Hostname: page-component-669899f699-tpknm Total loading time: 0 Render date: 2025-04-27T05:20:17.073Z Has data issue: false hasContentIssue false
  • English
  • Français

Measurement of heat stress conditions at cow level and comparison to climate conditions at stationary locations inside a dairy barn

Published online by Cambridge University Press:  07 September 2016

Laura K Schüller  and
Wolfgang Heuwieser
Laura K Schüller
Affiliation:
Clinic for Animal Reproduction, Faculty of Veterinary Medicine, Freie Universität Berlin, Koenigsweg 65, 14163 Berlin, Germany
Wolfgang Heuwieser*
Affiliation:
Clinic for Animal Reproduction, Faculty of Veterinary Medicine, Freie Universität Berlin, Koenigsweg 65, 14163 Berlin, Germany
*
*For correspondence; e-mail: w.heuwieser@fu-berlin.de
Get access Rights & Permissions [Opens in a new window]

Abstract

The objectives of this study were to examine heat stress conditions at cow level and to investigate the relationship to the climate conditions at 5 different stationary locations inside a dairy barn. In addition, we compared the climate conditions at cow level between primiparous and multiparous cows for a period of 1 week after regrouping. The temperature-humidity index (THI) differed significantly between all stationary loggers. The lowest THI was measured at the window logger in the experimental stall and the highest THI was measured at the central logger in the experimental stall. The THI at the mobile cow loggers was 2·33 THI points higher than at the stationary loggers. Furthermore, the mean daily THI was higher at the mobile cow loggers than at the stationary loggers on all experimental days. The THI in the experimental pen was 0·44 THI points lower when the experimental cow group was located inside the milking parlour. The THI measured at the mobile cow loggers was 1·63 THI points higher when the experimental cow group was located inside the milking parlour. However, there was no significant difference for all climate variables between primiparous and multiparous cows. These results indicate, there is a wide range of climate conditions inside a dairy barn and especially areas with a great distance to a fresh air supply have an increased risk for the occurrence of heat stress conditions. Furthermore, the heat stress conditions are even higher at cow level and cows not only influence their climatic environment, but also generate microclimates within different locations inside the barn. Therefore climate conditions should be obtained at cow level to evaluate the heat stress conditions that dairy cows are actually exposed to.

Keywords

Heat stresscow levelclimate datatemperature-humidity indexdairy barn
Type
Research Article
Information
Journal of Dairy Research , Volume 83 , Issue 3 , August 2016 , pp. 305 - 311
Copyright
Copyright © Proprietors of Journal of Dairy Research 2016 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Article purchase

Temporarily unavailable

References

Beilharz, RG & Zeeb, K 1982 Social dominance in dairy cattle. Applied Animal Ethology 8 7997 Google Scholar
Berman, A, Folman, Y, Kaim, M, Mamen, M, Herz, Z, Wolfenson, D, Arieli, A & Graber, Y 1985 Upper critical temperatures and forced ventilation effects for high-yielding dairy cows in a subtropical climate. Journal of Dairy Science 68 14881495 Google Scholar
Bickert, WG & Stowell, RR 1993 Design and operation of natural ventilation systems in dairy freestall barns. In Livestock Environment IV. Proc. Fourth Int. Livestock Env. Symp. ASAE, St. Joseph, MI, pp. 970977 Google Scholar
Brantas, GC 1967 On the dominance order in Friesian-Dutch dairy cows. Journal of Animal Breeding and Genetics 84 127151 Google Scholar
Brügemann, K, Gernand, E, von Borstel, UU & König, S 2011 Genetic analyses of protein yield in dairy cows applying random regression models with time-dependent and temperature x humidity-dependent covariates. Journal of Dairy Science 94 41294139 CrossRefGoogle ScholarPubMed
Chen, JM, Schütz, KE & Tucker, CB 2013 Dairy cows use and prefer feed bunks fitted with sprinklers. Journal of Dairy Science 96 50355045 Google Scholar
Chen, JM, Schütz, KE & Tucker, CB 2016 Cooling cows efficiently with water spray: behavioral, physiological, and production responses to sprinklers at the feed bunk. Journal of Dairy Science 99 46074618 CrossRefGoogle ScholarPubMed
Coimbra, PAD, Machado Filho, LCP & Hötzel, MJ 2012 Effects of social dominance, water trough location and shade availability on drinking behaviour of cows on pasture. Applied Animal Behaviour Science 139 175182 CrossRefGoogle Scholar
Collier, RJ, Dahl, GE & VanBaale, MJ 2006 Major advances associated with environmental effects on dairy cattle. Journal of Dairy Science 89 12441253 Google Scholar
DeVries, TJ, von Keyserlingk, MAG & Weary, DM 2004 Effect of feeding space on the inter-cow distance, aggression, and feeding behavior of free-stall housed lactating dairy cows. Journal of Dairy Science 87 14321438 Google Scholar
Dikmen, S & Hansen, PJ 2009 Is the temperature-humidity index the best indicator of heat stress in lactating dairy cows in a subtropical environment? Journal of Dairy Science 92 109116 CrossRefGoogle Scholar
Dohoo, IR, Martin, SW & Stryhn, H 2009 Veterinary Epidemiologic Research. Charlottetown, PEI, Canada: University of Prince Edward Island Google Scholar
Fiedler, M, Berg, W, Ammon, C, Loebsin, C, Sanftleben, P, Samer, M, von Bobrutzki, K, Kiwan, A & Saha, CK 2013 Air velocity measurements using ultrasonic anemometers in the animal zone of a naturally ventilated dairy barn. Biosystems Engineering 116 276285 Google Scholar
García-Ispierto, I, López-Gatius, F, Bech-Sabat, G, Santolaria, P, Yániz, JL, Nogareda, C, De Rensis, F & López-Béjar, M 2007 Climate factors affecting conception rate of high producing dairy cows in northeastern Spain. Theriogenology 67 13791385 Google Scholar
Gorniak, T, Meyer, U, Sudekum, KH & Danicke, S 2014 Impact of mild heat stress on dry matter intake, milk yield and milk composition in mid-lactation Holstein dairy cows in a temperate climate. Archives of Animal Nutrition 68 358369 Google Scholar
Hammami, H, Bormann, J, M'Hamdi, N, Montaldo, HH & Gengler, N 2013 Evaluation of heat stress effects on production traits and somatic cell score of Holsteins in a temperate environment. Journal of Dairy Science 96 18441855 Google Scholar
Hasegawa, N, Nishiwaki, A, Sugawara, K & Ito, I 1997 The effects of social exchange between two groups of lactating primiparous heifers on milk production, dominance order, behavior and adrenocortical response. Applied Animal Behaviour Science 51 1527 Google Scholar
Hill, DL & Wall, E 2015 Dairy cattle in a temperate climate: the effects of weather on milk yield and composition depend on management. Animal: an International Journal of Animal Bioscience 9 138149 Google Scholar
Honig, H, Miron, J, Lehrer, H, Jackoby, S, Zachut, M, Zinou, A, Portnick, Y & Moallem, U 2012 Performance and welfare of high-yielding dairy cows subjected to 5 or 8 cooling sessions daily under hot and humid climate. Journal of Dairy Science 95 37363742 Google Scholar
Huzzey, JM, DeVries, TJ, Valois, P & von Keyserlingk, MAG 2006 Stocking density and feed barrier design affect the feeding and social behavior of dairy cattle. Journal of Dairy Science 89 126133 Google Scholar
Janni, K & Stowell, R 2000 Building environment. In Dairy Freestall Housing and Equipment, pp. 7590 (Ed. Bickert, WG, Holmes, B, Janni, K, Kammel, D, Stowell, R & Zulovich, J). Ames, USA: Iowa State University Google Scholar
Kondo, S & Hurnik, JF 1990 Stabilization of social hierarchy in dairy cows. Applied Animal Behaviour Science 27 287297 Google Scholar
Lobeck-Luchterhand, KM, Silva, PRB, Chebel, RC & Endres, MI 2015 Effect of stocking density on social, feeding, and lying behavior of prepartum dairy animals. Journal of Dairy Science 98 240249 CrossRefGoogle ScholarPubMed
National Research Council NRC 1971 A Guide to Environmental Research on Animals. Washington, DC, USA: National Academies Google Scholar
Ortiz, XA, Smith, JF, Rojano, F, Choi, CY, Bruer, J, Steele, T, Schuring, N, Allen, J & Collier, RJ 2015 Evaluation of conductive cooling of lactating dairy cows under controlled environmental conditions. Journal of Dairy Science 98 17591771 Google Scholar
Phillips, CJC & Rind, MI 2001 The effects on production and behavior of mixing uniparous and multiparous cows. Journal of Dairy Science 84 24242429 Google Scholar
Phillips, CJC & Rind, MI 2002 The effects of social dominance on the production and behavior of grazing dairy cows offered forage supplements. Journal of Dairy Science 85 5159 Google Scholar
Ravagnolo, O, Misztal, I & Hoogenboom, G 2000 Genetic component of heat stress in dairy cattle, development of heat index function. Journal of Dairy Science 83 21202125 Google Scholar
Robinson, JB, Ames, DR & Milliken, GA 1986 Heat-production of cattle acclimated to cold, thermoneutrality and heat when exposed to thermoneutrality and heat-stress. Journal of Animal Science 62 14341440 Google Scholar
Schein, MW & Fohrman, MH 1955 Social dominance relationships in a herd of dairy cattle. The British Journal of Animal Behaviour 3 4555 Google Scholar
Schirmann, K, Chapinal, N, Weary, DM, Heuwieser, W & von Keyserlingk, MAG 2011 Short-term effects of regrouping on behavior of prepartum dairy cows. Journal of Dairy Science 94 23122319 Google Scholar
Schüller, LK, Burfeind, O & Heuwieser, W 2013 Short communication: comparison of ambient temperature, relative humidity, and temperature-humidity index between on-farm measurements and official meteorological data. Journal of Dairy Science 96 77317738 Google Scholar
Schüller, LK, Burfeind, O & Heuwieser, W 2014 Impact of heat stress on conception rate of dairy cows in the moderate climate considering different temperature-humidity index thresholds, periods relative to breeding, and heat load indices. Theriogenology 81 10501057 Google Scholar
Schütz, KE, Rogers, AR, Cox, NR, Webster, JR & Tucker, CB 2011 Dairy cattle prefer shade over sprinklers: effects on behavior and physiology. Journal of Dairy Science 94 273283 Google Scholar
Schütz, KE, Cox, NR & Tucker, CB 2014 A field study of the behavioral and physiological effects of varying amounts of shade for lactating cows at pasture. Journal of Dairy Science 97 35993605 Google Scholar
Silanikove, N 2000 Effects of heat stress on the welfare of extensively managed domestic ruminants. Livestock Production Science 67 118 Google Scholar
Smith, DL, Smith, T, Rude, BJ & Ward, SH 2013 Short communication: comparison of the effects of heat stress on milk and component yields and somatic cell score in Holstein and Jersey cows. Journal of Dairy Science 96 30283033 Google Scholar
Teye, FK, Hautala, M, Pastell, M, Praks, J, Veermäe, I, Poikalainen, V, Pajumägi, A, Kivinen, T & Ahokas, J 2008 Microclimate and ventilation in Estonian and Finnish dairy buildings. Energy and Buildings 40 11941201 CrossRefGoogle Scholar
Villa-Mancera, A, Mendez-Mendoza, M, Huerta-Crispin, R, Vazquez-Flores, F & Cordova-Izquierdo, A 2011 Effect of climate factors on conception rate of lactating dairy cows in Mexico. Tropical Animal Health and Production 43 597601 Google Scholar
von Keyserlingk, MAG, Olenick, D & Weary, DM 2008 Acute behavioral effects of regrouping dairy cows. Journal of Dairy Science 91 10111016 CrossRefGoogle ScholarPubMed
Wagner-Storch, AM & Palmer, RW 2002 Day and night seasonal temperature differences for a naturally ventilated freestall barn with different stocking densities. Journal of Dairy Science 85 35343538 Google Scholar
Wiersma, FA, D 1983 Cooling Cattle in the Holding Pen. St. Joseph, Michigan: American Society of Agricultural Engineers Google Scholar