Heat tolerance, thermal equilibrium and environmental management strategies for dairy cows living in intertropical regions

Severino Guilherme Caetano Gonçalves Dos Santos; Edilson Paes Saraiva; Severino Gonzaga Neto; Maria Isabelly Leite Maia; Angela M Lees; Verassamy Sejian; Alex Sandro Campos Maia; Geovergue Rodrigues de Medeiros; Vinícius de França Carvalho Fonsêca

doi:10.3389/fvets.2022.988775

Heat tolerance, thermal equilibrium and environmental management strategies for dairy cows living in intertropical regions

Front Vet Sci. 2022 Nov 16:9:988775. doi: 10.3389/fvets.2022.988775. eCollection 2022.

Authors

Severino Guilherme Caetano Gonçalves Dos Santos¹, Edilson Paes Saraiva², Severino Gonzaga Neto³, Maria Isabelly Leite Maia², Angela M Lees⁴, Verassamy Sejian⁵, Alex Sandro Campos Maia⁶, Geovergue Rodrigues de Medeiros¹, Vinícius de França Carvalho Fonsêca^{6

7}

Affiliations

¹ Department of Animal Production, National Institute of Semiarid (INSA), Campina Grande, Brazil.
² Research Group in Bioclimatology, Behavior and Animal Welfare (BIOET), Department of Animal Science, Federal University of Paraiba (UFPB), Areia, Brazil.
³ Research Group in Cattle Farming (GEABOV), Department of Animal Science, Federal University of Paraiba (UFPB), Areia, Brazil.
⁴ School of Agriculture and Food Sciences, Animal Science Group, The University of Queensland, Gatton, QLD, Australia.
⁵ Rajiv Gandhi Institute of Veterinary Education and Research (RIVER), Kurumbapet, India.
⁶ Innovation in Thermal Comfort and Animal Welfare (INOBIO-MANERA), São Paulo State University, Jaboticabal, Brazil.
⁷ Brain Function Research Group, School of Physiology, University of the Witwatersrand, Johannesburg, South Africa.

Abstract

This review makes an attempt to characterize the physical attributes of heat tolerance, thermal equilibrium and thermal stress thresholds for dairy cows living in tropical environments, with a particular emphasis on pasture-based systems. Under such circumstances, the radiant heat load is the principal climatic factor that determines rates of heat and mass exchanges between cows and the environment. This fact may explain why simple mechanistic models based on air temperature and humidity are not adequately predicting thermal stress thresholds for cattle in tropical regions. To overcome this limitation, the Index of Thermal Stress for Cows (ITSC) and Index for the time spent in shade (ITS), which account for various sources of thermal radiation, were proposed to predict autonomous and behavioral thermoregulation of cows. Overall, the evolutionary adaptation of cattle in tropics favored animals that have cutaneous surface with a skin well protected against penetration of ultraviolet solar radiation (UV), covered by a coat surface with high thermal conductivity. For Holstein breed, although predominantly black animals absorb greater levels of short-wave solar radiation, they may present better protection of skin than white ones. However, dark-colored cows in tropical pastures have potential to absorb as much as 640 W m^-2 of thermal radiation. This amount of heat load would require close to 1,300 g h ^-1 of cutaneous evaporative water loss through sweating to prevent increases to body temperature, where cows do not have access to shade. Cows are motivated to reduce time spent grazing and to seek shade when solar irradiance exceeds 550 W m^-2, levels that in equatorial latitudes are likely to occur between 08:00 and 16:00h. This information may help producers improve the welfare of cows, as they can determine more comfortable hours for them to graze, for example, by employing nocturnal grazing. Over the daytime, cows should have access to areas with shade and this could include shade provided via solar panels, which has the potential to improve thermal comfort and sustainability of dairy production in tropical areas.

Keywords: dairy cows; evolutionary adaptation; solar radiation; thermal equilibrium; thermoregulation.

Publication types

Review