Heat stress impact on physiological and behavioral parameters in dairy calves
DOI:
https://doi.org/10.14409/favecv.v19i2.9058Keywords:
heat stress, respiratory rate, rectal temperature, dairy calves, animal welfareAbstract
Among the stress factors to which dairy cattle is exposed heat is one of the most studied due to the impact it has on milk production. However, there is lack of information regarding this stress condition in calves compared to the one related to adult animals. The aim of this paper was to study the relevance of heat stress in dairy calves. For the experiment 246 dairy calves from 19 dairy farms were monitored in days with Temperature Humidity Index (ITH) above 72 between 12:00 pm and 03:00 pm. Heat stress related to ITH was categorized in three degrees: low, moderate and sever stress. Additional information was taken during the visit: shade access, water availability, body position, activity being developed, rectal temperature (TR) and respiratory rate (FR). Data were analyzed using ANOVA. Comparison between median values was analyzed with Tukey´s test (α=0,05) and correlation analysis with Spearman´s test. The software used to analyze statistical data was Infostat version 2019. Differences were found in the body position between animals exposed to sever stress versus those with moderate stress (p=0.0138). However, there were no differences in animal activity in any of the temperature exposures. Results on average rectal temperature (TR) showed differences (p=0.0063) between animals with low stress and those with severe and moderate stress (> 39.2 °C). Relative average of FR was higher (p<0.0001) on calves under sever heat stress, reaching above 80 breaths per minute. The correlation coefficient between ITH and TR was 0.25 (p=0.0001), and between ITH and TR was 0.33 (p<0.0001). Regarding the practices implemented on the farms was noted that 26% of calves did not have shade or water available at the moment data was taken.
References
Adamczyk K, Górecka-Bruzda A, Nowicki J, Gumułka M, Molik E, Schwarz T, Earley B, Klocek C. 2015. Perception of environment in farm animals – A review. Ann. Anim. Sci. 15: 565-589.
Blackshaw JK, Blackshaw AW. 1994. Heat stress in cattle and the effect of shade on production and behaviour. Aust. J. Exp. Agric. 34: 285-295.
Broucek J, Kisac P, Uhrincat, M. 2009. Effect of hot temperatures on the hematological parameters, health and performance of calves. Int. J. Biometeorol. 53: 201-208.
Coleman DA, Moss BR, McCaskey TA. 1996. Supplemental shade for dairy calves reared in commercial calf hutches in a south-ern climate. J. Dairy Sci. 79: 2038-2043.
Dikmen S, Hansen PJ. 2009. Is the temperature-humidity index the best indicator of heat stress in lactating dairy cows in a subtropical environment? J. Dairy Sci. 92: 109-116.
Habeeb AA, Gad AE, Atta MA. 2018. Temperature-Humidity Indices as indicators to heat stress of climatic conditions with relation to production and reproduction of farm animals. Int. J. Biotechnol. Recent. Adv. 1: 5-50.
Johnson HD. 1980. Environmental management of cattle to minimize the stress of climate changes. Int. J. Biometeor. 24: 65-78.
Kovács L, Kézér FL, Ruff F, Jurkovich V, Szenci O. 2018. Assessment of heat stress in 7- week old dairy calves with non-invasive physiological parameters in different thermal environments. PLoS ONE 13: e0200622.
Kovács L, Kézér FL, Bakony M, Jurkovich V, & Szenci O. 2018b. Lying down frequency as a discomfort index in heat stressed Holstein bull calves. Sci. Rep. 8: 15065.
Lima PO, Souza JBF Jr, Lima RN, Oliveira FCS, Domingos HGT, Miranda MV. 2013. Effect of time of day and type of shading on the physiological responses of crossbred calves in tropical environment. J Anim Behav Biometeorol. 1:7-12.
Martínez G, Suárez VH, Ghezzi MD. 2016. Impacto de la relación humano-animal en la productividad y el bienestar animal de los rodeos lecheros. Rev. Arg. Prod. Anim. 36: 75-82.
Nardone A, Ronchi B, Lacetera N, Bernabucci U. 2006. Climatic effects on productive traits in livestock. Vet. Res. Commun. 30: 75-81.
Piccione G, Refinetti R. 2003. Thermal chronobiology of domestic animals. Front. Biosci. 8: 258-264
SIGLeA. 2017. Sistema Integrado de la gestión de la cadena lacteal Argentina. [En línea] https://siglea.magyp.gob.ar/ [Consultado el 28 de julio 2020].
Silanikove N. 2000. Effects of heat stress on the welfare of extensively managed domestic ruminants. Livest. Prod. Sci. 67: 1-8.
Spain JN, Spiers, DE 1996. Effects of supplemental shade on thermoregulatory response of calves to heat challenge on heat environment. J. Dairy Sci. 79: 639-646.
Theurer ME, Anderson DE, White BJ, Miesner MD, Larson RL. 2014.Effects of weather variables on thermoregulation of calves during periods of extreme heat. Am. J. Vet. Res. 75: 296-300.
Thickett, WS, Cuthbert, NH, Brigstock, TDA, Lindeman MA. Wilson, PN. 1981. The management of calves on an early-weaning system: the relationship of voluntary water intake to dry feed intake and live-weight gain to 5 weeks. Anim. Prod. 33: 25-30.
Thom, EC. 1959. The discomfort index. Weatherwise 12: 57-59.
Downloads
Published
Issue
Section
License
FAVE Sección Ciencias Veterinarias ratifies the open access model, in which contents (in full) are available free to anyone in the internet. The costs of production and publication are not transfered to the authors. This policy intends to break social and economical barriers that generate inequities in the access to information, and for the publication of research results.
All articles can be accessed at http://bibliotecavirtual.unl.edu.ar/publicaciones/index.php/FAVEveterinaria/issue/current/, under license Creative CommonsAtribución-NoComercial-Compartir Igual 4.0 Internacional.
