Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-24T12:45:12.612Z Has data issue: false hasContentIssue false
  • English
  • Français

The life cycle of Paramphistomum microbothrium Fischoeder, 1901 (Trematoda, Paramphistomidae)

Published online by Cambridge University Press:  06 April 2009

J. A. Dinnik  and
N. N. Dinnik
J. A. Dinnik
Affiliation:
East African Veterinary Research Organization, Muguga, Kenya
N. N. Dinnik
Affiliation:
East African Veterinary Research Organization, Muguga, Kenya
Get access Rights & Permissions [Opens in a new window]

Extract

The whole life cycle of Paramphistomum microbothrium Fischoeder, 1901, found in cattle of Kenya, East Africa, has been established experimentally.

In laboratory conditions, the eggs hatched miracidia on the 14th to 16th day, if they were kept in water at a temperature of 26–28° C.

In a snail, Bulinus alluaudi (Dautzenberg), kept at the temperature of 18–20° C., the miracidium developed into a sporocyst, the elongated body of which, containing young rediae, reached a length of 3·6 mm. in about 2 weeks.

The first rediae which emerged from a sporocyst were observed on the 14th day, and on the 20th day the first generation rediae began to produce second-generation rediae. From the 28th day onward the first-generation parent rediae ceased to produce daughter rediae and began to develop cercariae only. This period of production of cercariae by the redia lasted about 30 days, and when the life of the first-generation rediae drew to its close, the old rediae developed a few daughter rediae again.

Cercariae began to emerge from the first-generation rediae 30 days after exposure of the snail to miracidia. The cercariae left the parent redia in a very immature state and further development occurred in the liver of the snail. The emergence of cercariae from the infected snail began on the 43rd day after exposure to miracidia. Shortly after emerging from the snail, the cercariae attached themselves to vegetation and encysted.

Development of rediae of the second, third, fourth and apparently more successive generations followed an identical course to that outlined for the rediae of the first generation. As a result the successive generations of rediae maintain the infection going in an intermediate host and the infected snails were continually shedding cercariae as long as they lived. In the laboratory experiments the life span of some of the infected snails exceeded a year.

In cattle infected experimentally P. microbothrium reached maturity and began passing out the eggs about a 100 days after the encysted cercariae were fed to the animals.

Type
Research Article
Information
Parasitology , Volume 44 , Issue 3-4 , November 1954 , pp. 285 - 299
Copyright
Copyright © Cambridge University Press 1954

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Barlow, C. H. & Muench, H. (1951). Life span and monthly mortality rate of Bulinus truncatus and Planorbis boissyi, the intermediate hosts of schistosomiasis in Egypt. J. Parasit. 37, 165–73.CrossRefGoogle Scholar
Bennett, H. J. (1936). The life history of Cotylophoron cotylophorum, a trematode from ruminants. Illinois Biol. Monogr. 14, no. 4, 119 pp.Google Scholar
Brumpt, E. (1936). Contribution à l'étude de l'évolution des paramphistomides. Paramphistomum cervi et cercair de Planorbis exustus. Ann. Parasit. hum. comp. 14, 552–63.CrossRefGoogle Scholar
Buckley, J. J. C. (1939). On a new amphistone cercaria (Diplocotylea) from Planorbis exustus. J. Helminth. 26, 2530.CrossRefGoogle Scholar
Dinnik, J. A. (1951). An intermediate host of the common stomach fluke, Paramphistomum cervi (Schrank), in Kenya. E. Afr. Agric. J. 26, 124–5.Google Scholar
Edney, J. M. (1950). Productivity in Clinostomum marginatum (Trematoda:Clinostomatidae). Trans. Amer. Micr. Soc. 69, 186–8.CrossRefGoogle Scholar
Fischoeder, F. (1901). Die Paramphistomiden der Saugetiere. Zool. Anz. 24, 365–75.Google Scholar
Fischoeder, F. (1903). Die Paramphistomiden der Saugetiere. Zool. Jb. (Syst.), 16, 485660.Google Scholar
Krull, W. H. (1933). New snail and rabbit hosts for Fasciola hepatica Linn. J. Parasit. 20, 4952.CrossRefGoogle Scholar
Le Roux, P. L. (1930). A preliminary communication on the life cyele of Cotylophoron cotylophorum and its pathogenicity for sheep and cattle. 16th Rep. Dir. Vet. Serv. and An. Ind., U. of S. Africa, pp. 243–53.Google Scholar
Looss, A. (1896). Recherches sur la Faune parasitaire de l'Egypt, pp. 1252. Cairo.Google Scholar
Maplestone, P. A. (1923). A revision of the amphistomata of mammals. Ann. Trop. Med. Parasit, 27, 113212.CrossRefGoogle Scholar
Näsmark, K. E. (1937). A revision of the trematode family Paramphistomidae. Zool. Bidr. Uppsala, 16, 301565.Google Scholar
Price, E. W. & McIntosh, A. (1944). Paramphistomes of North American domestic ruminants. J. Parasit. 30, Suppl. p. 9.Google Scholar
Thomas, A. P. (1883). The life history of the liver fluke (Fasciola hepatica). Quart. J. Micr. Sci., N.S., 23, 99133.Google Scholar