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Association of lameness with milk yield and lactation curves in Chios dairy ewes

Published online by Cambridge University Press:  04 February 2015

Athanasios I Gelasakis ,
Georgios Arsenos ,
Georgios E Valergakis  and
Georgios Banos
Athanasios I Gelasakis*
Affiliation:
Laboratory of Animal Husbandry, School of Veterinary Medicine, Aristotle University of Thessaloniki, Box 393, 54124 Thessaloniki, Greece
Georgios Arsenos
Affiliation:
Laboratory of Animal Husbandry, School of Veterinary Medicine, Aristotle University of Thessaloniki, Box 393, 54124 Thessaloniki, Greece
Georgios E Valergakis
Affiliation:
Laboratory of Animal Husbandry, School of Veterinary Medicine, Aristotle University of Thessaloniki, Box 393, 54124 Thessaloniki, Greece
Georgios Banos
Affiliation:
Laboratory of Animal Husbandry, School of Veterinary Medicine, Aristotle University of Thessaloniki, Box 393, 54124 Thessaloniki, Greece Department of Animal Breeding and Genomics, Animal & Veterinary Sciences, Scotland's Rural College, RIB, Easter Bush, Midlothian EH259RG, UK
*
*For correspondence; e-mail: gelasakis.vet@gmail.com
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Abstract

The objective of the study was twofold: (i) to quantify the differences in daily milk yield (DMY) and total milk yield (TMY) between lame and non-lame dairy ewes and (ii) to determine the shape of lactation curves around the lameness incident. The overall study was a prospective study of lameness for the surveyed sheep population, with a nested study including the selection of matching controls for each lame ewe separately. Two intensively reared flocks of purebred Chios ewes and a total of 283 ewes were used. Data, including gait assessment and DMY records, were collected on a weekly basis during on-farm visits across the milking period. A general linear model was developed for the calculation of lactation curves of lame and non-lame ewes, whereas one-way ANOVA was used for the comparisons between lame ewes and their controls. Lameness incidence was 12·4 and 16·8% on Farms A and B, respectively. Average DMY in lame ewes was significantly lower (213·8 g, P < 0·001) compared with the rest of the flock, where DMY averaged 1·340 g. The highest DMY reduction in lame ewes was observed during the week 16 of the milking period (P < 0·001), whereas the reduction of DMY, for lame ewes, remained significant at P < 0·001 level from week 8 to week 28 of milking. Comparisons between lame and controls revealed that at the week of lameness diagnosis a significant DMY reduction (P ≤ 0·001) was observed in lame ewes (about 32·5%), which was maximised 1 week later (35·8%, P ≤ 0·001) and continued for several weeks after recovery, resulting in 19·3% lower TMY for lame ewes for the first 210 d of the milking period (P < 0·01). Moreover, at flock level, TMY for non-lame and lame ewes, as calculated by the general linear model, was 318·9 and 268·0 kg, respectively. The results of this study demonstrate evidence of significant financial losses in dairy sheep due to lameness which, however, need to be accurately estimated in further, more detailed, analyses.

Keywords

Lamenessdairy sheepmilk yieldlactation curves
Type
Research Article
Information
Journal of Dairy Research , Volume 82 , Issue 2 , May 2015 , pp. 193 - 199
Copyright
Copyright © Proprietors of Journal of Dairy Research 2015 

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References

Barkema, HW, Westrik, JD, van Keulen, KAS, Schukken, YH & Brand, A 1994 The effects of lameness on reproductive performance, milk production and culling in Dutch Dairy Farms. Preventive Veterinary Medicine 20 249259Google Scholar
Barker, ZE, Amory, JR, Wright, JL, Mason, SA, Blowey, RW & Green, LE 2009 Risk factors for increased rates of sole ulcers, white line disease, and digital dermatitis in dairy cattle from twenty-seven farms in England and Wales. Journal of Dairy Science 92 19711978Google Scholar
Bicalho, RC, Warnick, LD & Guard, CL 2008 Strategies to analyze milk losses caused by diseases with potential incidence throughout the lactation: a lameness example. Journal of Dairy Science 91 26532661CrossRefGoogle ScholarPubMed
Boden, E 1998 Black's Veterinary Dictionary, 10th edition. London: Adam & Charles BlackGoogle Scholar
Conington, J, Nicoll, L, Mitchell, S & Bünger, L 2010 Characterisation of white line degeneration in sheep and evidence for genetic influences on its occurrence. Veterinary Research Communications 34 481489CrossRefGoogle ScholarPubMed
Coulon, JB, Lescourret, F & Fonty, A 1996 Effect of foot lesions on milk production by dairy cows. Journal of Dairy Science 79 4449Google Scholar
De Rancourt, M, Fois, N, Lavín, MP, Tchakérian, E & Vallerand, F 2006 Mediterranean sheep and goats production: an uncertain future. Small Ruminant Research 62 167179Google Scholar
Dohoo, IR & Martin, SW 1984 Disease, production and culling in Holstein-Friesian cows. IV. Effects of disease on production. Preventive Veterinary Medicine 2 755770Google Scholar
Espejo, LA, Endres, MI & Salfer, JA 2006 Prevalence of lameness in high-producing Holstein cows housed in freestall barns in Minnesota. Journal of Dairy Science 89 30523058Google Scholar
Eze, CA 2002 Lameness and reproductive performance in small ruminants in Nsukka Area of the Enugu State, Nigeria. Small Ruminant Research 44 263267CrossRefGoogle Scholar
Fthenakis, GC, El-masannat, ETS, Booth, JM & Jones, JET 1991 Somatic cell counts of ewes milk. British Veterinary Journal 47 575581Google Scholar
Gelasakis, AI, Valergakis, GE & Arsenos, G 2009 Predisposing factors of sheep lameness. Journal of the Hellenic Veterinary Medical Society 59 346356Google Scholar
Gelasakis, AI, Arsenos, G, Valergakis, GE, Fortomaris, P & Banos, G 2010 Effect of lameness on milk production in a flock of dairy sheep. The Veterinary Record 167 533534CrossRefGoogle Scholar
Gelasakis, AI, Valergakis, GE, Arsenos, G & Banos, G 2012 Description and typology of intensive Chios dairy sheep farms in Greece. Journal of Dairy Science 95 30703079Google Scholar
Gelasakis, AI, Oikonomou, G, Bicalho, RC, Valergakis, GE, Fthenakis, GC & Arsenos, G 2013 Clinical characteristics of lameness and potential risk factors in intensive and semi-intensive dairy sheep flocks in Greece. Journal of the Hellenic Veterinary Medical Society 64 123130CrossRefGoogle Scholar
Green, LE & George, TRN 2008 Assessment of current knowledge of footrot in sheep with particular reference to Dichelobacter nodosus and implications for elimination or control strategies for sheep in Great Britain. The Veterinary Journal 175 173178Google Scholar
Green, LE, Hedges, VJ, Schukken, YH, Blowey, RW & Packington, AJ 2002 The impact of clinical lameness on the milk yield of dairy cows. Journal of Dairy Science 85 22502256Google Scholar
Harden, LM, Du Plessis, I, Poole, S & Laburn, HP 2008 Interleukin (IL)-6 and (IL)-1β act synergistically within the brain to induce sickness behaviour and fever in rats. Brain, Behaviour and Immunity 22 838849Google Scholar
Hill, NP, Murphy, PE, Nelson, AJ, Mouttotou, N, Green, LE & Morgan, KL 1997 Lameness and foot lesions in adult British dairy goats. The Veterinary Record 141 412416Google Scholar
Huxley, JN 2013 Impact of lameness and claw lesions in cows on health and production. Livestock Science 156 6470Google Scholar
Kaler, J & Green, LE 2008 Naming and recognition of six foot lesions of sheep using written and pictorial information: a study of 809 English sheep farmers. Preventive Veterinary Medicine 83 5264Google Scholar
Kaler, J, Wassink, GJ & Green, LE 2009 The inter- and intra-observer reliability of a locomotion scoring scale for sheep. The Veterinary Journal 180 189194CrossRefGoogle ScholarPubMed
Leach, KA, Whay, HR, Maggs, CM, Barker, ZE, Paul, ES, Bell, AK & Main, DC 2010 Working towards a reduction in cattle lameness: 1. Understanding barriers to lameness control on dairy farms. Research in Veterinary Science 89 311317Google Scholar
Machado, VS, Caixeta, LS & Bicalho, RC 2011 Use of data collected at cessation of lactation to predict incidence of sole ulcers and white line disease during the subsequent lactation in dairy cows. American Journal of Veterinary Research 72 13381343Google Scholar
Marshall, DJ, Walker, RI, Cullis, BR & Luff, MF 1991 The effect of footrot on body weight and wool growth of sheep. Australian Veterinary Journal 68 4549Google Scholar
Martin, SW, Aziz, SA, Sandals, WCD & Curtis, RA 1982 The association between clinical disease, production and culling of Holstein-Friesian cows. Canadian Journal of Animal Science 62 633640Google Scholar
Ministry of Agriculture Fisheries and Food 1986 Manual of Veterinary Parasitological Laboratory Techniques. London: HMSOGoogle Scholar
Oikonomou, G, Cook, NB & Bicalho, RC 2013 Sires predicted transmitting ability for conformation and yield traits and previous lactation incidence of foot lesions as risk factors for the incidence of foot lesions in Holstein cows. Journal of Dairy Science 96 37133722Google Scholar
Phythian, CJ, Cripps, PC, Grove-White, D, Jones, PH, Michalopoulou, E & Duncan, JS 2013 Observing lame sheep: evaluating test agreement between group-level and individual animal methods of assessment. Animal Welfare 22 417422Google Scholar
Rajala-Schultz, PJ, Grοhn, YT & McCulloch, CE 1999 Effects of milk fever, ketosis, and lameness on milk yield in dairy cows. Journal of Dairy Science 82 288294Google Scholar
Russel, AJF, Doney, JM & Gunn, RG 1969 Subjective assessment of fat in live sheep. Journal of Agricultural Science 72 451454Google Scholar
Stewart, DJ, Clark, BL & Jarrett, RG 1984 Difference between strains of Bacteroides nodosus in their effects on the severity of footrot, body weight and wool growth in Merino sheep. Australian Veterinary Journal 61 348352CrossRefGoogle ScholarPubMed
Van Hertem, T, Maltz, E, Antler, A, Romanini, CEB, Viazzi, S, Bahr, C, Schlageter-Tello, A, Lockhorst, C, Berckmans, D & Halachmi, I 2013 Lameness detection based on multivariate continuous sensing of milk yield, rumination, and neck activity. Journal of Dairy Science 96 42864298Google Scholar
Warnick, LD, Janssen, D, Guard, CL & Gröhn, YT 2001 The effect of lameness on milk production in dairy cows. Journal of Dairy Science 84 19881997Google Scholar
Winter, AC 2004 Lameness in Sheep. Ramsbury, Marlborough, Wiltshire: The Crowood PressGoogle Scholar
Winter, AC & Arsenos, G 2009 Diagnosis of white line lesions in sheep. In Practice 31 1721Google Scholar