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The effects of diet on the faecal pH of horses

Published online by Cambridge University Press:  27 February 2018

C.E. Hale  and
S. Pickering
C.E. Hale
Affiliation:
Writtle College, Writtle, Chelmsford, Essesx, CM1 3RR, UK. Email: [email protected]
S. Pickering
Affiliation:
Reaseheath College, Reaseheath, Nantwich, Cheshire, CW5 6DF, UK
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Extract

Laminitis is accepted as one of the most common causes of lameness in horses (Johnson et al., 2004). The painful and crippling condition is potentially fatal and has obvious far-reaching implications for the welfare of affected animals, . However, considering the prevalence of the disease, the exact aetiology of laminitis has still to be unanimously identified (Hale, 2005; Bailey et al., 2004; Mungall et al., 2001). Although there are several causes of laminitis in horses, studies into the dietary-induced form of the disease have found there to be a strong correlation between ingestion of large amounts of soluble carbohydrates and the development of laminitis. Excessive consumption of cereal starch or soluble sugars found in pasture have been linked to the aetiology of the disease (King and Mansmann, 2004). Indeed, in a recent study carried out in America, it was concluded that 53% of all laminitis cases were dietary induced, with 46% attributed to “lush pasture” and 7% caused by grain overload (USDA, 2000).

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Posters
Information
BSAP Occasional Publication , Volume 35: Applying Equine Science: Research into Business , 2006 , pp. 305 - 309
Copyright
Copyright © British Society of Animal Production 2006

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References

Bailey, S.R., Ballion, M.-L., Rycroft, A.N., Harris, P.A. and Elliott, J. (2003)a. Identification of equine caecal bacteria producing amines in an in vitro model of carbohydrate overload. Applied and Environmental Microbiology, 69, (4), 20872093.Google Scholar
Bailey, S.R., Marr, C.M. and Elliott, J. (2003) b. Identification and quantification of amines in the equine caecum. Research in Veterinary Science, 74, 113118.Google Scholar
Bailey, S.R., Marr, C.M. & Elliott, J. (2004). Current research and theories on the pathogenesis of acute laminitis in the horse. The Veterinary Journal, 167, 129142.Google Scholar
Cahn, T.T., Sutton, A.L., Aarnink, A.J.A., Verstegan, M.W.A., Schrama, J.W. & Bakker, G.C.M. (1998). Dietary carbohydrates alter the faecal composition & the ammonia emission from slurry of growing pigs. Journal of Animal Science 76, 18871895.Google Scholar
Dyer, J., Merediz, E.F.-C., Salmon, K.S.H., Proudman, C.J., Edwards, G.B. and Shirazi-Beechey, S.P. (2002). Molecular characteristics of carbohydrate digestion and absorption in the equine small intestine. Equine Veterinary Journal, 34, 349358.Google Scholar
Garner, M.R., Flint, J.F. and Russell, J.B. (2002). Allisonella histaminiforman gen. nov., sp. nov. A novel bacterium that produces histamine, utilises histidine as its sole energy source, and could play a role in bovine and equine laminitis. Systemic and Applied Microbiology, 25, 498506.Google Scholar
Gill, H.S., Shu, Q. and Leng, R.A. (2000). Immunization with Streptococcus bovis protects against lactic acidosis in sheep. Vaccine, 18, 25412548.CrossRefGoogle ScholarPubMed
Hale, C.E. (2005). Dietary – Induced Laminitis; A Review. National Equine Student 6, 711.Google Scholar
King, C. and Mansmann, R.A. (2004). Preventing laminitis in horses: Dietary strategies for horse owners. Clinical Techniques in Equine Practice 3, 96102.Google Scholar
Longland, A. and Cairns, A. (1998). Sugars in grass – an overview of sucrose and fructan accumulation in temperate grasses. Proceedings of the Dodson and Horrell International Research Conference on Laminitis, 13.Google Scholar
McLean, B.M.L., Hyslop, J.J., Longland, A.C., Cuddeford, D. and Hollands, T. (2000). Physical processing of barley and its effects on intra-caecal fermentation parameters in ponies. Animal Feed Science and Technology 85, 7987.Google Scholar
Mungall, B.A., Kyaw-Tanner, M., and Pollitt, C.C. (2001). In vitro evidence for a bacterial pathogenesis of equine laminitis. Veterinary Microbiology, 79, 209233.Google Scholar
Pollitt, C.C. (2004). Equine Laminitis. Clinical Techniques in Equine Practice 3, 3444.CrossRefGoogle Scholar
Radicke, S., Kienzle, E. and Meyer, H. (1991). Preileal apparent digestibility of oats & corn starch & consequences for cecal metabolism. In: Proceedings of the 12th Equine Nutrition & Physiology Symposium. Calgary, Canada, pp 4348.Google Scholar
Tajima, K., Arai, S., Ogata, K., Nagamine, T., Matsui, H., Nakamura, M., Aminov, R.I., and Benno, Y. (2000). Rumen bacterial community transistion during adaptation to high-grain diet. Anaerobe, 6, 273284.Google Scholar
USDA, (2000). Lameness and laminitis in US horses. National Animal Health monitoring System. Fort Collins.Google Scholar
Wheeler, R. (2004). An investigation into whether a significant correlation exists between feed pH and faecal pH of horses fed a variety of different diets. In: Alliston, J., Chadd, S., Ede, A., Hemmings, A., Hyslop, J., Longland, A., Moreton, H. and Moore-Colyer, M. Emerging Equine Science BSAS pub 32, Nottingham University Press. pp 211213.Google Scholar