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Effect of iron deficiency on Trichuris suis and Ascaris suum infections in pigs

Published online by Cambridge University Press:  07 August 2001

S. PEDERSEN ,
I. SAEED ,
H. FRIIS  and
K. F. MICHAELSEN
S. PEDERSEN
Affiliation:
Danish Centre for Experimental Parasitology, The Royal Veterinary and Agricultural University, Ridebanevej 3, DK-1870 Frederiksberg C, Copenhagen, Denmark
I. SAEED
Affiliation:
Danish Centre for Experimental Parasitology, The Royal Veterinary and Agricultural University, Ridebanevej 3, DK-1870 Frederiksberg C, Copenhagen, Denmark
H. FRIIS
Affiliation:
Research Department of Human Nutrition, The Royal Veterinary and Agricultural University, Ridebanevej 3, DK-1870 Frederiksberg C, Copenhagen, Denmark Danish Bilharziasis Laboratory, Jaegersborg Allé 1D, DK-2920, Charlottenlund, Denmark
K. F. MICHAELSEN
Affiliation:
Research Department of Human Nutrition, The Royal Veterinary and Agricultural University, Ridebanevej 3, DK-1870 Frederiksberg C, Copenhagen, Denmark
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Abstract

The objective of this experiment was to detect a possible interaction between iron deficiency and intestinal nematode infections. We report on a 2×2 study where thirty-one 10-week-old pigs fed a low or a normal iron diet were infected with both Trichuris suis (4500 eggs) and Ascaris suum (1200 eggs). No significant difference was detected between diet groups with respect to parasitological parameters for A. suum or the total number of adult T. suis recovered at necropsy 10 weeks p.i. However, in the low iron group T. suis were located more proximally and the worms were increased in length. A higher proportion of pigs with initial faecal egg excretion at 6 weeks p.i. was observed in the low iron group, indicating a shortened pre-patency period. Worm fecundity and total faecal egg excretion were also highest in the low iron group. A significant correlation was found between female worm length and fecundity. The peripheral eosinophil counts were diminished in the low iron host groups. The infected low iron group experienced more severe pathophysiological changes in terms of hypoalbuminaemia and decreases in erythrocyte volumes. A significant inverse correlation existed between iron content in the bone-marrow and liver (body) store. In conclusion, iron deficiency increased the severity of T. suis infection in pigs.

Keywords

Trichuris suiswhipwormpigswinesingle infectioniron deficiency
Type
Research Article
Information
Parasitology , Volume 122 , Issue 5 , May 2001 , pp. 589 - 598
Copyright
2001 Cambridge University Press

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References

ALLEN, L. & AHLUWALIA, N. (1997). Improving Iron Status Through Diets: The Application of Knowledge Correcting Dietary Iron Bioavailability in Human Populations. OMNI/USAID, Arlington, VA, USA.
BATTE, E. G., MCLAMB, R. D., MUSE, K. E., TALLY, S. D. & VESTAL, T. J. (1977). Pathophysiology of swine trichuriasis. American Journal of Veterinary Research 38, 10751079.Google Scholar
BEER, R. J. S. (1973a). Studies on the biology of the life-cycle of Trichuris suis Schrank, 1788. Parasitology 67, 253262.Google Scholar
BEER, R. J. S. (1973b). Morphological descriptions of the egg and larval stages of Trichuris suis Schrank, 1788. Parasitology 67, 263278.Google Scholar
BEER, R. J. S. & LEAN, I. J. (1973). Clinical trichuriasis produced experimentally in growing pigs. Part 1: Pathology of infection. Veterinary Record 93, 189195.Google Scholar
BEER, R. J., SANSOM, B. F. & TAYLOR, P. J. (1974). Erythrocyte losses from pigs with experimental Trichuris suis infections measured with a whole-body counter. Journal of Comparative Pathology 84, 331346.CrossRefGoogle Scholar
BEER, R. J., TAFFS, L. F., JACOBS, D. E., LEAN, I. J. & CURRAN, M. K. (1971). Evaluation of dichlorvos (v3 formulation) against larval and adult Trichuris suis and observations on experimental infection in growing pigs. Veterinary Record 88, 436441.CrossRefGoogle Scholar
BEISEL, W. R. (1982). Synergism and antagonism of parasitic diseases and malnutrition. Reviews of Infectious Diseases 4, 746750.CrossRefGoogle Scholar
BOLIN, T. D., DAVIS, A. E., CUMMINS, A. G., DUNCOMBE, V. M. & KELLY, J. D. (1977). Effect of iron and protein deficiency on the expulsion of Nippostrongylus brasiliensis from the small intestine of the rat. Gut 18, 182186.CrossRefGoogle Scholar
BUNDY, D. A. P. & GOLDEN, M. H. N. (1987). The impact of host nutrition on gastrointestinal helminth populations. Parasitology 95, 623635.CrossRefGoogle Scholar
BURDEN, D. J. & HAMMET, N. C. (1976). A comparison of the infectivity of Trichuris suis ova embryonated by four different methods. Veterinary Parasitology 2, 307311.CrossRefGoogle Scholar
CHAN, M. S., MEDLEY, G. F., JAMISON, D. & BUNDY, D. A. P. (1994). The evaluation of global morbidity attributable to intestinal nematode infections. Parasitology 109, 373387.CrossRefGoogle Scholar
CHWALIBOG, A. (1997). Husdyrernœring. Bestemmelse af Nœringsvœrdi og Nœringsbehov, 3. udgave. DSR forlag, København (in Danish).
COOP, R. L. & KYRIAZAKIS, I. (1999). Nutrition-parasite interaction. Veterinary Parasitology 84, 187204.CrossRefGoogle Scholar
DALLMAN, P. R. (1987). Iron deficiency and the immune system. American Journal of Clinical Nutrition 46, 329334.CrossRefGoogle Scholar
DUNCOMBE, V. M., BOLIN, T. D. & DAVIS, A. (1979). The effect of iron and protein deficiency on the development of acquired resistance to reinfection with Nippostrongylus brasiliensis in rats. American Journal of Clinical Nutrition 32, 553558.CrossRefGoogle Scholar
FLEMING, A. (1982). Iron deficiency in the tropics. Clinics in Haematology 11, 365388.Google Scholar
HOLLAND, C. (1987). Neglected infections–trichuriasis and strongyloidiasis. In Impact of Helminth Infections on Human Nutrition (ed. STEPHENSON, L. S.), pp. 161201. Taylor & Francis; London.
LARSEN, T. & SANDSTRÖM, B. (1992). Tissues and organs as indicators of intestinal absorption of minerals and trace elements evaluated in rats. Biological Trace Element Research 35, 185199.CrossRefGoogle Scholar
MILLER, R. A. & BRITIGAN, B. E. (1997). Role of oxidants in microbial pathophysiology. Clinical Microbiology Reviews 10, 118.Google Scholar
MILLER, E. R. & ULLREY, D. E. (1987). The pig as a model for human nutrition. Annual Review of Nutrition 7, 361382.CrossRefGoogle Scholar
OLSEN, A., NAWIRI, J. & FRIIS, H. (2000). The impact of iron supplementation on reinfection with intestinal helminths and Schistosoma mansoni in western Kenya. Transactions of the Royal Society of Tropical Medicine and Hygiene 94, 493499.CrossRefGoogle Scholar
POWERS, K. G., TODD, A. C. & MCNUTT, S. H. (1960). Experimental infections of swine with Trichuris suis. American Journal of Veterinary Research 21, 262268.Google Scholar
ROEPSTORFF, A. & MURRELL, K. D. (1997). Transmission dynamics of helminth parasites of pigs on continuous pasture: Ascaris suum and Trichuris suis. International Journal for Parasitology 27, 563572.CrossRefGoogle Scholar
ROEPSTORFF, A. & NANSEN, P. (1998). The Epidemiology, Diagnosis and Control of Helminth Parasites of Swine. FAO Animal Health Manual, No. 3. FAO, Rome, Italy.
SHERWOOD, R. A., PIPPARD, M. J. & PETERS, T. J. (1998). Iron homeostasis and the assessment of iron status. Annals of Clinical Biochemistry 35, 693708.CrossRefGoogle Scholar
STEPHENSON, L. S. (1987). Impact of Helminth Infections on Human Nutrition. Taylor & Francis, London.
STOLTZFUS, R. & DREYFUSS, M. (1998). Guidelines for the Use of Iron Supplements to Prevent and Treat Iron Deficiency Anaemia. The International Nutritional Anaemia Consultative group (INACG/WHO/UNICEF),Washington, DC, USA.
WHITTAKER, P. (1998). Iron and zinc interactions in humans. American Journal of Clinical Nutrition 68 (Suppl.), S442S446.CrossRefGoogle Scholar
WORLD HEALTH ORGANIZATION. (1998). Life in the 21st Century: A Vision for All. Report of the Director General of the World Health Organization. WHO, Geneva, Switzerland.Google Scholar