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Effects of sequential feeding with low- and high-protein diets on growth performances and plasma metabolite levels in geese

Published online by Cambridge University Press:  05 January 2015

S.-Y. Ho
Affiliation:
Department of Animal Science and Biotechnology, Tunghai University, 40704 Taichung, Taiwan
Y.-H. Chen
Affiliation:
Department of Animal Science and Biotechnology, Tunghai University, 40704 Taichung, Taiwan
S.-K. Yang*
Affiliation:
Department of Animal Science and Biotechnology, Tunghai University, 40704 Taichung, Taiwan
*
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Abstract

This study was conducted by two trials to investigate effects of sequential feeding with low- and high-protein diets on growth traits and plasma metabolites in geese. In Trial I, the effect of sequential feeding under time-restricted feeding system was investigated. Seventy-two White Roman goslings were randomly allotted into either sequential feeding (S1) or control feeding (C1) group. All goslings were fed for 1 h at morning and at evening, respectively, from 2 to 8 weeks of age. S1 group was offered 13% CP diet at morning and 19% CP diet at evening. C1 group was offered the same diet (16% CP; mixed equally with the two diets mentioned above) at both morning and evening. Blood samples were hourly collected for 4 h after feeding at both morning and evening for the determination of the postprandial plasma levels of glucose, triacylglycerol and uric acid at the end of experiment. Results showed that BW, average daily gain (ADG), and daily feed intake (FI) were not different between groups, but the feed efficiency (FE) in S1 group was significantly higher than that in C1 group (P<0.05). The areas under curve (AUC) of plasma postprandial levels of glucose, triacylglycerol and uric acid were not affected by treatment, but the AUC of triacylglycerol and uric acid in morning were lower than those in evening (P<0.05). In Trial II, the effect of sequential feeding under ad libitum feeding system was investigated. Twenty-four goslings were randomly allotted into either sequential feeding (S2) or control feeding (C2) group. Diets were altered at 0600 and 1800 h, respectively, and geese were fed ad libitum from 4 to 8 weeks of age. S2 group was offered 14% CP diet at morning and 20% CP diet at evening. C2 group was supplied the same diet (mixed with the two diets according to the ratio of diets consumed by S2 group on the preceded day) at both morning and evening. Results showed that the ADG in S2 group was higher than those in C2 group (P<0.05). Summarized data from both trials showed that sequential feeding improves daily gain and FE in growing geese.

Type
Research Article
Copyright
© The Animal Consortium 2015 

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References

Arnal, MA, Mosoni, L, Dardevet, D, Ribeyre, MC, Bayle, G, Prugnaud, J and Mirand, PP 2002. Pulse protein feeding pattern restores stimulation of muscle protein synthesis during the feeding period in old rats. Journal of Nutrition 132, 10021008.Google Scholar
Arnal, MA, Mosoni, L, Boirie, Y, Houlier, ML, Morin, L, Verdier, E, Ritz, P, Antoine, JM, Prugnaud, J, Beaufrere, B and Mirand, PP 1999. Protein pulse feeding improves protein retention in elderly women. The American Journal of Clinical Nutrition 69, 12021208.Google Scholar
Arnal, MA, Mosoni, L, Boirie, Y, Houlier, ML, Morin, L, Verdier, E, Ritz, P, Antoine, JM, Prugnaud, J, Beaufrere, B and Mirand, PP 2000a. Protein feeding pattern does not affect protein retention in young women. Journal of Nutrition 130, 17001704.Google Scholar
Arnal, MA, Mosoni, L, Boirie, Y, Gachon, P, Genest, M, Bayle, G, Grizard, J, Arnal, M, Antoine, JM, Beaufrere, B and Mirand, PP 2000b. Protein turnover modifications induced by the protein feeding pattern still persist after the end of the diets. American Journal of Physiology (Endocrinology and Metabolism) 278, E902E909.Google Scholar
Bouvarel, I, Barrier-Guillot, B, Larroude, P, Boutten, B, Leterrier, C, Merlet, F, Vilarino, M, Roffidal, L, Tesseraud, S, Castaing, J and Picard, M 2004. Sequential feeding programs for broiler chickens: twenty-four- and forty-eight-hour cycles. Poultry Science 83, 4960.Google Scholar
Chu, HH 2012. Effect of photoperiod on feeding, growth traits and metabolism in geese. Thesis Master, Tunghai University, Taichung, Taiwan.Google Scholar
De Basilio, V, Vilarino, M, Yahav, S and Picard, M 2001. Early age thermal conditioning and a dual feeding program for male broilers challenged by heat stress. Poultry Science 80, 2936.Google Scholar
Ho, S-Y, Wu, Y-C, Chen, Y-H and Yang, S-K 2014. The effects of feeding time and time-restricted feeding on the fattening traits of White Roman geese. Animal 8, 395400.Google Scholar
Keshavarz, K 1998. Further investigations on the effects of dietary manipulation of protein, phosphorus, and calcium for reducing the daily requirement of laying hens. Poultry Science 77, 13331347.Google Scholar
Koopmans, SJ, van der Meulen, J, Dekker, R, Corbijn, H and Mroz, Z 2005. Diurnal rhythms in plasma cortisol, insulin, glucose, lactate and urea in pigs fed identical meals at 12-hourly intervals. Physiology and Behavior 84, 497503.Google Scholar
Koopmans, SJ, van der Meulen, J, Dekker, R, Corbijn, H and Mroz, Z 2006. Diurnal variation in insulin-stimulated systemic glucose and amino acid utilization in pigs fed with identical meals at 12-hour intervals. Hormone and Metabolic Research 38, 607613.CrossRefGoogle ScholarPubMed
Lui, ZJ, Chu, HH, Wu, YC and Yang, SK 2014. Effect of two-step time-restricted feeding on the fattening traits in geese. Asian-Australasian Journal of Animal Sciences 27, 841846.CrossRefGoogle ScholarPubMed
Lin, MJ, Chang, SC, Wu, KC, Chen, TF, Jea, TS, Lee, SR and Fan, YK 2007. Feeding value of green napiergrass and nilegrass supplement to diets for White Roman geese. Journal of the Chinese Society of Animal Science 36, 231242.Google Scholar
Lozano, C, De Basilio, V, Oliveros, I, Alvarez, R, Colina, I, Bastianelli, D, Yahav, S and Picard, M 2006. Is sequential feeding a suitable technique to compensate for the negative effects of a tropical climate in finishing broilers? Animal Research 55, 7176.Google Scholar
Morgan, M, Hampton, S, Gibbs, M and Arendt, J 2003. Circadian aspects of postprandial metabolism. Chronobiology International 20, 795808.CrossRefGoogle ScholarPubMed
Morgan, LM, Arendt, J, Owens, D, Folkard, S, Hampton, SM, Deacon, S, English, J, Ribeiro, D and Taylor, K 1998. Effects of the endogenous clock and sleep time on melatonin, insulin, glucose and lipid metabolism. Journal of Endocrinology 157, 443451.Google Scholar
Penz, AM Jr and Jensen, LS 1991. Influence of dietary protein concentration, amino acid supplementation, and daily time of access to high- and low-protein diets on egg weight and egg components in laying hens. Poultry Science 70, 24602466.CrossRefGoogle Scholar
Sirri, F and Meluzzi, A 2012. Effect of sequential feeding on nitrogen excretion, productivity, and meat quality of broiler chickens. Poultry Science 91, 316321.Google Scholar
Umar Faruk, M, Bouvarel, I, Même, N, Roffidal, L, Tukur, HM, Nys, Y and Lescoat, P 2010a. Adaptation of wheat and protein-mineral concentrate intakes by individual hens fed ad libitum in sequential or in loose-mix systems. British Poultry Science 51, 811820.Google Scholar
Umar Faruk, M, Bouvarel, I, Mallet, S, Ali, MN, Tukur, HM, Nys, Y and Lescoat, P 2011. Is sequential feeding of whole wheat more efficient than ground wheat in laying hens? Animal 5, 230238.Google Scholar
Umar Faruk, M, Bouvarel, I, Même, N, Rideau, N, Roffidal, L, Tukur, HM, Bastianelli, D, Nys, Y and Lescoat, P 2010b. Sequential feeding using whole wheat and a separate protein-mineral concentrate improved feed efficiency in laying hens. Poultry Science 89, 785796.CrossRefGoogle Scholar