Trematodes are parasitic flatworms of the class Trematoda, specifically parasitic flukes with two suckers: one ventral and the other oral. Trematodes are covered by a tegument, that protects the organism from the environment by providing secretory and absorptive functions.
The life cycle of a typical trematode begins with an egg. Some trematode eggs hatch directly in the environment (water), while others are eaten and hatched within a host, typically a mollusc. The hatchling is called a miracidium, a free-swimming, ciliated larva. Miracidia will then grow and develop within the intermediate host into a sac-like structure known as a sporocyst or into rediae, either of which may give rise to free-swimming, motile cercariae larvae. The cercariae then could either infect a vertebrate host or a second intermediate host. Adult metacercariae or mesocercariae, depending on the individual trematode's life cycle, will then infect the vertebrate host or be rejected and excreted through the rejected host's faeces or urine.[1]
The egg is found in the faeces, sputum, or urine of the definitive host. Depending on the species, it will either be non-embryonated (immature) or embryonated (ready to hatch). The eggs of all trematodes (except schistosomes) are operculated. Some eggs are eaten by the intermediate host (snail) or they are hatched in their habitat (water).
Miracidia hatch from eggs either in the environment or in the intermediate host. They do not have a mouth; therefore they cannot eat and need to find a host quickly if they hatch in the environment. Energy is needed to develop into a sporocyst. The first intermediate host can differ for different trematodes.[3]
After the sporocyst the larva forms. The first development from it forms the redia.[5] They have a mouth which allows them to have an advantage to their competitors because they can just consume them and will either produce more rediae or start to form cercariae.
Co-infections of different parasite species within the same host could occur and cause competition between the rediae and sporocysts. Not all trematode species have a redia stage; some may just have a sporocyst stage depending on the life cycle. The rediae are dominant over sporocysts because they have mouths and are able to either eat their competitors' food or their competitors.[citation needed]
The larval form of the parasite develops within the germinal cells of the sporocyst or redia.[6] A cercaria has a tapering head with large penetration glands.[7] It may or may not have a long swimming "tail", depending on the species.[6] The motile cercaria finds and settles in a host where it will become either an adult, a mesocercaria, or a metacercaria, according to species.
Mesocercaria: They are involved in an encysted stage either on vegetation or in a host tissue on the second intermediate host. They have a hard shell and are also involved in the trophic transmission. This is where the parasite is able to infect the definitive host because it consumes the second intermediate host that has metacercariae on/in it.[citation needed]
Metacercaria: A cercaria encysted and resting. They are only involved when there are 3 intermediate host life cycles.
Cercaria is also used as a genus of trematodes, when adult forms are not known.[8] The usage dates back to Müller, in 1773.[9]
Not all trematodes follow the typical sequence of eggs, miracidia, sporocysts, rediae, cercariae, and adults. In some species, the redial stage is omitted, and sporocysts produce cercariae. In other species, the cercaria develops into an adult within the same host.
Many digenean trematodes require two hosts; one (typically a snail) where asexual reproduction occurs in sporocysts, the other a vertebrate (typically a fish) where the adult form engages in sexual reproduction to produce eggs. In some species (for example Ribeiroia) the cercaria encysts, waits until their host is eaten by a third host, in whose gut it emerges and develops into an adult.
^Galaktionov, K. V., & Dobrovolʹskiĭ, A. A. (2003). The biology and evolution of trematodes: An essay on the biology, morphology, life cycles, transmission, and evolution of digenetic trematodes. Dordrecht: Kluwer Academic.[page needed]
^Fried, Bernard, and Thaddeus K. Graczyk. Echinostomes as Experimental Models for Biological Research. Springer, 2011.[page needed]
^Fried, Bernard, and Thaddeus K. Graczyk. Echinostomes as Experimental Models for Biological Research. Springer, 2011.[page needed]
^ ab"Glossary". VPTH 603 Veterinary Parasitology. University of Pennsylvania School of Veterinary Medicine. Archived from the original on 18 July 2011. Retrieved 21 February 2011.
^ ab"Schistosoma". Australian Society for Parasitology. Retrieved 19 February 2011.