Your search keyword '"high ambient-temperatures"' showing total 7 results

1. Effect of floor cooling on farrowing sow and litter performance: Field experiment under Dutch conditions

Subjects

Research, pigs, systems, swine, lactation, preference, Wageningen Livestock Research, high ambient-temperatures, Onderzoek

Abstract

Lactating sows generally have problems dissipating their body heat to the environment. Cooling the floor under the sow¿s shoulder, called the cool-sow system, is a method to increase body heat removal by conduction, thereby contributing to the thermal comfort of the sow. In this study, the effect of the cool-sow system on the performance of the sow and her piglets in the farrowing room and on the position of the sow in the farrowing crate was determined. In total, 60 sows (parity between 2 and 5) were included in the study. One room with 12 pens was used during five batches in autumn, spring, and summer. During each batch, the floors were cooled in six randomly chosen pens, while the other six pens were used as reference pens. The sows on the cool-sow system had 0.6 kg higher average daily feed intake (P

Published

2006

2. Effects of increasing temperatures on physiological changes in pigs at different relative humidities

Subjects

Animal Nutrition, behavior, AFSG Agrisystems & Environment, heat-production, growing-pigs, swine, Agrotechnology and Food Sciences, Agrotechnologie en Levensmiddelentechnologie, Diervoeding, stress, WIAS, Adaptation Physiology, Adaptatiefysiologie, high ambient-temperatures

Abstract

The effects of relative humidity (RH) and high ambient temperature (T) on physiological responses and animal performance were studied using 12 groups (10 gilts per group) in pens inside respiration chambers. The microclimate in the chamber was programmed so that T remained constant within a day. Each day, the T was increased by 2°C from low (16°C) to high (32°C). Relative humidity was kept constant at 50, 65, or 80%. The pigs¿ average initial BW was 61.7 kg (58.0 to 65.5 kg), and their average ending BW was 70.2 kg (65.9 to 74.7 kg). Respiration rate (RR), evaporative water (EW), rectal temperature (RT), skin temperature (ST), voluntary feed intake (VFI), water-to-feed ratio (rW:F), heat production (HP), and ADG were analyzed. The animals had free access to feed and water. We determined the T above which certain animal variables started to change: the so-called inflection point temperature (IPt) or "upper critical temperature." The first indicator of reaction, RR, was in the range from 21.3 to 23.4°C. Rectal temperature was a delayed indicator of heat stress tolerance, with IPt values ranging from 24.6 to 27.1°C. For both these indicators the IPt was least at 80% RH (P

Published

2005

3. Robustness to chronic heat stress in laying hens: a meta-analysis

Author

Michèle Tixier-Boichard, Tatiana Zerjal, Agnès Narcy, T.B. Rodenburg, U. Moreri, Sandrine Mignon-Grasteau, X. Rousseau, Recherches Avicoles (SRA), Institut National de la Recherche Agronomique (INRA), AgroParisTech, WUR Animal Breeding and Genomics Group, Wageningen University and Research Centre [Wageningen] (WUR), Génétique Animale et Biologie Intégrative (GABI), AgroParisTech-Institut National de la Recherche Agronomique (INRA), Gallus Futurus, Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Behavioural Ecology Group, Unité de Recherches Avicoles (URA), Wageningen University and Research [Wageningen] (WUR), World's Poultry Science Association (WPSA). INT., and Mignon-Grasteau, Sandrine

Subjects

stress thermique, [SDV.SA]Life Sciences [q-bio]/Agricultural sciences, production d'oeufs, food.ingredient, Genotype, qualité des oeufs, [SDV]Life Sciences [q-bio], egg quality, Animal Breeding and Genomics, Biology, Heat Stress Disorders, Behavioral Ecology, food, Animal science, Residual sum of squares, Yolk, méta analyse, Animals, Fokkerij en Genomica, gene, dwarf, oeuf de poule, Naked Neck, Reproduction, Age Factors, Temperature, Robustness (evolution), General Medicine, poule pondeuse, Stress factor, Housing, Animal, robustesse, Heat stress, Gedragsecologie, nutrition, Meta-analysis, supplementation, WIAS, naked neck, Trait, Female, Animal Science and Zoology, vitamin-c, Chickens, management, performance, high ambient-temperatures

Abstract

Chronic heat is a major stress factor in laying hens and many studies on the effect of heat stress have been published. It remains difficult, however, to draw general conclusions about the effect of chronic heat stress on performance and its relationship with genetic and environmental factors, as these studies have been done under varying experimental conditions and using various experimental designs. A meta-analysis enabled us to make a quantitative review of the results from 131 published papers. The relative effects of four factors (genotype, age, group size, and amplitude of temperature variation) and their interactions with temperature were analyzed for 13 traits. After pre-correcting the data for a random study effect, the best model for each trait was selected in a step-wise procedure based on its residual sum of squares. Shell strength, daily feed intake, egg mass, and hen-day egg production were found to be more sensitive to heat stress than the other traits as they dropped by 9.0 to 22.6% between thermo-neutrality (15 to 20 degrees C) and heat stress (30 to 35 degrees C) while yolk and albumen proportions or Haugh units showed nearly no variation with temperature (

Published

2015

4. Robustness to chronic heat stress in laying hens: a meta-analysis

Author

Mignon-Grasteau, S., Moreri, U., Narcy, A., Rousseau, X., Rodenburg, T.B., Tixier-Boichard, M., Zerjal, T., Mignon-Grasteau, S., Moreri, U., Narcy, A., Rousseau, X., Rodenburg, T.B., Tixier-Boichard, M., and Zerjal, T.

Abstract

Chronic heat is a major stress factor in laying hens and many studies on the effect of heat stress have been published. It remains difficult, however, to draw general conclusions about the effect of chronic heat stress on performance and its relationship with genetic and environmental factors, as these studies have been done under varying experimental conditions and using various experimental designs. A meta-analysis enabled us to make a quantitative review of the results from 131 published papers. The relative effects of four factors (genotype, age, group size, and amplitude of temperature variation) and their interactions with temperature were analyzed for 13 traits. After pre-correcting the data for a random study effect, the best model for each trait was selected in a stepwise procedure based on its residual sum of squares. Shell strength, daily feed intake, egg mass, and hen-day egg production were found to be more sensitive to heat stress than the other traits as they dropped by 9.0 to 22.6% between thermo-neutrality (15 to 20°C) and heat stress (30 to 35°C) while yolk and albumen proportions or Haugh units showed nearly no variation with temperature (

Published

2015

5. Effect of floor cooling on farrowing sow and litter performance: Field experiment under Dutch conditions

Author

G.P. Binnendijk, A. V. van Wagenberg, C. M. C. van der Peet-Schwering, and P. J. P. W. Claessen

Subjects

Litter (animal), Food intake, Waste management, Field experiment, Research, Biomedical Engineering, Soil Science, pigs, Forestry, swine, lactation, Crate, Heat stress, Animal science, systems, Animal behavior, preference, Agronomy and Crop Science, Wageningen Livestock Research, Food Science, Mathematics, high ambient-temperatures, Onderzoek

Abstract

Lactating sows generally have problems dissipating their body heat to the environment. Cooling the floor under the sow's shoulder, called the cool-sow system, is a method to increase body heat removal by conduction, thereby contributing to the thermal comfort of the sow. In this study, the effect of the cool-sow system on the performance of the sow and her piglets in the farrowing room and on the position of the sow in the farrowing crate was determined. In total, 60 sows (parity between 2 and 5) were included in the study. One room with 12 pens was used during five batches in autumn, spring, and summer. During each batch, the floors were cooled in six randomly chosen pens, while the other six pens were used as reference pens. The sows on the cool-sow system had 0.6 kg higher average daily feed intake (P < 0.001). These sow's piglets grew 20 g per day per piglet faster (P < 0.001). There was no effect on the loss of bodyweight of the sow or on piglet mortality. The sows on the cool-sow system showed a higher feed intake during all five batches, not only during summer batches. Sow position and location in the crate was hardly affected by the cool-sow system. The cool-sow system removed on average 107 W of heat per pen, of which approximately 58 W was directly removed from the sow's body.

Published

2006

6. Effects of increasing temperatures on physiological changes in pigs at different relative humidities

Author

Huynh Thi Thanh Thuy, Aarnink, A.J.A., Verstegen, M.W.A., Gerrits, W.J.J., Heetkamp, M.J.W., Kemp, B., and Canh, T.T.

Subjects

Animal Nutrition, behavior, AFSG Agrisystems & Environment, heat-production, growing-pigs, swine, Agrotechnology and Food Sciences, Agrotechnologie en Levensmiddelentechnologie, Diervoeding, stress, WIAS, Adaptation Physiology, Adaptatiefysiologie, high ambient-temperatures

Abstract

The effects of relative humidity (RH) and high ambient temperature (T) on physiological responses and animal performance were studied using 12 groups (10 gilts per group) in pens inside respiration chambers. The microclimate in the chamber was programmed so that T remained constant within a day. Each day, the T was increased by 2°C from low (16°C) to high (32°C). Relative humidity was kept constant at 50, 65, or 80%. The pigs¿ average initial BW was 61.7 kg (58.0 to 65.5 kg), and their average ending BW was 70.2 kg (65.9 to 74.7 kg). Respiration rate (RR), evaporative water (EW), rectal temperature (RT), skin temperature (ST), voluntary feed intake (VFI), water-to-feed ratio (rW:F), heat production (HP), and ADG were analyzed. The animals had free access to feed and water. We determined the T above which certain animal variables started to change: the so-called inflection point temperature (IPt) or "upper critical temperature." The first indicator of reaction, RR, was in the range from 21.3 to 23.4°C. Rectal temperature was a delayed indicator of heat stress tolerance, with IPt values ranging from 24.6 to 27.1°C. For both these indicators the IPt was least at 80% RH (P

Published

2005

7. Effect of floor cooling on farrowing sow and litter performance: Field experiment under Dutch conditions

Author

van Wagenberg, A.V., van der Peet-Schwering, C.M.C., Binnendijk, G.P., Claessen, P.J.P.W., van Wagenberg, A.V., van der Peet-Schwering, C.M.C., Binnendijk, G.P., and Claessen, P.J.P.W.

Abstract

Lactating sows generally have problems dissipating their body heat to the environment. Cooling the floor under the sow¿s shoulder, called the cool-sow system, is a method to increase body heat removal by conduction, thereby contributing to the thermal comfort of the sow. In this study, the effect of the cool-sow system on the performance of the sow and her piglets in the farrowing room and on the position of the sow in the farrowing crate was determined. In total, 60 sows (parity between 2 and 5) were included in the study. One room with 12 pens was used during five batches in autumn, spring, and summer. During each batch, the floors were cooled in six randomly chosen pens, while the other six pens were used as reference pens. The sows on the cool-sow system had 0.6 kg higher average daily feed intake (P <0.001). These sow¿s piglets grew 20 g per day per piglet faster (P <0.001). There was no effect on the loss of bodyweight of the sow or on piglet mortality. The sows on the cool-sow system showed a higher feed intake during all five batches, not only during summer batches. Sow position and location in the crate was hardly affected by the cool-sow system. The cool-sow system removed on average 107 W of heat per pen, of which approximately 58 W was directly removed from the sow¿s body.

Published

2006