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Associations of teat morphometric parameters and subclinical mastitis in riverine buffaloes

Published online by Cambridge University Press:  02 August 2018

Gagandeep Kaur
Affiliation:
Department of Veterinary Medicine, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, India
Baljinder Kumar Bansal
Affiliation:
Department of Veterinary Medicine, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, India
Raj Sukhbir Singh*
Affiliation:
Department of Teaching Veterinary Clinical Complex, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, India
Neeraj Kashyap
Affiliation:
Department of Animal Breeding and Genetics, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, India
Shukriti Sharma
Affiliation:
Department of Veterinary Medicine, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, India
*
*For correspondence; e-mail: [email protected]

Abstract

The possible association between teat morphometric traits and subclinical mastitis (SCM) in dairy buffaloes was studied. Teat morphometric parameters, i.e. teat shape (bottle, conical, cylindrical, and others), teat-end shape (flat, round, and pointed), teat length (TL), teat diameter (TD), and teat-end to floor distance were measured before milking, but after proper milk let-down, in clinically healthy buffaloes (47 Murrah and 34 Nili-Ravi breeds). Subclinical mastitis was defined on the basis of bacteriology and somatic cell count (SCC) of quarter foremilk samples. A high proportion of cylindrical teats (40%) and pointed teat-ends (64·4%) was observed. Hind teats were longer and thicker than fore teats (P < 0·05). A significant breed effect was found with respect to teat shape, length and diameter (P < 0·05). Teats were mostly cylindrical (43·3 vs. 35·4%) and conical (34·2 vs. 30·8%) shaped, smaller (mean 8·2 vs. 9·5 cm) and thinner (mean 3·3 vs. 3·6 cm) in the Murrah breed compared with the Nili-Ravi breed. Teats that had ‘other’ shapes and were longer, wider, and placed closer to the floor were more associated with SCM (P < 0·05). Mean SCC was significantly higher (P < 0·05) in Nili-Ravi buffaloes, teat shapes classified as ‘others’, and quarters with SCM. Teat morphometric traits seem to be associated with indicators of udder health in buffaloes, thus, their inclusion in breeding programmes for selection against undesirable dairy type traits may be of value in reducing susceptibility to intramammary infections in Indian buffaloes.

Type
Research Article
Copyright
Copyright © Hannah Dairy Research Foundation 2018 

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References

Abdullah, M, Javed, K, Khalid, MS, Ahmad, N, Bhatti, JA & Younas, U 2013 Relationship of udder and teat morphology with milk production in Nili-Ravi buffaloes of Pakistan. Buffalo Bulletin 32 13351338Google Scholar
Ahlawat, SPS, Vij, PK & Tantia, MS 2003 Conservation of buffalo genetic resources. In Proceedings of 4 th Asian Buffalo Congress, New Delhi, India, pp. 62–68Google Scholar
Bardakcioglu, HE, Sekkin, S & Toplu, HDO 2011 Relationship between some teat and body measurements of Holstein cows and sub-clinical mastitis and milk yield. Journal of Animal and Veterinary Advances 10 17351737Google Scholar
Berry, DP, Buckley, F, Dillon, P, Evans, RD & Veerkamp, RF 2004 Genetic relationships among linear type traits, milk yield, body weight, fertility and somatic cell count in primiparous dairy cows. Irish Journal of Agricultural and Food Research 43 161176Google Scholar
Bharadwaj, A, Dixit, VB, Sethi, RK & Khanna, S 2007 Association of breed characteristics with milk production in Murrah buffaloes. Indian Journal of Animal Science 77 10111016Google Scholar
Bharti, P, Bhakat, C, Pankaj, PK, Bhat, SA, Prakash, MA, Thul, MR & Japheth, KP 2015 Relationship of udder and teat conformation with intramammary infection in crossbred cows under hot-humid climate. Veterinary World 8 898901Google Scholar
Bhutto, AL, Murray, RD & Woldehiwet, Z 2010 Udder shape and teat-end lesions as potential risk factors for high somatic cell counts and intramammary infections in dairy cows. The Veterinary Journal 183 6367Google Scholar
Breen, JE, Bradley, AJ & Green, MJ 2009 Quarter and cow risk factors associated with a somatic cell count greater than 199 000 cells per milliliter in United Kingdom dairy cows. Journal of Dairy Science 92 31063115Google Scholar
Bulla, TR, Rana, YS, Sharma, A & Beniwal, BS 2006 Prevalence of subclinical mastitis in Murrah buffaloes. Haryana Veterinarian 45 5356Google Scholar
Chandrasekar, T, Das, KS, Bhat, SA, Singh, JK, Parkunanan, T, Japheth, KP & Bharti, P 2016 Relationship of prepartum udder and teat measurements with subsequent milk production traits in primiparous Nili-Ravi buffaloes. Veterinary World 9 11731177Google Scholar
Chrystal, MA, Seykora, AJ & Hansen, LB 1999 Heritabilities of teat end shape and teat diameter and their relationships with somatic cell score. Journal of Dairy Science 82 20172022Google Scholar
Chrystal, MA, Seykora, AJ, Hansen, LB, Freeman, AE, Kelley, DH & Healey, MH 2001 Heritability of teat-end shape and the relationship of teat-end shape with somatic cell score for an experimental herd of cows. Journal of Dairy Science 84 25492554Google Scholar
Coban, O, Sabuncuoglu, N & Tuzemen, N 2009 A study on relationships between somatic cell count (SCC) and some udder traits in dairy cows. Journal of Animal and Veterinary Advances 8 134138Google Scholar
Deng, MP, Badri, TM, Atta, M & Hamad, ME 2012 Relationship between udder dimensions and milk yield of Kenana × Friesian crossbred cows. Research Opinion in Animal and Veterinary Science 2 4954Google Scholar
Hardenberg, F 2016 Clinical and subclinical mastitis in dairy cattle and buffaloes in Bihar, India Prevalence, major pathogens and risk factors. Assessed online on 2017 https://stud.epsilon.slu.se/8859/1/Hardenberg_F_160225.pdfGoogle Scholar
Hogan, JS, González, RN, Harmon, RJ, Nickerson, SC, Oliver, SP, Pankey, JW & Smith, KL 1999 Laboratory Handbook on Bovine Mastitis. Revised edition. Madison, WI, USA: National Mastitis Council IncGoogle Scholar
Hussain, R, Javed, MJ, Khan, A & Muhammad, G 2013 Risks factors associated with subclinical mastitis in water buffaloes in Pakistan. Tropical Animal Health and Production 45 17231729Google Scholar
International Dairy Federation (IDF) 1987 Bovine Mastitis. Definition and Guidelines for Diagnosis. Bulletin of the International Dairy Federation. Brussels, Belgium: International Dairy FederationGoogle Scholar
Kaur, M, Verma, R, Bansal, BK, Mukhopadhyay, CS & Arora, JS 2015 Status of subclinical mastitis and associated risk factors in Indian water buffalo in Doaba region of Punjab, India. Indian Journal of Dairy Science 68 3540Google Scholar
Kuczaj, M 2003 Analysis of changes in udder size of high-yielding cows in subsequent lactations with regard to mastitis. Electronic Journal of Polish Agricultural Universities. Series Animal Husbandry 6 25Google Scholar
Mein, GA, Reinemann, DJ, Schuring, N & Ohnstad, I 2004 Milking machines and mastitis risk: a storm in a teatcup. In Proceedings of the 43rd Annual Meeting of the National Mastitis CouncilGoogle Scholar
Mustafa, YS, Farhat, NA & Tooba, Z 2013 Prevalence and antibacterial susceptibility in mastitis in buffalo and cow in district Lahore-Pakistan. Buffalo Bulletin 32 307314Google Scholar
Nakov, D, Hristov, S, Andonov, S & Trajchev, M 2014 Udder-related risk factors for clinical mastitis in dairy cows. Veterinarski Arhiv 84 111127Google Scholar
Nyman, AK, Ekman, T, Emanuelson, U, Gustaffson, AH, Holtenius, K, Person Waller, K & Hallen Sandgren, C 2007 Risk factors associated with the incidence of veterinary-treated clinical mastitis in Swedish dairy herds with a high milk yield and a low prevalence of subclinical mastitis. Preventive Veterinary Medicine 78 142160Google Scholar
Okano, W, Koetz Junior, C & Bogado, ALG 2015 Relationship between shape of teat and teat tip and somatic cell count (SCC) in dairy cows. Acta Scientiae Veterinariae 43 12761281Google Scholar
Porcionato, MADF, Soares, WVB, Reis, CBMD, Cortinhas, CS, Mestieri, L & Santos, MVD 2010 Milk flow, teat morphology and subclinical mastitis prevalence in Gir cows. Pesquisa Agropecuaria Brasileira 45 15071512Google Scholar
Prasad, RMV, Rao, ER, Sudhakar, K, Gupta, BR & Mahender, M 2010 Studies on udder and teat measurements as affected by parity and their relationship with milk yield in Murrah buffaloes. Buffalo Bulletin 29 194198Google Scholar
Rathore, AK 1976 Relationships between teat shape, production and mastitis in Friesian cows. British Veterinary Journal 132 389392Google Scholar
Rogers, GW, Hargrove, GL, Lawlor, TJJ & Ebersole, JL 1991 Correlations among linear type traits and somatic cell counts. Journal of Dairy Science 74 10871091Google Scholar
Seykora, AJ & McDaniel, BT 1985 Udder and teat morphology related to mastitis resistance: a review. Journal of Dairy Science 68 20872093Google Scholar
Sharma, A & Sindhu, N 2007 Occurrence of clinical and sub-clinical mastitis in buffaloes in the State of Haryana (India). Italian Journal of Animal Science 6 965967Google Scholar
Sharma, T, Das, PK, Ghosh, PR, Banerjee, D & Mukherjee, J 2017. Association between udder morphology and in vitro activity of milk leukocytes in high yielding crossbred cows. Veterinary World 10 342347Google Scholar
Singh, RS, Bansal, BK & Gupta, DK 2014 Udder health in relation to udder and teat morphometry in Holstein-Friesian × Sahiwal crossbred dairy cows. Tropical Animal Health Production 46 9398Google Scholar
Slettbakk, T, Jørstad, A, Farver, TB & Holmes, JC 1995 Impact of milking characteristics and morphology of udder and teats on clinical mastitis in first- and second-lactation Norwegian cattle. Preventive Veterinary Medicine 24 235244Google Scholar
Talukder, AA, Rahman, HH, Mahmud, SJM, Alam, F & Dey, SK 2016 Isolation, identification and resistance pattern of microorganisms associated with mastitis in Buffalo. Bangladesh Journal of Microbiology 30 15Google Scholar
Thomas, CS, Svennersten-Sjaunja, K, Bhosrekar, R & Bruckmaier, R 2004 Mammary cistern size, cisternal milk and milk ejection in Murrah buffaloes. Journal of Dairy Research 71 162168Google Scholar
Tilki, M, Inal, S, Colak, M & Garip, M 2005 Relationships between milk yield and udder measurements in Brown Swiss cows. Turkish Journal of Veterinary and Animal Sciences 29 7581Google Scholar
Uppal, SK, Singh, KB, Roy, KS, Nauriyal, DC & Bansal, BK 1994 Natural defense mechanism against mastitis: a comparative histo-morphology of buffalo and cow teat canal. Buffalo Journal 2 125131Google Scholar
Uzmay, C, Kaya, Y, Akbas, Y & Kaya, A 2003 Effects of udder and teat morphology, parity and lactation stage on subclinical mastitis in Holstein cows. Turkish Journal of Veterinary and Animal Science 27 695701Google Scholar
Valde, JP, Lystad, ML, Simensen, E & Osteras, O 2007 Comparison of feeding management and body condition of dairy cows in herds with low and high mastitis rates. Journal of Dairy Science 90 43174324Google Scholar
Weiss, D, Weinfurtner, M & Bruckmaier, RM 2004 Teat anatomy and its relationship with quarter and udder milk flow characteristics in dairy cows. Journal of Dairy Science 87 32803289Google Scholar