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Journal of Parasitic Diseases

, Volume 40, Issue 3, pp 724–729 | Cite as

Effect of induced Fasciola gigantica infection during pre-patency on the performance of buffalo calves fed on different percentage of protein

  • P. Singh
  • A. K. Verma
  • S. C. Gupta
  • U. R. Mehra
Original Article
  • 63 Downloads

Abstract

Thirty growing Murrah buffalo calves (8–12 months of age, 109.85 ± 2.43) were reared in parasite free conditions and randomly divided into three equal groups as per CRD. They were fed on iso-caloric (2.01 ME Mcal/Kg diet) diets containing standard protein (SP) diet at 100 %, 90 % of SP (medium protein, MP) and 80 % of SP (low protein, LP) of the protein requirements (Kearl 1982). After 21 days of feeding, each group was further subdivided into two sub-groups (A & B). Animals in sub-groups ‘A’ served as non-infected control, while in sub group ‘B’ were orally infected with Fasciola gigantica metacercarie (mc; 1,000 each). A metabolic trial of 40 days post infection was carried out in control and parasitized animals. Intake of digestible dry matter, organic matter and acid detergent fibre (ADF) was significantly higher (P < 0.05) in SP group compared to LP group. The digestibility of crude protein (CP) and ADF was significantly higher in SP group compared to MP and LP groups. The digestible crude protein (DCP) and total digestible nutrients (TDN) intakes (g/kgW0.75) were also significantly (P < 0.001) higher in SP than MP and LP groups. However, DCP intake was significantly (P < 0.001) lower in infected subgroups compared to control subgroups. Intake and balance (g/d) of nitrogen, calcium and phosphorus were significantly (P < 0.01) higher in SP than MP and LP groups. The average daily gain of buffalo calves fed on SP Uninfected (SPU), SP Infected (SPI), MPU, MPI and LPU, LPI groups was 333, 178, 356, 144, 222 and 144 g and was significantly (P < 0.01) lower in animals fed LP ration. The feed conversion ratio (FCR) was also significantly (P < 0.01) higher in infected sub-groups as compared to respective control groups. The results showed that a SP diet substantially improved the overall performance of buffalo calves in control and infected groups and reduced adverse effect of F. gigantica infection.

Keywords

Fasciola gigantica Buffalo Protein levels Growth rate Nutrient utilization 

Notes

Acknowledgments

Authors are thankful to the Director, Indian Veterinary Research Institute, Izatnagar for providing required facilities to carry out the research work and Indian Council of Agricultural Research for financial support as AP Cess Fund Scheme.

References

  1. Akinbamijo OO, Lahlou-kassi A, Tembely S (1996) Effect of experimental fascioliasis on feed intake, nitrogen retention and body weight changes in open and pregnant Menz sheep. Small Rumin Res 20:163–169CrossRefGoogle Scholar
  2. AOAC (2000) Official Methods of Analysis, 16th edn. Association of Official Analytical Chemists, Washington, DCGoogle Scholar
  3. Cawdery MJH, Strickland KL, Conway A, Crowe PJ (1977) Production effects of liver fluke in cattle Part 1. Effects of infection on live weight gain, feed intake and food conversion efficiency in beef cattle. Br Vet J 133:145–159CrossRefPubMedGoogle Scholar
  4. Chantiratikul A, Chumpawadee S, Kanchanamayoon W, Chantiratikul P (2009) Effect of dietary protein on nutrient digestibility and nitrogen metabolism in Thai-Indigenous heifers. J Anim Vet Adv 8:297–300Google Scholar
  5. Chumpawadee S, Pimpa O (2008) Effect of non forage high fibrous feedstuffs as fiber sources in total mixed ration on gas production characteristics and in vitro fermentation. Pak J Nutr 7:459–464CrossRefGoogle Scholar
  6. Hawkins CD, Morris RS (1978) Depression of productivity in sheep infected with Fasciola hepatica. Vet Parasitol 4:341–350CrossRefGoogle Scholar
  7. Hoffman PC, Esser NM, Bauman LM, Denzina Engstrom M, Cheser-Jonos (2001) Effect of dietary protein on growth and nitrogen balance of Holstein heifers. J Dairy Sci 84:843–847CrossRefPubMedGoogle Scholar
  8. Ingale SL, Singh P, Verma AK, Mehra UR (2010) Effect of Fasciola gigantica infection on nutrient utilization and cytokine gene expression during prepatent period in crossbred calves. Anim Nutr Feed Technol 10:177–185Google Scholar
  9. Jacob AB, Singh P, Raina OK, Verma AK (2012) Growth performance and nutrient utilization in crossbred calves experimentally infected with F. gigantica and/or supplemented with deoiled mahua (Bassia latifolia) seed cake. Livest Sci 149:109–117CrossRefGoogle Scholar
  10. Kawashima T, Sumamal W, Pholsen P, Chaithang R, Boonpakdee W, Terada F (2003) Energy and nitrogen metabolism of Thai native cattle given ruzi grass hay with different levels of soybean meal. In: Animal Research Report, Division of Animal Nutrition, of Agriculture and Cooperative, pp: 263–378Google Scholar
  11. Kearl LC (1982) Nutrient requirements of ruminants in developing countries. International feedstuffs Institute, Utah Agricultural Experimental Station, Utah State University, Logan, Utah 84322, USA. ISBN: 0-87421-116-6Google Scholar
  12. Kumar P, Sharma MC (1991) Infertility in rural cows in relation to fasciolosis. Indian J Anim Sci 47:273–274Google Scholar
  13. Mehra UR, Dass RS, Verma AK, Sharma RL, Yadav SC (1999) Effect of Fasciola gigantica infection on growth and nutrient utilization in buffalo calves. Vet Rec 145:699–702PubMedGoogle Scholar
  14. Milis C, Liamadis D (2007) Effect of protein levels, main protein and non forage fibre source on digestibility, N-balance and energy value of sheep rations. J Anim Vet Adv 6:68–75Google Scholar
  15. NRC (1988) Nutrient requirements of dairy cattle. National Academy Press, Washington, DCGoogle Scholar
  16. Sharma RL, Dhar DN, Raina OK (1989) Studies on the prevalence and laboratory transmission of fasciolosis in animal in the Kashmir valley. Br Vet J 145:5761CrossRefGoogle Scholar
  17. Snedecor GW, Cochran WG (1994) Statistical methods, 8th edn. Iowa State University, IowaGoogle Scholar
  18. Spithill TW, Smooker PM, Coperman DB (1999) Fasciola gigantica: epidemiology, control, immunology and molecular biology. In: Dalton JP (ed) Fasciolosis. CAB International, Cambridge, pp 465–527Google Scholar
  19. Sykes AR, Coop RL, Rushton B (1980) Chronic subclinical fasciolosis in sheep: effect on food intake, food utilization and blood constituents. Res Vet Sci 28:63–70CrossRefPubMedGoogle Scholar
  20. Talpatra SK, Ray SN, Sen KC (1940) The analysis of mineral constituents in biological material. Part 1. Estimation of phosphorus, chlorine, calcium, magnesium, sodium and potassium in food stuffs. Indian J Vet Sci Anim Husb 10:243–246Google Scholar
  21. Van Soest PJ, Robertson JB, Lewis BA (1991) Methods of dietary fibre, neutral detergent fibre and non-starch polysaccherides in relation to animal nutrition. J Dairy Sci 74:3583–3597CrossRefGoogle Scholar
  22. Veira DM, Macleod GK, Burton JH, Stone JB (1980) Nutrition of the weaned Holstein calf. I. Effect of dietary protein levels on ruminant metabolism. J Anim Sci 50:937–944CrossRefPubMedGoogle Scholar
  23. Yadav SC, Sharma RL, Kalicharan, Mehra UR, Dass RS, Verma AK (1999) Primary experimental infection of riverine buffaloes with Fasciola gigantica. Vet Parasitol 82:285–296CrossRefPubMedGoogle Scholar

Copyright information

© Indian Society for Parasitology 2014

Authors and Affiliations

  • P. Singh
    • 1
  • A. K. Verma
    • 1
  • S. C. Gupta
    • 2
  • U. R. Mehra
    • 1
  1. 1.Animal Nutrition DivisionIndian Veterinary Research InstituteIzatnagarIndia
  2. 2.Parasitology DivisionIndian Veterinary Research InstituteIzatnagarIndia

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