Effects of Heat-Stress on Production in Dairy Cattle

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Effects of Heat-Stress on Production in Dairy Cattle

J. W. West

Animal and Dairy Science Department, University of Georgia Coastal Plain Experiment Station, Tifton 31793-0748

Corresponding author
J. W. West; e-mail:
jwest{at}tifton.uga.edu.

The southeastern United States is characterized as humid subtropicaland is subject to extended periods of high ambient temperatureand relative humidity. Because the primary nonevaporative meansof cooling for the cow (radiation, conduction, convection) becomeless effective with rising ambient temperature, the cow becomesincreasingly reliant upon evaporative cooling in the form ofsweating and panting. High relative humidity compromises evaporativecooling, so that under hot, humid conditions common to the Southeastin summer the dairy cow cannot dissipate sufficient body heatto prevent a rise in body temperature. Increasing air temperature,temperature-humidity index and rising rectal temperature abovecritical thresholds are related to decreased dry matter intake(DMI) and milk yield and to reduced efficiency of milk yield.Modifications including shade, barns which enhance passive ventilation,and the addition of fans and sprinklers increase body heat loss,lowering body temperature and improving DMI. New technologiesincluding tunnel ventilation are being investigated to determineif they offer cooling advantages. Genetic selection for heattolerance may be possible, but continued selection for greaterperformance in the absence of consideration for heat tolerancewill result in greater susceptibility to heat stress. The nutritionalneeds of the cow change during heat stress, and ration reformulationto account for decreased DMI, the need to increase nutrientdensity, changing nutrient requirements, avoiding nutrient excessesand maintenance of normal rumen function is necessary. Maintainingcow performance in hot, humid climatic conditions in the futurewill likely require improved cooling capability, continued advancesin nutritional formulation, and the need for genetic advancementwhich includes selection for heat tolerance or the identificationof genetic traits which enhance heat tolerance.

Key Words: dairy • heat stress • environment • lactation

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