1893
- Subfamily Acanthopleurinae Dall, 1889
- Family Ochmazochitonidae Hoare et Smith, 1984
- Superfamily Schizochitonoidea Dall, 1889
- Superfamily Chitonoidea Rafinesque, 1815
Suborder Acanthochitonina Bergenhayn, 1930
Superfamily Mopalioidea Dall, 1889
Family Tonicellidae Simroth, 1894
- Subfamily Tonicellinae Simroth, 1894
- Subfamily Juvenichitoninae Sirenko, 1975
- Family Schizoplacidae Bergenhayn, 1955
Family Mopaliidae Dall, 1889
- Subfamily Heterochitoninae Van Belle, 1978
Subfamily Mopaliinae Dall, 1889
- Aerilamma Hull, 1924
- Guildingia Pilsbry, 1893
- Frembleya H. Adams, 1866
- Diaphoroplax Iredale, 1914
- Plaxiphora Gray, 1847
- Placiphorina Kaas & Van Belle, 1994
- Nuttallochiton Plate, 1899
- Mopalia Gray, 1847
- Maorichiton Iredale, 1914
- Placiphorella (Carpenter MS) Dall, 1879
- Katharina Gray, 1847
- Amicula Gray, 1847
- Family Tonicellidae Simroth, 1894
Superfamily Cryptoplacoidea H. & A. Adams, 1858
Family Acanthochitonidae Pilsbry, 1893
- Subfamily Acanthochitoninae Pilsbry, 1893
Subfamily Cryptochitoninae Pilsbry, 1893
- Cryptochiton Middendorff, 1847
- Family Hemiarthridae Sirenko, 1997
- Family Choriplacidae Ashby, 1928
- Family Cryptoplacidae H. & A. Adams, 1858
- Family Acanthochitonidae Pilsbry, 1893
- Superfamily Mopalioidea Dall, 1889
- Suborder Chitonina Thiele, 1910
- Order Lepidopleurida Thiele, 1910
Family Scanochitonidae Bergenhayn, 1955
- Scanochiton Bergenhayn, 1955
Family Olingechitonidae Starobogatov et Sirenko, 1977
- Olingechiton Bergenhayn, 1943
Family Haeggochitonidae Sirenko et Starobogatov, 1977
- Haeggochiton Bergenhayn, 1955
Family Ivoechitonidae Sirenko et Starobogatov, 1977
- Ivoechiton Bergenhayn, 1955
- Family Scanochitonidae Bergenhayn, 1955
- Subclass Paleoloricata Bergenhayn, 1955
This system is now generally accepted.
The most recent classification (Sirenko 2006) is based not only on shell morphology, as usual, but also other important features, including aesthetes, girdle, radula, gills, glands, egg hull projections, and spermatozoids. It includes all the living and extinct genera of chitons.
Since chitons were first described by Linnaeus (1758), extensive taxonomic studies at the species level have been made. However, the taxonomic classification at higher levels in the group has remained somewhat unsettled.
Most classification schemes in use today are based, at least in part, on Pilsbry's Manual of Conchology (1892–1894), extended and revised by Kaas and Van Belle (1985–1990).
The Greek-derived name Polyplacophora comes from the words poly- (many), plako- (tablet), and -phoros (bearing), a reference to the chiton's eight shell plates.
The English name "chiton" originates from the Latin word chitōn, which means "mollusc", and in turn is derived from the Greek word khitōn, meaning tunic (which also is the source of the word chitin). The Greek word khitōn can be traced to the Central Semitic word *kittan, which is from the Akkadian words kitû or kita’um, meaning flax or linen, and originally the Sumerian word gada or gida.
Chitons were first studied by Carolus Linnaeus in 1758. Since his description of the first four species, chitons have been variously classified. They were called Cyclobranchians ("round arm") in the early 19th century, and then grouped with the aplacophorans in the subphylum Amphineura in 1876. The class (biology) Polyplacophora was named by de Blainville 1816.
History of scientific investigation
The chitons evolved from multiplacophora during the Palaeozoic, with their relatively conserved modern-day body plan being fixed by the Mesozoic.
Kimberella and Wiwaxia of the Precambrian and Cambrian may be related to ancestral polyplacophora. Matthevia is a Late Cambrian polyplacophoran preserved as individual pointed valves, and sometimes considered to be a chiton, although it can at best be a stem-group member of the group. Based on this and co-occurring fossils, one plausible hypothesis for the origin of polyplacophora has that they formed when an aberrant monoplacophoran was born with multiple centres of calcification, rather than the usual one. Selection quickly acted on the resultant conical shells to form them to overlap into protective armour; their original cones are homologous to the tips of the plates of modern chitons.
Chitons have a relatively good fossil record, stretching back  to the Devonian. Before this, some organisms have been interpreted (tentatively) as stem-group polyplacophora; the record of polyplacophora stretches back to the Ordovician.
The largest species
The egg has a tough spiny coat, and usually hatches to release a free-swimming trochophore larva, typical of many other mollusc groups. In a few cases, the trochophore remains within the egg (and is then called lecithotrophic – deriving nutrition from yolk), which hatches to produce a miniature adult. Unlike most other molluscs, there is no intermediate stage, or veliger, between the trochophore and the adult. Instead, a segmented shell gland forms on one side of the larva, and a foot forms on the opposite side. When the larva is ready to become an adult, the body elongates, and the shell gland secretes the plates of the shell. Unlike the fully grown adult, the larva has a pair of simple eyes, although these may remain for some time in the immature adult.
Chitons have separate sexes, and fertilization is external. The male releases sperm into the water, while the female releases eggs either individually, or in a long string. In most cases, fertilization takes place either in the surrounding water, or in the mantle cavity of the female. Some species brood the eggs within the mantle cavity, and the species Callistochiton viviparus even retains them within the ovary and gives birth to live young, an example of ovoviviparity.
Reproduction and lifecycle
A few species of chitons are predatory, such as the small western Pacific species Placiphorella velata. These predatory chitons have enlarged anterior girdles. They catch other small invertebrates, such as shrimp and possibly even small fish, by holding the enlarged, hood-like front end of the girdle up off the surface, and then clamping down on unsuspecting, shelter-seeking prey.
Chitons or Canchalagua are also eaten in Galapagos in Chiviche and BBQ.
Chitons are eaten in many islands in the Caribbean, including Trinidad, Tobago, The Bahamas, St. Maarten, Bonaire, Anguilla and Barbados, as well as in Bermuda. They are also eaten in certain parts of the Philippines and by native Americans of the Pacific coasts of both North and South America. The foot of the chiton is prepared in a manner similar to abalone.
Similar to many species of saltwater snail back to its home site. It is unclear if chiton homing functions in the same way, but they may leave chemical cues along the rock surface and at the home scar which their olfactory senses can detect and home in on. Furthermore, older trails may also be detected, providing further stimulus for the chiton to find its home, Chitons have radular teeth made of magnetite (an iron compound) making them unique among animals. This means they have an exceptionally abrasive tongue with which to scrape algae from rocks. The iron crystals may also be involved in magnetoception, the ability to sense the polarity or the inclination of the Earth's magnetic field, and thus may be used in navigation.
However, chitons lack a cerebral ganglion.
A relatively good fossil record of chiton shells exists, but ocelli are only present in those dating to or younger; this would make the ocelli, whose precise function is unclear, the most recent eyes to evolve.
The primary sense organs of chitons are the subradula organ and a large number of unique organs called aesthetes. The aesthetes consist of light-sensitive cells just below the surface of the shell, although they are not capable of true vision. In some cases, however, they are modified to form ocelli, with a cluster of individual photoreceptor cells lying beneath a small lens, in some cases made up of aragonite. An individual chiton may have thousands of such ocelli. These 'rock-based-eyes' make them capable of true vision; though research continues as to the extent of their visual acuity. It is known that they can differentiate between a predator's shadow and changes in light caused by clouds.
Some species bear an array of tentacles in front of the head.
 No true  Chitons lack a clearly demarcated head; their nervous system resembles a dispersed ladder.
Cilia pull the food through the mouth in a stream of mucus and through the oesophagus, where it is partially digested by enzymes from a pair of large pharyngeal glands. The oesophagus, in turn, opens into a stomach, where enzymes from a digestive gland complete the breakdown of the food. Nutrients are absorbed through the linings of the stomach and the first part of the intestine. The intestine is divided in two by a sphincter, with the latter part being highly coiled and functioning to compact the waste matter into faecal pellets. The anus opens just behind the foot.