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Observations on the development of Toxocara canis (Werner, 1782) in the dog*

Published online by Cambridge University Press:  06 April 2009

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

1. Evidence from previous literature shows that puppies are commonly infected with larvae of Toxocara canis at birth and that prenatal infection can be produced by feeding embryonated eggs to pregnant bitches.

2. Observations on fifty-eight dogs in Brisbane showed that all of twenty-nine puppies 1–6 months old were infected, while only three out of twenty-nine dogs over 6 months old were infected.

3. In naturally infected puppies, 1–3 weeks old, it was found that at birth third-stage larvae were present in the lungs. Third-stage larvae continued to appear in the lungs for the first week of life; their length was 0·6–1·3 mm.

4. Third-stage larvae were found in the stomach on the day after birth; at 3 days after birth fourth-stage larvae were found in the intestine.

5. It appeared likely that the second moult occurs in puppies before birth, and that the third moult takes place at a length of 1·0–1·3 mm. in the lungs and stomach within the first week of life.

6. By the beginning of the second week, fourth-stage larvae were fully grown and had commenced the fourth moult at a length of 5–7 mm.

7. Throughout the second and third weeks, adults grew rapidly, reaching a length of about 67 mm. by the end of the third week, but no eggs had appeared in the faeces at this time.

8. Experimental infection of mice with eggs showed that the larvae were distributed to the somatic tissues, few reaching the alimentary tract. The larvae did not progress beyond the second stage in the tissues of mice.

9. Experimental infection of dogs with eggs showed that in dogs over 5 weeks old the larvae were distributed to the somatic tissues and did not reach the alimentary tract. The larvae did not progress beyond the second stage, though some of them showed signs of commencing the second moult. In contrast, 1 to 3-week-old puppies infected in the same way were found to harbour larvae in the alimentary tract. Though some of these larvae were probably derived from a naturally acquired prenatal infection, it was evident from the progress of development that the experimental infection resulted in the presence of second-stage larvae in the liver and lungs and that these larvae underwent the second moult, commenced development as third-stage larvae in the lungs, migrated into the stomach and developed to the adult stage in the intestine.

10. Experimental infection of dogs and foxes with mice harbouring second-stage larvae in the tissues showed that, in some instances, development of larvae proceeded in the alimentary tract. No evidence of somatic migration was found in dogs infected in this way, but in foxes second-stage larvae were found in the lungs.

11. The structure and development of the second, third and fourth stage is described in detail and found to resemble closely the development of T. cati larvae (Sprent, 1956). Second-stage larvae from dog tissues had a length of 0·34–0·44 mm. and the second moult occurred at a length of 0·37–0·44 mm. Third-stage larvae varied in length from 0·46 to 1·36 mm., and the third moult occurred at a length of 0·98–1·3 mm. Fourth-stage larvae measured 1·2–6·3 mm., though moulting fourth-stage larvae were observed up to a length of 7·4 mm. Sexual differentiation occurred during the fourth stage and was evident at a length of about 1·5 mm.

12. The migratory behaviour of the larvae of T. canis and T. cati is compared and discussed in relation to their wide range of hosts. It is concluded that differences in migratory behaviour are adaptations to prevailing modes of nutrition and it is suggested that the somatic migration occurring in dogs is an adaptation to the non-predatory habits of this particular host.

Type
Research Article
Information
Parasitology , Volume 48 , Issue 1-2 , May 1958 , pp. 184 - 209
Copyright
Copyright © Cambridge University Press 1958

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References

Augustine, D. L. (1927). Development in prenatal infestation of Belascaris. J. Parasit. 13, 256–9.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, J. W. (1952). Chronic eosinophilia due to visceral larva migrans. Pediatrics, Springfield, 9, 719.CrossRefGoogle ScholarPubMed
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.Google Scholar
Cowan, I. M. (1947). The timber wolf in the Rocky mountain national parks of Canada. Canad. J. Res. D, 25 139–74.CrossRefGoogle Scholar
Davaine, C. J. (1863). Sur la constitution de l'œuf de certains entozoaires et sur la propriété de se développer à sec. C.R. Soc. Biol., Paris, 4, 273–8.Google Scholar
Fülleborn, F. (1921). Askarisinfektion durch Verzehren eingekapselter Larven und über gelungene intrauterine Askarisinfektion. (Vorläufige Mitteilung.) Arch. Schiffs.- u. TropenHyg. 25, 367–75.Google Scholar
Hadley, F. B., Warwick, B. L. & Gildow, E. M. (1924). Prenatal infestation of fox pups with belascardis. J. Amer. Vet. Med. Ass. 19, 301–7.Google Scholar
Hering, E. A. von (1873). Beiträge zur Entwicklungsgeschichte einiger Eingeweide-würmer. Jh. Ver. vaterl. Naturk. Württemb. 29, 305–67.Google Scholar
Hitchcock, D. J. (1953). Incidence of gastro-intestinal parasites in some Michigan kittens. N. Amer. Vet. 34, 428–9.Google Scholar
Hoepli, R., Feng, L. C. & Li, F. (1949). Histological reactions in the liver of mice due to larvae of different Ascaris species. Peking Nat. Hist. Bull. 18, 119–32.Google Scholar
Kreis, H. A. (1952). Helminthologische Untersuchungen in schweizerischen Tierpärken und bei Haustieren. Schweiz. Archiv Tierheilk. 94, 499583.Google Scholar
Leiper, R. T. (1907). Two new genera of nematodes occasionally parasitic in man. Brit. Med. J, 1, 1296–8.Google Scholar
Matoff, K. (1949). [Experimental Investigations on the Migration of Toxocara canis, Toxocaris leonina and Neoascaris vitulorum], Year book of the Rural Academy, Sofia. (In Russian.) xxv, 593659.Google Scholar
Mozgovi, A. A. (1953). [Ascaridata of Animals and Man and Diseases Caused by Them.] 2 vols. (In Russian.) U.S.S.R.: Leningrad, Academy of Sciences.Google Scholar
Nelson, H. (1852). On the reproduction of the Ascaris mystax. Phil Trans. pp. 563–94.Google Scholar
Nichols, R. L. (1956). The etiology of visceral larva migrans. I. Diagnostic morphology of infective second-stage Toxocara larvae. J. Parasit. 42, 349–62.Google Scholar
Nifontov, S. N. (1949). Importance of intra-uterine invasion in the epizoology of Toxocara infection in dogs. Veterinariia, Moscow, 26, 32–4.Google Scholar
Petrov, A. M. (1930) The work of the 61st Union Helminthological Expedition on Sakhalin Island. [Russian text—original not seen.] Trudy Gosudarstv. Inst. Eksper. Vet. 6, 110–26.Google Scholar
Petrov, A. M. (1941). (Importance de l'invasion intrauterine dans l'epizootologie de la toxocarose des renards noirs-argentés.) [Russian text: French Summary.] Vestn. selkhoz. Nauk. Vet. 3, 8492.Google Scholar
Railliet, A. & Henry, A. C. (1911). Recherches sur les ascarides des carnivores. C.R. Soc. Biol. Paris, 70, 1215.Google Scholar
Schmid, F. (1934). Über Parasiten und parasitäre Veränderungen der Harnorgane bei Silberfüchsen. Berl. tierärtzl. Wschr. 50, 33–6.Google Scholar
Shillinger, J. E. & Cram, E. B. (1923). Parasitic infestation of dogs before birth. J. Amer. Vet. Med. Ass. 63, 200–3.Google Scholar
Shoho, C. (1955). Helminthic diseases of the central nervous system and intrauterine foetal infection by helminths. (Significance of histologic diagnosis in somatic Helminthiasis.) Rev. iber. Parasit. (Tomo Extraordinario), pp. 927–51.Google Scholar
Smith, L. F. (1943). Internal parasites of the red fox in Iowa. J. Wildlife Mgmt, 7, 174–8.Google Scholar
Sprent, J. F. A. (1952). On the migratory behaviour of the larvae of various Ascaris species in white mice. I. Distribution of larvae in tissues. J. Infect. Dis. 90, 165–76.Google Scholar
Sprent, J. F. A. (1953). On the migratory behaviour of the larvae of various Ascaris species in white mice. II. Longevity of encapsulated larvae and their resistance to freezing and putrefaction. J. Infect. Dis. 92, 114–17.Google Scholar
Sprent, J. F. A. (1955). On the invasion of the central nervous system by Nematodes. II. Invasion of the nervous system in Ascariasis. Parasitology, 45, 4155.Google Scholar
Sprent, J. F. A. (1956). The life history and development of Toxocara cati (Schrank 1788), in the domestic cat. Parasitology, 46, 5478.CrossRefGoogle ScholarPubMed
Tiner, J. D. (1953). The migration, distribution in the brain, and growth of ascarid larvae in rodents. J. Infect. Dis. 92, 105–13.CrossRefGoogle ScholarPubMed
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. 4 901–19.Google Scholar
Yamaguti, S. (1941). Studies on the helminth fauna of Japan. Part 35. Mammalial nematodes, II. Jap. J. Zool. 9, 409–39.Google Scholar
Yutuc, L. M. (1949). Prenatal infection of dogs with ascarids, Toxocara canis and hookworms, Ancylostoma caninum. J. Parasit. 35, 358–60.CrossRefGoogle Scholar