Larval migration of Toxocara canis in piglets and transfer of larvae from infected porcine tissue to mice

Visceral larva migrans (VLM), caused by Toxocara canis larvae in humans, animals and birds, is now well documented throughout the world. Seven piglets were infected orally with 5 x 104 embryonated eggs and the migration and distribution of T. canis larvae in the tissues were evaluated. After artificial gastric juice digestion, larval yields at necropsy from different organs and muscles on days 1, 3, 7, 15 and 30 post-infection (DPI) revealed 3.05, 0.97, 0.21, 0.13, 0.05, 0.14% recovery from liver, lungs, heart, kidneys, skeletal muscles and brain tissues respectively, with a total of 2486 (4.97%) recovery from all tissues together. The highest number of larvae 1527 (3.05%) was recovered from the liver throughout the period (1-30 DPI), indicating a special affinity of larvae for the liver. Subsequently five mice were each infected orally with 5 g of infected pig liver and, after necropsy on 10 DPI, 20 +/- 3.62, 17 +/- 5.10, 3 +/- 1.26, 12 +/- 3.92 and 30 +/- 5.69 larvae were recovered from liver, lungs, heart, brain and muscles, respectively. Thus, primarily, the migratory potential and adaptation of T. canis larvae in porcine tissue was examined and, subsequently, their establishment in the second paratenic host, the mouse, has been successful. No influence of host sex on the migratory potential of T. canis larvae was observed. The related pathology caused by migratory larvae and its zoonotic significance through the consumption of raw or undercooked pork has been emphasized.     

Larval recovery of Toxocara canis in organs and tissues of experimentally infected Rattus norvegicus

The aim of this note was to record for the first time the recovery of Toxocara canis larvae from tissues and organs of Rattus norvegicus (Berkenhout, 1769), Wistar strain, until the 60th day after experimental infection. Rats were orally infected with embryonated T. canis eggs, killed on days 3, 5, 8, 10, 15, 30, and 60 after inoculation and larvae were recovered from liver, lungs, kidneys, brain, and carcass after acid digestion, showing a pattern of migration similar of that previously observed in mice.     

Kinetics of liver trapping of infective larvae in murine toxocariasis

Mice sensitized by prior infection with Toxocara canis eggs trap many larvae of a challenge infection within the liver. In this study the distribution of challenge larvae in sensitized mice was examined to determine the earliest onset of liver trapping and to establish if the previously described phenomenon truly represented larval trapping. In all experiments, C57BL/6J mice were infected with a sensitization dose of 125 infective T. canis eggs on day 0 postinfection (PI) and challenged with 500 infective eggs on day 28 PI. In the initial experiments, larval numbers were determined within the intestinal contents, intestinal wall, mesenteric tissues, liver, lungs, skeletal muscle, and brain of each mouse on days 0.5, 1, 2, 3, 5, and 6 postchallenge (PC). Migration patterns were similar among the test and control groups except the peak of larval numbers in the liver, seen at 1 day PC in control mice, was delayed until 3 days PC in the test group. Larval trapping occurred within the liver of test mice at least by day 5 PC. In subsequent experiments, larval numbers were determined within the liver, skeletal muscle, brain of each mouse, and within the eyes of each mouse group at 4, 8, 12, and 16 wk PC. Larval numbers within the liver of test mice were similar both at 5 days PC and 16 wk PC, implying that larvae were trapped in this organ rather than delayed in their migration to other body sites. Liver trapping did not protect the eyes or brain of sensitized mice from larval migration, nor did it result in larval killing.     

Experimental infection of pups with Ancylostoma caninum larvae from an abnormal host, the chicken

The migration and distribution of Ancylostoma caninum larvae in the tissues of chickens, infected orally with 1,000 larvae, were studied. Larval yield at necropsy from different organs after digestion with artificial gastric juice revealed a 62.9% recovery four hours after inoculation, followed by a sharp decline to 5.4% at 72 hours. Larvae were found in the heart within four hours, the lungs within eight hours and the liver within 12 to 18 hours but no larvae were recovered from the spleen, kidney or brain. Migration in the muscles of head, neck, thorax and abdomen was detected at 12 hours and was maximal at 36 hours. The establishment of patent infection in the definitive host was studied by feeding infected chicks to hookworm-free pups (one chick/pup) 48 hours, 7 days and 14 days after infection. The mean worm burden at necropsy was highest (15) in the pups fed with chicks 48 hours after infection and was three and nil in the other groups respectively.     

Migration behaviour and pathogenesis of five ascarid nematode species in the Mongolian gerbil Meriones unguiculatus

To understand the characteristic features of the Mongolian gerbil, Meriones unguiculatus, as an animal model of ascarid infections, the migration behaviour and pathogenesis of larvae were investigated in experimentally infected gerbils. Embryonated eggs from each of Toxocara canis, Baylisascaris procyonis, B. transfuga, Ascaris suum, and A. lumbricoides were orally inoculated into gerbils and larvae were recovered from various organs at designated periods. In T. canis-infected gerbils, larvae were present in the liver 3 days after infection and in the skeletal muscle and brain via the heart and lungs at a similar rate. In B. procyonis- and B. transfuga-infected gerbils, larvae were present in the lungs within 24 h after infection, with some having reached the brain by that time. After 24 h, larvae of B. procyonis tended to accumulate in the brain, while those of B. transfuga accumulated in skeletal muscles. In A. suum- and A. lumbricoides-infected gerbils, larvae remained in the liver on day 5 post-infection and elicited pulmonary haemorrhagic lesions, which disappeared 7 days after initial infection. Thereafter, no larvae of any type were recovered. Ocular manifestations were frequently observed in T. canis- and B. procyonis infected gerbils, but were rare in B. transfuga-infected gerbils. In the cases of A. suum and A. lumbricoides, migration to the central nervous system and eyes was extremely rare, and larvae had disappeared by 2 weeks post-infection. Fatal neurological disturbances were observed in B. procyonis-infected gerbils, whereas irreversible non-fatal neurological symptoms were observed in the case of B. transfuga.     

Eosinophilia, granuloma formation, migratory behaviour of second stage larvae in murine Toxocara canis infection. Effect of the inoculum size

Experimental infection of mice with Toxocara canis provides one of the best models for immunological and pathological studies of the visceral larva migrans syndrome. Blood eosinophilia, the migratory behaviour of second stage larvae and granuloma formation were studied in Swiss mice infected with Toxocara canis. Eosinophilia, spleen, liver and lung indexes were followed during a primary infection with different inoculum sizes (500 and 1500 eggs) while the migratory behaviour of larvae was studied in a primary infection with 1500 eggs over a period of 4 months. In mice infected with three challenges of 1500 eggs in order to elicit a strong inflammatory reaction in the tissues, a histopathological study was carried out. The results showed that eosinophilia, spleen and lung indexes (but not the liver index) were influenced by the parasite inoculum size. The migratory behaviour study showed that larval recovery was maximal three days post-infection, from the liver and lungs; the peak recovery from the skeletal muscles and brain being on days 15 and 30 post-infection, respectively. The histopathological study revealed the formation of granulomas in all the tissues examined (liver, lungs, kidneys, spleen, lymph nodes, myocardium etc.) but not in nervous tissue or in the retina of the eye. Granulomas in the lungs were larger than those found in the liver. The implications of these results are discussed considering host-parasite inter-relations.     

Effects of irradiation on the biology of the infective larvae of Toxocara canis in the mouse

Mice were infected with either 2,000 normal or irradiated embryonated eggs of Toxocara canis and the number of larvae in their livers, lungs, brains, and carcasses investigated at 5, 20, and 33 days of infection. Mortality of mice infected with normal eggs was 33% between day 4 and 8 postinfection but there was no mortality among mice infected with irradiated eggs. Irradiation with 60, 90, or 150 kr of X-rays inhibited the migration of larvae from the livers and lungs and their accumulation in brain and carcass in proportion to the irradiation dose. By day 33 of infection, the ratio of larvae in liver and lungs to larvae in brain and carcass was 0.16 in normal mice, 0.42 in 60-kr mice, 0.98 in 90-kr mice, and 23.3 in 150-kr mice. Irradiated larvae, particularly those migrating through the peritoneal cavity, died faster than normal larvae until day 20. Irradiation favored survival after day 20. By days 20 and 33 postinfection the total parasite load was 29% and 8%, respectively, of the administered dose in control mice, 18% and 12% in 60-kr mice, 8% and 4% in 90-kr mice, and 0.9% and 0.3% in 150-kr mice. Irradiation of infective T. canis larvae, then, reduces their pathogenicity, inhibits their migration from liver and lungs, kills some of the parasites during the first 3 weeks of infection, but favors their late survival in the host.     

The occurrence of Strongyloides ratti in the tissues of mice after percutaneous infection

The migration of infective larvae of Strongyloides ratti has been examined in C57Bl/6 mice after percutaneous infection of the anterior abdominal wall. Lateral migration of larvae through the skin and subcutaneous tissues was not seen. Large numbers of larvae were recovered from the muscles between 2 and 24 hours after infection and larvae were seen in the cerebrospinal fluid 24 and 48 hours after infection. Insignificant numbers of larvae were seen in the blood, serosal cavities, liver, spleen, kidneys, brain or nasopharynx. Larvae arrived in the lungs between 24 and 72 hours after infection and worms were first noted in the small intestines at 48 hours. It is concluded that larvae migrate preferentially to the muscles and CSF before passing to the lungs, but the exact mode of travel is uncertain.     

Larval migration in oral and parenteral Toxocara pteropodis infections and a comparison with T. canis dispersal in the flying fox, Pteropus poliocephalus

When eggs of T. pteropodis were fed in large doses to juveniles of a definitive host, Pteropus poliocephalus, larvae hatched throughout the gastrointestinal tract. The majority penetrated the mucosa of the distal half of the intestine, to reach the liver via the portal circulation. A few entered the lymphatics to eventually reach the liver by passing through the lungs and migrating tracheally or continuing in the systemic circulation. Patent infections did not develop. Eggs inoculated subcutaneously also hatched and larvae again reached the liver, travelling via the circulation through the lungs and often other tissues; again, some underwent tracheal migration. Infective larvae of T. canis, identical in size with T. pteropodis, passed through the liver and lungs and dispersed mainly to skeletal muscles, but with time gradually accumulated in the brain. These findings indicate that Toxocara larval distribution is not primarily influenced by larval dimensions but reflects goal-directed behaviour.     

Susceptibility of rats to infection with Toxocara pteropodis

Infective eggs of Toxocara pteropodis were administered to Wistar rats via oral and parenteral routes. Third-stage larvae were recovered from the livers of suckling young 8 days after oral infection, and from livers and lungs after intraperitoneal or subcutaneous inoculation of eggs. These larvae were short-lived as none were found in suckling mice killed 2 weeks post-infection. Larvae were not recovered from tissues of rats aged 22 days or more when inoculated orally, indicating that refractoriness to infection develops rapidly with growth. Small numbers of larvae were recovered from the lungs of older rats 4 days after subcutaneous but not after oral inoculation. Adult male Buffalo and Fisher rats were also totally resistant to oral infection. Hence, rats differ from mice in their susceptibility to T. pteropodis.     

Kinetics of primary and secondary infections with Strongyloides ratti in mice

Dawkins H. J. S. and Grove D. I. 1981 Kinetics of primary and secondary infections with Strongyloides ratti in mice. International journal for Parasitology11: 89–96. The kinetics of infection with S. ratti were quantitated in normal and previously exposed C57B1 /6 mice. In primary infections, larvae penetrated the skin rapidly and were seen in peak numbers 12 h after infection. By 24 h after infection, larval numbers had declined appreciably and there was a slow decrease in numbers thereafter. Larvae were first observed in the lungs at 24 h and maximal recovery occurred at 48 h. It is thought that larval migration through the lungs is rapid. Worms were first seen in the intestines two days after infection. Maximum numbers were seen on the fifth day and worm expulsion was complete by day 10. Two moults took place in the small intestine during days 3 and 4 after infection. Rhabditiform larvae were first noted on the fourth day after infection. Mice exposed to S. ratti four weeks previously had significantly less larvae in the skin 4 and 12 h after infection but by 24 h there was no difference when compared with mice with primary infections. Peak recovery of larvae from the lungs occurred 24 h after infection; significantly less larvae were recovered on days 2 and 3 when compared with normal mice. There was a marked reduction in the adult worm burden in the gut; the number of worms recovered was less than one fifth of that seen in primary infections. Those worms which did mature were less fecund and were expelled from the intestines within 7 days of infection. It is suggested that in previously exposed animals, the migration of larvae from the skin is hastened, many of these larvae are destroyed in the lungs and that expulsion of worms which do mature in the intestines is accelerated.     

Investigation into the distribution of total,free, peptide-bound,protein-bound,soluble- and insoluble-collagen hydroxyproline in various bovine tissues

Collagen is a family of proteins which consists of several genetically distinct molecular species and is intimately involved in tissue organization, function, differentiation and development. The purpose of this study was to investigate the concentration of different hydroxyproline (Hyp) fractions viz., total, free, peptide-bound, protein-bound, soluble- and insoluble-collagen hydroxyproline (Hyp) in various bovine tissues. Results showed that liver had the highest concentration of free Hyp followed by kidney, brain, spleen, lungs, muscle and heart. Liver also had the highest concentration of peptide-bound collagen Hyp followed by kidney, heart, spleen, lungs, brain and muscle. The concentration of protein-bound collagen Hyp was highest in the liver, followed by kidney, spleen, lungs, muscle, brain and heart. Total Hyp was highest in the liver, followed by kidney, spleen, brain, heart, muscle and lungs. Liver also had significantly high concentration of collagen as compared to other tissues examined (P<0.001). Spleen had the significantly higher concentration of soluble-collagen Hyp when compared to other tissues (P<0.001). This was followed by heart, muscle, lungs, brain, kidney and liver. Heart had the highest concentration of insoluble-collagen Hyp followed by lungs, kidney, liver, muscle, spleen and brain. The variation among the insoluble-collagen Hyp concentration of heart and muscle, spleen and brain was significant (P<0.001). We speculate that these differences could be due to the variation in turn over of rate of collagen metabolism in this species.     

Longevity of Toxocara cati Larvae and Pathology in Tissues of Experimentally Infected Chickens

This study was conducted to determine the distribution patterns and duration of stay of Toxocara cati larvae in organs of chickens and to investigate chronic phase and potential zoonotic risk of toxocariasis in chickens. Chickens were orally infected with 1,000 embryonated T. cati eggs and necropsied 240 days post-infection. Organs of the chickens were examined at gross and microscopic levels; tissues were digested to recover larvae. Peribronchiolitis with infiltration of lymphocytes, and hyperplasia of bronchiolar associated lymphatic tissues (BALT) and goblet cells, were evident in the lungs of infected chickens. There were mild hemorrhages and infiltration of lymphocytes and a few eosinophils in the meninges. Larvae were recovered from 30% of the exposed chickens. Larvae recovery indicated that T. cati larvae stay alive for at least 240 days in the chicken brain. Therefore, chickens may potentially act as a paratenic host in nature and transfer T. cati larvae to other hosts.     

Plasma dependent and independent accumulation of betaine in male and female rat tissues

Tissue betaine is an intracellular osmolyte that also provides a store of labile methyl groups. Despite these important biological roles, there are few data regarding tissue betaine content. We measured the betaine concentration of plasma and various tissues (brain, heart, lungs, liver, kidney, spleen, intestine, reproductive tissues, skeletal muscle and skin) in male and female rats and assessed whether there were any gender-specific differences in betaine content or distribution and whether there was any relationship between tissue accumulation and plasma levels. Betaine was highest in the liver and kidney with values ranging from 1.6 to 9.5 mmol/l and 2.0 to 5.4 mmol/l, respectively. Plasma betaine concentrations were significantly lower than tissue levels except in the brain (? 25 % of plasma) and skeletal muscle (similar to plasma). Regression analysis of the combined male and female data revealed a significant plasma-related accumulation of betaine in the heart, skin and skeletal muscle, while the lung, liver, kidney, spleen, and intestine showed significant plasma-related and plasma-independent accumulations of betaine. The betaine content of the skin, liver and kidney was not significantly different between males and females, but in plasma and all tissues analyzed it was significantly higher in males (P<0.01).     

Hookworm behaviour: larval movement patterns after entering hosts.

Larvae of the cat hookworm, Ancylostoma tubaeforme migrate from the skin to the lungs of both mice and cats. Experiments have examined changes in the basic movement patterns of infective larvae after as long as 5 days within host tissues. Similarly, morphological developments and changes in unbound neutral lipid were investigated. There were no changes in the larvae except for a fall in the concentrations of lipid. Furthermore, it was found that larvae which had successfully completed a migration from the skin of a mouse to its lungs could successfully complete a second migration. The evidence does not support the hypothesis that a distinct series of tissues cr physico-chemical barriers may be sequentially followed in the migration of hookworms in their hosts. The migration route is seen as a much more random, less purposeful series of events.     

Trichinella spiralis: migration of larvae in the rat

Counts were made of Trichinella spiralis “migratory” larvae recovered from blood, abdominal cavity, lungs, liver, kidneys, and thoracic duct lymph of male albino rats from 4–15 days postinoculation. From these data, the pathways the larvae utilized to travel from the small intestine to skeletal muscle were determined. Approximately 70% of the encysted muscle larvae were accounted for by the lymph-blood circulatory system pathway. The data indicate that the other 30% probably migrated by way of both (a) the hepatic portal circulatory system to the heart and then to the general circulation and skeletal muscle; and (b) the abdominal cavity and/or abdominal fluids to skeletal muscle.     

Visceral larva migrans: migratory pattern of Toxocara canis in pigs.

The migratory pattern of Toxocara canis was investigated following infection of pigs with 60000 infective eggs. Groups of six pigs were slaughtered at 7, 14 and 28 days after infection (p.i.), and the number of larvae in selected organs and muscles was determined by digestion. A group of uninfected pigs was used as negative controls for blood parameters and weight gain. Toxocara canis migrated well in the pig, although the relative numbers of larvae recovered decreased significantly during the experiment. On day 7 p.i., high numbers of larvae were recovered from the lymph nodes around the small intestine and to some extent also from the lymph nodes around the large intestine, and from the lungs and the liver. On day 14, the majority of larvae were recovered from the lungs and the lymph nodes around the small intestine, and by day 28 p.i. most larvae were found in the lungs. Larvae were recovered from the brain on days 14 and 21, with a maximum on day 14 p.i. No larvae were found in the eyes. Severe pathological changes were observed in the liver and lungs, especially on day 14 p.i.; also, development of granulomas was observed in the kidneys. Finally, a strong specific antibody response towards T. canis L2/L3 ES products was observed from day 14 p.i. until termination of the experiment, and the maximum eosinophil response was observed 14 days p.i. The pig is a useful non-primate model for human visceral larva migrans, since T. canis migrate well and induce a strong immunological response in the pig. However, the importance of the pig as a paratenic host is probably minor, because of the relatively early death of most of the larvae.     

Ubiquitous binding of benzo[a]pyrene metabolites to DNA and protein in tissues of the mouse and rabbit

The in vivo formation of benzo[alpha]pyrene (BP) metabolite-DNA adducts in several tissues of mice and rabbits was examined. Included were tissues with widely divergent xenobiotic metabolizing capabilities such as liver and brain. The major adduct identified in each tissue was the (+)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10-tetrahydro-BP (BPDEI)-deoxyguanosine adduct. A 7 beta,8 alpha-dihydroxy-9 beta,10 beta-epoxy-7,8,9,10-tetrahydro-BP (BPDEII)-deoxyguanosine adduct, a (-)-BPDEI-deoxyguanosine adduct and an unidentified adduct were also observed. These adducts were present in all of the tissues of the mice and in the lungs of the rabbits; only BPDEI and BPDEII were seen in the rest of the rabbit tissues. In all of the tissues studied, the DNA adduct levels were unexpectedly similar. For example, the BPDEI-DNA adduct levels in muscle and brain of mice were approx. 50% of those in lung and liver at each oral BP dose examined. After an i.v. dose of BP in rabbits, the BPDEI adduct levels in lung were three times those in brain or liver and twice those in muscle. The binding of BP metabolites to protein was also determined in these tissues. The tissue-to-tissue variation in protein binding levels of BP metabolites was greater than that for BPDEI-DNA adducts. There are several possible explanations for the in vivo binding of BP metabolites to DNA and protein of various tissues. First, oxidative metabolism of BP in each of the examined tissues might account for the observed binding. Second, reactive metabolites could be formed in tissues such as liver and lung and be transported to cells in tissues such as muscle and brain where they bind to DNA and protein. In any case, the tissue-to-tissue variations in protein and DNA binding of BP-derived radioactivity do not correlate with differences in cytochrome P-450 activity.     

Alterations in Ascaris suum larval burdens, eosinophil numbers, and lysophospholipase activity associated with low levels of dietary iron

The effect of various amounts of dietary iron on the immune response was investigated using BALB/cAnNCr/BR mice infected with Ascaris suum. Changes in numbers of larvae, numbers of eosinophils, and levels of lysophospholipase (LPL) activity in lung or liver tissues were analyzed from nonimmune and immunized mice at 2 and 7 days postinfection (PI). Various iron diets did not influence the numbers of tissue larvae, eosinophils, or the LPL activity in lungs or livers of nonimmunized mice at various times after infection. Lung and liver LPL activity was reduced in immunized mice without significant changes in larval numbers at 2 days PI. At 7 days PI, lung and liver LPL activity, eosinophil numbers, and numbers of larvae were increased in immunized mice receiving low iron diets. Results confirm that low iron diets affect the host response to A. suum.     

Migration of Alaria marcianae (Trematoda) in domestic cats

The migration of Alaria marcianae was studied in domestic cats. Mesocercariae penetrated the stomach wall, entered the abdominal cavity, and penetrated the diaphragm within 3 hr. Direct penetration of the lungs via the thoracic cavity occurred within 6 hr. Also observed was a circulatory route to the lungs when mesocercariae were recovered from both the liver and the chambers of the heart. Upon entrance into the lungs, mesocercariae began to enlarge with sequential lappet formation, holdfast development, and penetration gland atrophy. By day 7, they were recognized as fully formed diplostomula. The diplostomula resided a minimum of 4 days in the lungs as they first appeared in the duodenum by day 11. Diplostomula were found in both the trachea and stomach, indicating that they reach the duodenum after being coughed up from the lungs and swallowed. Diplostomula recovered from the duodenum were indistinguishable morphologically from the most advanced lung forms. Maturation of the reproductive organs occurred in as little as 4 days as the first ovigerous specimens were seen on day 15. The bidirectional route to the lungs may be significant when viewed in light of the recent discovery of transmammarian transmission. If a hormonal stimulus is involved, it is conceivable that those mesocercariae in the circulatory system may be more readily influenced than those undergoing a somatic migration. This may account for why some larvae are diverted to the mammary glands in a pregnant mammal instead of the normal, maturative migration to the duodenum.