Hostname: page-component-586b7cd67f-gb8f7 Total loading time: 0 Render date: 2024-11-20T09:35:19.733Z Has data issue: false hasContentIssue false

The life history and development of Toxocara cati (Schrank 1788) in the domestic cat

Published online by Cambridge University Press:  06 April 2009

J. F. A. Sprent
Affiliation:
University of Queensland Veterinary School, Brisbane, Queensland

Extract

1. An account is given of the history, synonymy and host-range of Toxocara cati.

2. Eggs of T. cati were fed to various animals, and the second-stage larvae were found in the tissues of earthworms, cockroaches, chickens, mice, dogs, lambs and cats.

3. Cats were successfully infected by feeding eggs of T. cati and by feeding mice harbouring larvae in the tissues.

4. In egg-infected cats the larvae were found in the liver, lungs, muscles and tracheal washings as well as in the digestive tract, indicating that they migrate through the tissues.

5. In mice the larvae were found in the liver, lungs and muscles, but did not reach the alimentary tract. Changes occurred in the mouth region of the larvae in mouse tissues between 8 and 11 days after infection, but no actual moult was observed. No significant growth of the larvae was observed in mouse tissues.

6. In mouse-infected cats the larvae were mostly confined to the wall and contents of the digestive tract.

7. It appeared that the second moult occurred in the stomach wall of egg-infected cats at 3–10 days after infection; moulting larvae measuring 0·353–0·423 mm. in length; in a mouse-infected cat moulting larvae (length 0·459–0·765 mm.) were observed at 6 days after infection.

8. In both egg- and mouse-infected cats the third-stage larvae grew in the stomach wall and moulted for the third time at a length of 0·9–1·2 mm. This occurred at about 10 days in mouse-infected cats and at about 19 days in egg-infected cats.

9. The smallest fourth-stage larvae were found in the stomach contents whence they passed into the intestine. Probably they are at first attached to the wall and later become free in the intestinal contents.

10. The fourth-stage larvae have lips resembling the adult; sexual differentiation occurs during this stage, being first evident at 1·5 mm.

11. The fourth moult occurs in the intestine at a length of approximately 4·5–5·5 mm.

12. In the adult stage the lateral alae gradually disappear and the cervical alae reach the adult form at a length of approximately 45 mm. The smallest female observed containing eggs in the vagina measured 55 mm. in length. Eggs were first observed in the faeces at 56 days after infection by eggs.

13. The evidence from experimental and natural infection indicated that infection of cats with T. cati always takes place after birth.

14. No larvae were found in the alimentary tract of dogs following experimental infection either with eggs or with infected mice.

15. The relationship of the life history of T. cati to that of other ascaridid species, to the feeding habits of the definitive hosts, and in relation to the occurrence of human infection with this parasite is discussed.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1956

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

Baylis, H. A. (1939). Further records of parasitic worms from British vertebrates. Ann. Mag. Nat. Hist. (s. 11), 4, 473–98.CrossRefGoogle Scholar
Baylis, H. A. & Daubney, R. (1922). Report on the parasitic nematodes in the collection of the Zoological Survey of India. Mem. Indian Mus. 7, 263347.Google Scholar
Beaver, P. C., Snyder, C. H., Carrera, G. M., Dent, J. H. & Lafferty, W. (1952). Chronic Eosinophilia due to visceral larva migrans. Pediatrics, 9, 719.CrossRefGoogle ScholarPubMed
Bremser, J. G. (1824). Icones helminthum systema Rudolphi entozoologicum illustrantes, 12 pp., 18 pls. Viennae.Google Scholar
Cameron, T. W. M. (1928). On some parasites of the rusty tiger cat (Felis planiceps). J. Helminth. 6, 8798.CrossRefGoogle Scholar
Canavan, W. P. N. (1929). Nematode parasites of vertebrates in the Philadelphia Zoological Garden and vicinity. I. Parasitology, 21, 63102.CrossRefGoogle Scholar
Canavan, W. P. N. (1931). Nematode parasites of vertebrates in the Philadelphia Zoological Garden and vicinity. II. Parasitology, 23, 196229.CrossRefGoogle Scholar
Cobbold, T. S. (1864). Entozoa: An Introduction to the Study of Helminthology, with Reference, more particularly to the Internal Parasites of Man. xxvi + 480 pp., 82 figs., 21 pls. London.Google Scholar
Diesing, K. M. (1851). Systema Helminthum, vol. 2. vi + 588 pp. Vindobonae.Google Scholar
Diesing, K. M. (1857). Sechzehn Arten von Nematoideen. Denkschr. Akad. Wiss. Wien (1. Abt.), 13, 626.Google Scholar
Von Drasche, R. (1883). Revision der in der Nematoden-Sammlung des k.k. zoologischen Hofcabinetes befindlichen Original-Exemplare Diesing's und Molin's. Verh. zool.-bot. Ges. Wien, 1882, 23, 117–38.Google Scholar
Glaue, H. (1909). 1. Zur Unterscheidung von Ascaris canis und A. felis (Ascaris canis s. mystax). Ein Beitrag zur Systematik der Nematoden. Zool. Anz. 33, 785–90.Google Scholar
Gmelin, J. F. (1790). Caroli à Linné. …Systema naturae, vol. 1. Editio decima tertia. Jo. Fred. Gmelin, pt. 6 (Vermes), pp. 3021–910.Google Scholar
Goeze, J. A. E. (1782). Versuch einer Naturgeschichte der Eingeweidewürmer thierischer Körper. xi + 471 pp., 44 (35) pls. Blankenburg.Google Scholar
Gough, L. H. (1909). Notes on South African parasites. Rep. S. Afr. Ass. Adv. Sci. (6th Meeting, Grahamstown, 1908), pp. 167–70.Google Scholar
Hall, M. C. (1912). Notes on the parasite fauna of Colorado. Abst. of a report before 7th Meeting Helminth. Soc. Wash., 19 12. 1911. Science, N.S., 35, 554–5.Google Scholar
Henry, A. C. L. & Joyeux, C. E. (1920). Contribution à la faune helminthologique de la Haute-Guinée française. Bull. Soc. Pat. exot. 13, 176–82.Google Scholar
Von Hering, E. A. (1873). Beiträge zur Entwicklungsgeschichte einiger Eingeweidewürmer. Jaresh. Ver. Vaterl. Naturk. Würtemberg. 29 (2–3): 305367.Google Scholar
Kreis, H. A. (1938). Beiträge zur Kenntnis parasitischer Nematoden. VI. Parasitische Nematoden aus deni Zoologischen Garten in Basel. Zbl. Bakt. (1. Abt. Orig.), 141, 279304.Google Scholar
Leiper, R. T. (1907). Two new genera of nematodes occasionally parasitic in man. Brit. Med. J. (2422), vol. 1, 1 06, 1296–98.CrossRefGoogle ScholarPubMed
Leuckart, K. G. F. R. (1876). Die menschlichen Parasiten und die von ihnen herrührenden Krankheiten. vol. 2, 3. Lief., pp. 513882, 119 figs. Leipzig.Google Scholar
Von Linstow, O. F. B. (1899). Nematoden aus der berliner zoologischen Sammlung. Mitt. Zool. Samml. Mus. Naturk. Berl. 1, 328.Google Scholar
Von Linstow, O. F. B. (1902). Beobachtungen an neuen und bekannten Nemathelminthen. Arch. mikr. Anat. 60, 217–32.CrossRefGoogle Scholar
Mendheim, H., Scheid, G. & Schmidt, J. (1951). Die selteneren Spulwurminfektionen beim Menschen. Z. Tropenmed. Parasit. 3, 358–68.Google Scholar
Moniez, R. L. (1896). Traité de parasitologie animale et végétale appliqué à la médecine. viii + 680 pp., 116 figs. Paris.CrossRefGoogle Scholar
Nelson, H. (1852). On the reproduction of the Ascaris mystax. Phil. Trans. pp. 563–94.Google Scholar
Neumann, L. G. (1892). A Treatise on the Parasites and parasitic Diseases of the Domesticated Animals. Translated and edited by George, Fleming. 800 pp., 364 figs. London.Google Scholar
Railliet, A. & Henry, A. C. L. (1911). Recherches sur les ascarides des carnivores. C.R. Soc. Biol., Paris, 70, 1215.Google Scholar
Roberts, F. H. S. (1934). The large roundworm of pigs, Ascaris lumbricoides L., 1758, its life history in Queensland, economic importance and control. Bull. (1) Animal Health Station, Yeerongpilly, Sept., 81 pp.Google Scholar
Rudolphi, C. A. (1793). Observations circa Vermes Intestinales. Grypiswaldiae. 46 pp.Google Scholar
Rudolphi, C. A. (1802). Fortsetzung der Beobachtnngen über die Eingeweiderwürmer. Arch. Zool. Zoot. 2, 167.Google Scholar
Sarles, M. P. & Stoll, N. R. (1935). On the resistance of the cat to superimposed infection with the ascarid, Toxocara cati. J. Parasit. 21, 277–91.CrossRefGoogle Scholar
Schrank, F. Von P. (1788). Verzeichnisse der bisher hinlänglich bekannten Engeweideriwürmer nebst einer Abhandlung über ihre Anverwandtschaften. 116 pp. München.Google Scholar
Smith, A. J. (1908). Synopsis of studies in metazoan parasitology in McManus laboratory of pathology, University of Pennsylvania. Univ. Pa. Med. Bull. 20, 262–82.Google Scholar
Smith, A. J., Fox, H. & White, C. Y. (1908). Contributions to systematic helminthology. Univ. Pa. Med. Bull. 20, 283–94.Google Scholar
Smith, M. H. D. & Beaver, Paul C. (1953). Persistence and distribution of Toxocara larvae in the tissues of children and mice. Pediatrics, Springfield, 12, 491–7.CrossRefGoogle ScholarPubMed
Sprent, J. F. A. (1952 a). On the migratory behaviour of the larvae of various ascaris species in white mice. J. Infect. Dis. 90, 165–76.CrossRefGoogle ScholarPubMed
Sprent, J. F. A. (1952 b). On an ascaris parasite of the Fisher and Marten, Ascaris devosi sp.nov. Proc. Helminth. Soc. Wash. 19, 2737.Google Scholar
Sprent, J. F. A. (1953). On the life history of Ascaris devosi and its development in the white mouse and the domestic ferret. Parasitology, 42, 244–58.CrossRefGoogle ScholarPubMed
Stewart, F. H. (1918). On the development of Ascaris lumbricoides and Ascaris mystax in the mouse. Part II. Parasitology, 10, 189–96.CrossRefGoogle Scholar
Stiles, C. W. & Brown, G. (1924). Nomenclature of the nematode genera Belascaris 1907, Toxascaris 1907, and Toxocara 1905. J. Parasit. 11, 92–3.Google Scholar
Stiles, C. W. & Hassall, A. (1905). The determination of generic types, and a list of round-worm genera, with their original and type species. Bull. no. 79, Bureau Animal Indust., U.S. Dep. Agric. 1150.Google Scholar
Stossich, M. (1896). Il genere Ascaris Linné. Lavoro monografico. Boll. Soc. adriat. Sci. nat. 17, 9120.Google Scholar
Taylor, E. L. (1924). On the ascarids of the dog and cat. Ann. Trop. Med. Parasit. 18, 243–51.CrossRefGoogle Scholar
Thwaite, J. W. (1927). On a collection of nematodes from Ceylon. Ann. Trop. Med. Parasit. 21, 225–44.CrossRefGoogle Scholar
Vevers, G. M. (1923). On the parasitic nematoda collected from mammalian hosts which died in the gardens of the Zoological Society of London during the years 1919–1921; with a description of three new genera and three new species. Proc. Zool. Soc. Lond. (1922), pt. 4, 02., pp. 901–19.Google Scholar
Walton, A. C. (1928). A revision of the nematodes of the Leidy collections. Proc. Acad. Nat. Sci. Philad. (1927), 79, 49163.Google Scholar
Werner, P. C. F. (1782). Vermium intestinalium brevis expositionis continuatio, 28 pp., pls. 8–9. Lipsiae. (Not seen.)Google Scholar
Wright, W. H. (1935). Observations on the life history of Toxascaris leonina (Nematoda: Ascaridae). Proc. Helminth. Soc. Wash. 2, 56.Google Scholar
Yamaguti, Satyû (1935). Studies on the helminth fauna of Japan. Part 13. Mammalian nematodes. Japan. J. Zool. 6, 433–57.Google Scholar
Yorke, W. & Maplestone, P. A. (1926). The Nematode parasites of Vertebrates. vii + 536. J. & A. Churchill, London.Google Scholar
Zeder, J. G. H. (1800). Erster Nachtrag zur Naturgeschichte der Eingeweiderwürmer, mit Zufässen und Anmerkungen herausgegeben. 320 pp., 6 pls. Leipzig.Google Scholar