Corn texture and particle size in broiler diets

Benedetti, MP; Sartori, JR; Carvalho, FB; Pereira, LA; Fascina, VB; Stradiotti, AC; Pezzato, AC; Costa, C; Ferreira, JG

doi:10.1590/S1516-635X2011000400002

Abstract

The objective of this study was to evaluate the effect of corn texture and the particle size on broiler performance, carcass yield, nutrient digestibility, and digestive organ morphometrics. In Experiment I, 720 male Cobb chicks were distributed in a completely randomized experimental design with a 2 x 3 factorial arrangement, consisting two corn textures (dented and hard) and three corn particle sizes, was applied, with four replicates of 30 birds each. Corn particle size was classified according to geometric mean diameter (GMD) as fine - 0.46 mm; medium - 0.73 mm, and coarse - 0.87 mm. In Experiment II, 120 broiler chicks were used to evaluate corn digestibility during the periods of 16 to 22 days and 35 to 41 days of age, using the method of total excreta collection. In Experiment I, corn particle size influenced body weight, average weight gain, feed intake and feed conversion ratio of 21-day-old birds. Corn texture and particle size did not affect the performance of 42-day-old broilers or carcass traits. In Experiment II, there was no influence of corn texture and particle size on digestive organ weights. Dented corn increased nitrogen excretion in the first trial, and hard corn improved dry matter digestibility in the second metabolic trial. Corn with fine particle size promotes better performance of broilers at 21 days of age. Hard corn results in higher dry matter digestibility and lower nitrogen excretion, and consequently higher production factor in 42-day-old broilers.

Carcass traits; digestibility; GMD; particle size; performance

Corn texture and particle size in broiler diets

Benedetti MP^I; Sartori JR^II; Carvalho FB^III; Pereira LA^IV; Fascina VB^III; Stradiotti AC^III; Pezzato AC^II; Costa C^II; Ferreira JG^IV

^IM.Sc. student of the Post-Graduation. Program in Animal Science, FMVZ/UNESP - Botucatu. São Paulo. Brazil

^IIProf. Dr. Department of Animal Genetic Improvement and Nutrition, FMVZ/UNESP - Botucatu. São Paulo. Brazil

^IIIPh.D. student of the Post-Graduation Program in Animal Science, FMVZ/UNESP - Botucatu. São Paulo. Brazil

^IVUndergraduate student in Animal Science, FMVZ-UNESP - Botucatu. São Paulo. Brazil

^{Mail Adress}

ABSTRACT

The objective of this study was to evaluate the effect of corn texture and the particle size on broiler performance, carcass yield, nutrient digestibility, and digestive organ morphometrics. In Experiment I, 720 male Cobb chicks were distributed in a completely randomized experimental design with a 2 x 3 factorial arrangement, consisting two corn textures (dented and hard) and three corn particle sizes, was applied, with four replicates of 30 birds each. Corn particle size was classified according to geometric mean diameter (GMD) as fine - 0.46 mm; medium - 0.73 mm, and coarse - 0.87 mm. In Experiment II, 120 broiler chicks were used to evaluate corn digestibility during the periods of 16 to 22 days and 35 to 41 days of age, using the method of total excreta collection. In Experiment I, corn particle size influenced body weight, average weight gain, feed intake and feed conversion ratio of 21-day-old birds. Corn texture and particle size did not affect the performance of 42-day-old broilers or carcass traits. In Experiment II, there was no influence of corn texture and particle size on digestive organ weights. Dented corn increased nitrogen excretion in the first trial, and hard corn improved dry matter digestibility in the second metabolic trial. Corn with fine particle size promotes better performance of broilers at 21 days of age. Hard corn results in higher dry matter digestibility and lower nitrogen excretion, and consequently higher production factor in 42-day-old broilers.

Keywords: Carcass traits, digestibility, GMD, particle size, performance.

INTRODUCTION

Corn is the third most cultivated cereal in the world, following wheat and rice. Brazilian poultry and swine industries use approximately 70 to 80% of locally produced corn. Broiler feeds represent more than two thirds of total broiler production cost, and because corn is used as the main energy feedstuff of broiler feeds, its production and processing strongly influence the profitability of the poultry industry (Lott et al., 1992).

The grain texture is mainly defined by the ratio between vitreous and starchy endosperm (Shull et al., 1990). According to grain characteristics, corn is classified in six classes: dent, flint, flour, popcorn, sweet, and waxy. Most of the corn produced in Brazil is flint corn, whereas in temperate climate, dent corn is predominant. In dent corn, the floury endosperm is concentrated in the central area of the grain, between the tip and the top, with the vitreous endosperm located on the sides and back of the grain. Hard corn has a continuous volume on vitreous endosperm, resulting on smoother and rounder grains, with a hard and vitreous appearance (Paes, 2006).

Corn quality losses caused by the action of insects and fungi have driven researchers to seek varieties with better health characteristics, such as thicker husks and hard and semi-hard grains instead of soft grains (Lima, 2001). However, in feed milling, hard corn requires more energy for grinding and impairs particle-size uniformity. Moreover, higher concentrations of digestive enzymes are required to allow animals to properly digest these grains due to their vitreous characteristics (Silva et al., 2006).

Particle size has a strong influence on feed intake regulation. Poultry, for instance, prefer diets with larger particle sizes as compared to finely-ground feeds (Jensen et al., 1962; Nir et al., 1990; Yo et al., 1997), and the consumption of diets with different particle sized may directly affect their performance and digestive tract morphology (Nir, 1998).

Grinding determines feed particle size, which can range from very fine to very coarse, according to the diameter of the sieve used in the grinder. Therefore, it may be possible to reduce costs by generating more accurate information on corn grinding in order to determine the particle size that allows the best utilization of nutrients by the birds. Coarse corn grinding increase grinder yield in up to 143%, and reduce electric energy consumption in 61%, with no effect on nutrient digestibility and broiler performance (Zanotto et al., 1994).

Nir et al. (1994) observed that young broilers presented better performance when fed grain particles sizes with 0.769 mm geometric mean diameter (GMD). The authors detected that the gizzard of broilers fed finely-ground grains was lighter and gastric pH was higher than in broilers fed larger particles, and argued that broiler performance was influenced by these physiological changes.

Zanotto & Bellaver (1996) suggested that the passage rate of larger particles through the gizzard is slower than that of small particles, and observed that 21-d-old broilers fed diets with GMD of 0.716 and 1.196 mm, presented better performance when fed diets with larger particle size.

The nutritional value of corn ground in hammer mills is usually not affected when its GMD is between 0.500 and 1.000 mm, as shown by some authors (Nir et al., 1994, Magro et al., 2002). However, if corn is too coarse or too fine, birds may not properly utilize corn nutrients. Very fine corn (GMD < 0.400 mm) is mash and/or crumbled feeds may impair feed intake due to the presence of dust, which may cause respiratory disorders, increase water intake, feed presence in the drinkers, and increase litter moisture (Brum et al., 1998).

When evaluating different corn particle sizes (781 950, 1042, 1109, 2242µm) in broiler diets, Parsons et al. (2006) found better feed efficiency and higher feed intake with increasing particle size, whereas weight gain was not affected.

In order to reduce production costs and increase profitability of broiler production, corn particle sizes that allow proper acceptance by the birds, promote the best nutrient digestibility and performance, maintain bird health, and are economically viable should be identified. Particle size has an important influence on broiler performance and production costs, as it directly affects feed intake.

The present study aimed at evaluating the effect of corn texture and particle size on the broiler performance, carcass yield, nutrient digestibility, and intestinal morphometrics.

MATERIALS AND METHODS

Two experiments were carried out in the Faculdade de Medicina Veterinária e Zootecnia, Univ. Estadual Paulista (UNESP), campus de Botucatu, DMNA, Laboratório de Nutrição de Aves, São Paulo, Brazil.

In Experiment I, 720 one-day-old male Cobb broilers were housed in 24 pens measuring 2.5 m² each. Water and feed were supplied ad libitum in bell drinkers, and trough feeders, respectively. A completely randomized experimental design, with a 2 x 3 factorial arrangement, consisting two corn textures (dented and hard) and three corn particle sizes, was applied, with four replicates of 30 birds each. Corn particle size was classified according to geometric mean diameter (GMD) as fine - 0.46 mm; medium - 0.73 mm, and coarse - 0.87 mm. The following corn hybrid varieties were used: AG 4051 for dented texture and DAW 2B 710 for hard texture.

Five sieve sizes were used during milling (4, 6, 8, 10 and 12 mm) to obtain fine, medium and coarse particle sizes of the dented and hard corn, which were determined according to the feedstuff particle size determination method proposed by Zanotto & Bellaver (1996). The 4mm sieve was used to obtain fine GMD hard corn; the 6 mm sieve to obtain fine GMD dented corn; the 8 mm sieve to obtain medium GMD dented and hard corn; the 10 mm sieve to obtain coarse GMD hard corn; and the 10 mm sieve to obtain coarse GMD dented corn. A mil with nine knives measuring eight centimeters each, with a total helix diameter of 26 cm and a 25-cv, 3510-rpm electrical engine, was used.

The experimental feeds were iso-nutritious, and formulated on corn and soybean meal basis. Feedstuff composition and nutritional requirements were obtained from the recommendations of Rostagno et al. (2005) for intermediate-performance male broilers. The feeding schedule was divided in four phases: pre-starter (1-7 days), starter (8-21 days), grower (22-35 days) and finisher (36-42 days) (Table 1).

Thumbnail

Performance data were obtained for the cumulative periods of 1 to 7; 1 to 21 and 1 to 42 days of age. When birds were 42 days of age, five birds per experimental unit were randomly selected, identified, fasted for eight hours, and weighed before slaughter. These birds were submitted to electrical stunning, bled, de-feathered, and eviscerated. The fat in the abdominal cavity and adhered to the gizzard was removed. The carcass with no feet, head, or neck was weighed, and carcass yield was calculated relative to live weight immediately before slaughter. Carcasses were then cut up to determine parts yield (breast, thigh and drumstick, back, and wings) relative to carcass weight. Feet, head+neck, abdominal fat yields were calculated relative to live weight before slaughter. Gizzard relative weight was determined after the removal of the proventriculus.

In Experiment II, 120 male broiler chicks were distributed in a completely randomized experimental design, with a 2 x 3 factorial arrangement, consisting two corn textures (dented and hard) and three corn particle sizes, with four replicates of five and two birds in the first and second metabolism trial, respectively. Birds were housed in metabolic cages and the experimental feeds, which were the same as those supplied in Experiment I, were offered from the first day of age.

The metabolism trials were carried out during the periods of 16 to 22 days of age (starter phase) and 35 to 41 days of age (finisher phase). At the end of each experimental period, one bird per experimental unit was removed to determine organ morphometrics. In the first metabolic trial, birds were housed in galvanized steel battery cages, and in the second trial, they were housed in galvanized steel metabolic cages. Cages were equipped with nipple drinkers and trough feeders in both assays.

The metabolic trials were carried out for seven days, divided in three days for bird adaptation to the cages and to the experimental diets and four days for collection. Excreta were collected twice daily (in the morning and in the evening) using the method of total excreta collection. Excreta collected from the tray placed under each cage were identified and stored in a freezer (-10 ºC) and subsequently homogenized for analyses. Feeds were weighed before supply, and after the four collection days to determine feed intake.

At the end of the collection period, excreta were thawed, homogenized, pre-dried at 65ºC in a forced-ventilation oven for 48 hours, after which they were ground for subsequent laboratory analysis. The coefficient of dry matter digestibility (CDMD) and nitrogen value were determined according to the method proposed by Silva & Queiroz (2002). Total nitrogen contente was determined using the micro-Kjeldahl method. The following equations used to calculate CDMD and nitrogen balance (NB):

NB (g) = N intake - N excretion;

CDMD (%) or NB (%) = [(Nutrient intake - Nutrient excretion) / Nutrient intake] x 100.

At the end of each metabolism trial, one bird per experimental unit was removed, fasted for six hours, weighed, and sacrificed by neck dislocation. The relative weights of proventriculus+gizzard, small intestine, large intestine, pancreas, liver with gall bladder, and small + large intestine length were determined.

Data were submitted to analysis of variance (ANOVA), using the GLM procedure of SAS (1996) statistical package. When necessary, treatment means were compared by the test of Tukey at 5% probability level.

RESULTS AND DISCUSSION

Corn texture influenced (p<0.05) body weight and weight gain of seven-day-old broilers. Those fed dented corn presented higher body weight and weight gain than those fed hard corn (Table 2).

Thumbnail

There was an interaction (p<0.05) between particle size and texture for feed intake and feed conversion ratio at seven days of age (Table 3). When dented corn was used, there was effect of particle sizes on feed intake, whereas when hard corn was fed, the broilers fed fine particle size presented lower feed intake (p<0.05). Also, when fine particle size was used, dented corn promoted higher feed intake than hard corn (p<0.05).

Thumbnail

Out of the broilers fed dented corn, those fed coarse particle size presented worse feed conversion ratio (p<0.05) (Table 3), and when hard corn was fed, the best feed conversion ratio was obtained with fine particle size (p<0.05). As to medium particle size, birds fed hard corn presented the worse feed conversion ratio relative to those receiving dented corn (p<0.05). Corn texture did not influence feed conversion ratio at seven days of age when fine or coarse particle size were fed. Although dented corn promoted higher body weight and weight gain at seven days of age (Table 2), hard corn with fine particle size fine resulted in the lowest feed intake and best feed conversion ratio (Table 3).

Particle size influenced (p<0.05) body weight, weight gain, feed intake and feed conversion ratio (Table 2). Body weight and weight gain of the broilers fed fine particle size were higher than those fed coarse particle size, differently from the findings of Nir et al. (1994), who obtained the best performance in young broilers fed particles with a GMD of 0.769 mm. Feed intake was lower when broilers were fed corn with fine particle size compared with those fed particle medium size. However, birds receiving corn with fine particle size presented better feed conversion ratio than those fed medium or coarse particle size. These results are also opposed to those reported by Deaton et al. (1995), who did not observe any differences in the performance parameters of broiler fed diets with particles sizes of 0.679, 0.987 or 1.289 mm GMD.

The results obtained in the present study when broilers were 21 days of age are consistent with the findings of Zanotto & Bellaver (1996), who observed that 1- to 21-day-old broilers fed diets with corn particles sizes of 0.716 and 1.196 mm GMD presented worse performance than those fed a diet with coarse particle size. Those authors mentioned that large particles promote very slow feed passage in the gizzard, consequently compromising broiler performance.

Factori et al. (2008) concluded that dented corn with a small particle size GMD (0.570 mm) reduced energy use for grinding compared to hard corn, but there was no influence on broiler performance, whereas when corn was ground into coarser particle size (0.865 mm GMD), there was no difference in energy use when grinding hard or dented corn.

The performance of broilers at 42 days of age was not affected by corn texture or particle size (Table 2), except for production factor, with birds fed hard corn presenting better results (p<0.05) relative to those fed dented corn.

Reece et al. (1985), Nir et al. (1990) and Nir et al. (1994) found higher weight gain and feed intake when broilers were fed coarse particles. Lott et al. (1992), working with 3.18 mm and 9.53 mm sieves (GMD = 0.71 mm and 1.17 mm), under temperatures of 15.5 and 26.5 ºC, observed reduced weight gain and increase in feed conversion ratio in the birds fed the largest GMD. Parsons et al. (2006), working with different corn particle sizes (781, 950, 1042, 1109, and 2242 µm) in diets for 22- to 42-day-old broilers, observed higher feed intake and worse feed efficiency when birds were fed coarser corn particles.

There was no effect of corn texture or particle size on the carcass parameters evaluated when birds were 42 days of age (Table 4). Carcass yield was not affected by the experimental treatments, which is consistent with the results of Dahlke et al., (2001) and López & Baião (2002). However, Ribeiro et al. (2002) found that particles coarser than 0.680 mm improved carcass yield, and Parsons et al. (2006) obtained linear reduction of breast yield and linear increase in abdominal fat as corn particle size increased.

Thumbnail

There was an effect (p<0.05) of the interaction between corn texture and particle size on gizzard percentage (Table 5). Independently of corn texture, broilers fed fine particle size presented lower gizzard percentage. As to particle size, when fine particle size was fed, birds fed dented corn presented higher gizzard percentage than those fed hard corn.

Thumbnail

Parsons et al. (2006) observed a linear increase in gizzard percentage as corn particle size increased. Nir et al. (1994) found that gizzard weight of broiler fed finely-ground grains was lower, and their gastric pH higher than those of birds fed coarser particles, and the authors argue that these physiological phenomena influence bird performance. Scholtyssek et al. (1983) and Munt et al. (1995) found that gizzard weight increases about 1% relative to carcass weight when whole cereal grains are fed.

In the study of Dahlke et al. (2001), particle size and feed physical form did not influence carcass yield or leg yield of 42-day-old broilers. The leg yield results obtained in the present study are different from those found by Ribeiro et al. (2002), who used mash diets with particle sizes of 0.337, 0.574, 0.680, 0.778, 0.868, and 0.936 mm and observed lower leg yield when particle size was 0.337 mm.

Corn texture did not influence (p>0.05) organ morphometrics of 22- and 41-day-old broilers (Table 6). However, there was an effect of corn particle size (p<0.05) on the relative weight of the gizzard + proventriculus of 22-day-old birds (Table 6). The broilers fed the fine particle size corn presented reduced gizzard + proventriculus weight (p<0.05), possibly due to the lower activity relative of these organs to the other tested particle sizes, as well as lower liver weight (p<0.05) relative to medium particle size. These results are consistent with the findings of Dahlke et al. (2003), who observed a linear increase in gizzard weight with increasing corn particle size (0.336, 0.585, 0.856, 1.120 mm). Diets with fine particles flow faster from the stomach to the duodenum and other parts of the small intestine. This faster passage produces marked atrophy of the gizzard and discrete hypertrophy of the small intestine (Nir et al., 1994).

Thumbnail

López & Baião (2004) evaluated the physical form of broiler diets, and found lighter livers in birds fed mesh diets as compared with those fed granulated-expanded diets.

There was no influence of corn texture or particle size on the relative weight of the pancreas of 22- or 41-day-old broilers, as opposed to Engberg et al. (2002), who observed that broilers fed mash diets with coarse particle size presented heavier pancreas than those fed mash diets with medium particle size.

There was no interaction (p>0.05) between corn texture and particle size for CDMD, NB, nitrogen intake (NI) or nitrogen excretion (NE) (Table 7). Birds fed dented corn presented the highest nitrogen excretion (p<0.05) (Table 7).

Thumbnail

Corn texture affected CDMD during the period of 38 to 41 days of age, with hard corn promoting higher CDMD relative to dented corn (Table 7). The better CDMD and nitrogen excretion results obtained with hard corn during the period of 38 to 41 days of age may explain the better, although not significant, performance of these birds (Table 2). There was en effect of the interaction between corn texture and particle size on nitrogen excretion during the period of 38 to 41 days of age (p<0.05) (Table 8). Birds fed dented corn with coarse particle size presented higher nitrogen excretion. On the other hand, the particle size of hard corn did not influence nitrogen excretion. Considering medium and coarse particle sizes, dented corn presented higher nitrogen excretion than hard corn. However, when ground to fine particle size, corn texture did not affect nitrogen excretion.

Thumbnail

Cantarelli et al. (2007) observed better nitrogen balance with dented corn relative to hard corn in pigs fed different corn hybrids (high-oil corn, QPM corn, dented corn, semi-dented corn, and hard corn), differently from the results of the present study, indicating different digestibility of corn texture in different animal species. According to Ribeiro et al. (2002), different corn particle sizes (0.337, 0.574, 0.680, 0.778, 0.868 and 0.936 mm GMD) had no effect on nitrogen retention in growing broilers, whereas Parsons et al. (2006) observed a linear increase in nitrogen retention inf 28-day-old broilers fed different corn particle sizes (781, 950, 1042, 1109, 2242 µm).

CONCLUSIONS

Corn with fine particle size promotes better performance of broilers at 21 days of age. Hard corn results in higher dry matter digestibility and lower nitrogen excretion, and consequently higher production factor in 42-day-old broilers.

Mail Adress:

José Roberto Sartori

Departamento de Melhoramento e Nutrição Animal FMVZ, UNESP

18.618-000. Botucatu, SP, Brasil

E-mail: jrsartori@fmvz.unesp.br

Submitted: August/2010

Approved: July/2011

Brum PAR, Zanotto DL, Guidoni AL. Granulometria do milho em rações fareladas e trituradas para frangos de corte: instrução técnica para o avicultor. Concórdia: EMBRAPA-CNPSA;1998. p. 2.
Cantarelli VS, Fialho ET, Sousa RV, Freitas RTF, Lima JAF. Composição química, vitreosidade e digestibilidade de diferentes híbridos de milho para suínos. Ciência Agrotécnica 2007;31(3):860-864.
Dahlke F, Ribeiro AML, Kessler AM, Lima AR. Tamanho da partícula do milho e forma física da ração e seus efeitos sobre o desempenho e rendimento de carcaça de frangos de corte. Brazilian Journal of Poultry Science 2001;3(3):57-64.
Dahlke F, Ribeiro AML, Kessler AM, Lima AR, Maiorka A. Effects of corn particle size and physical form of the diet on the gastrointestinal structures of broiler chickens. Brazilian Journal of Poultry Science 2003;5(1):61-67.
Deaton JW, Lott BD, Branton SL. Corn grind size and broilers reared under two temperature conditions. Journal Applied of Poultry Science 1995;4:402-406.
Engberg RM, Hedemann MS, Jensen BB. The influence of grinding and pelleting of feed on the microbial composition and activity in the digestive tract of broiler chickens. British Poultry Science 2002;43:569-579.
Factori MA, Costa C, Biaggioni MAM, Saleh MAD. Avaliação do consumo de energia elétrica em duas granulometrias de moagem de grãos de milho de textura dentada e dura. Boletim da Indústria Animal 2008;65(2):83-88.
Jensen LS, Merril LH, Reddy CV. Observations on eating patterns and rate of food passage of birds fed pelleted and umpeleted diets. Poultry Science 1962;41:1414-1419.
Lima, GJMM. Milho e subprodutos na alimentação animal. In: Anais do Simpósio sobre ingredientes na alimentação animal;2001 Abr 18-21;Campinas, São Paulo. Brasil. p. 13-32.
López CAA, Baião NC. Efeitos da moagem dos ingredientes e da forma física da ração sobre o desempenho de frangos de corte. Arquivo Brasileiro Medicina Veterinária e Zootecnia 2002;54:189-195.
López CAA, Baião NC. Efeitos do tamanho da partícula e da forma física da ração sobre o desempenho, rendimento de carcaça e peso dos órgãos digestivos de frangos de corte. Arquivo Brasileiro Medicina Veterinária e Zootecnia 2004;56(2):214-221.
Lott BD, Day EJ, Deaton JW. The effect of temperature, dietary energy level and corn particle size on broiler performance. Poultry Science 1992;71:618-624.
Munt RHC, Dingle JG, Sumpa MG. Growth, carcass composition and probability of meat chickens given pellets, mash or free choice diet. British Poultry Science 1995;36:277-284.
Nir I, Melcion JP, Picard M. Effect of particle size of sorghum grains on feed intake and performance of young broilers. Poultry Science 1990;69:2177-2184.
Nir I, Hillel R, Shefet G, Nitzan Z. Effect of grain particle size on performance. 2. Grain texture interctions. Poultry Science 1994;73:781-791.
Nir, I. Resposta de frangos de corte à estrutura alimentar: ingestão de alimentos e trato gatrointestinal. In: Anais do Simpósio Internacional sobre Nutrição de Aves;1998;Campinas, São Paulo. Brasil. p. 49-68.
Paes MCD. Aspectos Físicos, Químicos e Tecnológicos do Grão de Milho. Embrapa Milho e Sorgo, Circular Técnica 75 2006;12:6.
Parsons AS, Buchanan NP, Blemings KP, Wilson ME, Moritz JS. Effect of corn particle size and pellet texture on broiler performance in growing phase. Journal Applied of Poultry Research 2006;15:245-255.
Reece FN, Lott BD, Deaton JW. The effects of of feed form, grinding methodo, energy level and gender on broiler performance in a moderate (21 şC) environment. Poultry Science 1985;64:1834-1839.
Ribeiro AML, Magro N, Penz Jr. AM. Granulometria do milho em rações de crescimento de frangos de corte e seu efeito no desempenho e metabolismo. Brazilian Journal of Poultry Science 2002;4(1):47-53.
Rostagno HS, Albino LFT, Donzele JL, Gomes PC, Oliveira RF, Lopes DC, Ferreira AS, Barreto SLT. Tabelas brasileiras para aves e suínos: composição de alimentos e exigências nutricionais. Viçosa: UFV;2005. 186p.
Sas Institute. SAS/STAT. User's guide. Version 6.11. 4^th ed. Cary; 1996. v.2, 842 p.
Scholtyssek S, Seeman M, Seeman G. Mastleistung und schlachtkorperqualitat nach wahlfutterung von broilern (I. Mittillung). Ark. Geflugelk 1983;47:166-174.
Shull JM, Chandrasheka A, Kirleis AW, Ejeta G. Development of sorghum (Sorghum bicolor (L.) Moench) endosperm in varieties of varying hardness. Food Structure 1990;9(3):253-267.
Silva DJ, Queiroz AC. Análise de alimentos: métodos químicos e biológicos. 3ed. Viçosa: Editora UFV;2002. 235p.
Silva MMA, Furlan AC, Moreira I, Paiano D, Jobim CC, Barcellos LCG. Avaliação nutricional do milho com maior teor de óleo, nas formas de grãos secos e silagens, para suínos nas fases de crescimento e terminação. Revista Brasileira de Zootecnia 2006;35(3):830-839.
Yo T, Siegel PB, Guerin H. Self-selection of dietary protein and energy by broilers grown under a tropical climate: effects of feed particle size on the feed choice. Poultry Science 1997;76:1446-1473.
Zanotto DL, Albino LFT, Brum P. Efeito do grau de moagem no valor energético do milho para frangos de corte. Resumos da Reunião Anual da Sociedade Brasileira de Zootecnia;1994; Maringá, Paraná. Brasil: SBZ. p. 57.
Zanotto DL, Bellaver C. Método de determinação da granulometria para uso em rações de suínos e aves. Concórdia: EMBRAPA, CNPSA; 1996. 5 p.

Publication Dates

Publication in this collection
28 Feb 2012
Date of issue
Dec 2011

History

Received
Aug 2010
Accepted
July 2011

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] Brum PAR, Zanotto DL, Guidoni AL. Granulometria do milho em rações fareladas e trituradas para frangos de corte: instrução técnica para o avicultor. Concórdia: EMBRAPA-CNPSA;1998. p. 2.

[2] Cantarelli VS, Fialho ET, Sousa RV, Freitas RTF, Lima JAF. Composição química, vitreosidade e digestibilidade de diferentes híbridos de milho para suínos. Ciência Agrotécnica 2007;31(3):860-864.

[3] Dahlke F, Ribeiro AML, Kessler AM, Lima AR. Tamanho da partícula do milho e forma física da ração e seus efeitos sobre o desempenho e rendimento de carcaça de frangos de corte. Brazilian Journal of Poultry Science 2001;3(3):57-64.

[4] Dahlke F, Ribeiro AML, Kessler AM, Lima AR, Maiorka A. Effects of corn particle size and physical form of the diet on the gastrointestinal structures of broiler chickens. Brazilian Journal of Poultry Science 2003;5(1):61-67.

[5] Deaton JW, Lott BD, Branton SL. Corn grind size and broilers reared under two temperature conditions. Journal Applied of Poultry Science 1995;4:402-406.

[6] Engberg RM, Hedemann MS, Jensen BB. The influence of grinding and pelleting of feed on the microbial composition and activity in the digestive tract of broiler chickens. British Poultry Science 2002;43:569-579.

[7] Factori MA, Costa C, Biaggioni MAM, Saleh MAD. Avaliação do consumo de energia elétrica em duas granulometrias de moagem de grãos de milho de textura dentada e dura. Boletim da Indústria Animal 2008;65(2):83-88.

[8] Jensen LS, Merril LH, Reddy CV. Observations on eating patterns and rate of food passage of birds fed pelleted and umpeleted diets. Poultry Science 1962;41:1414-1419.

[9] Lima, GJMM. Milho e subprodutos na alimentação animal. In: Anais do Simpósio sobre ingredientes na alimentação animal;2001 Abr 18-21;Campinas, São Paulo. Brasil. p. 13-32.

[10] López CAA, Baião NC. Efeitos da moagem dos ingredientes e da forma física da ração sobre o desempenho de frangos de corte. Arquivo Brasileiro Medicina Veterinária e Zootecnia 2002;54:189-195.

[11] López CAA, Baião NC. Efeitos do tamanho da partícula e da forma física da ração sobre o desempenho, rendimento de carcaça e peso dos órgãos digestivos de frangos de corte. Arquivo Brasileiro Medicina Veterinária e Zootecnia 2004;56(2):214-221.

[12] Lott BD, Day EJ, Deaton JW. The effect of temperature, dietary energy level and corn particle size on broiler performance. Poultry Science 1992;71:618-624.

[13] Munt RHC, Dingle JG, Sumpa MG. Growth, carcass composition and probability of meat chickens given pellets, mash or free choice diet. British Poultry Science 1995;36:277-284.

[14] Nir I, Melcion JP, Picard M. Effect of particle size of sorghum grains on feed intake and performance of young broilers. Poultry Science 1990;69:2177-2184.

[15] Nir I, Hillel R, Shefet G, Nitzan Z. Effect of grain particle size on performance. 2. Grain texture interctions. Poultry Science 1994;73:781-791.

[16] Nir, I. Resposta de frangos de corte à estrutura alimentar: ingestão de alimentos e trato gatrointestinal. In: Anais do Simpósio Internacional sobre Nutrição de Aves;1998;Campinas, São Paulo. Brasil. p. 49-68.

[17] Paes MCD. Aspectos Físicos, Químicos e Tecnológicos do Grão de Milho. Embrapa Milho e Sorgo, Circular Técnica 75 2006;12:6.

[18] Parsons AS, Buchanan NP, Blemings KP, Wilson ME, Moritz JS. Effect of corn particle size and pellet texture on broiler performance in growing phase. Journal Applied of Poultry Research 2006;15:245-255.

[19] Reece FN, Lott BD, Deaton JW. The effects of of feed form, grinding methodo, energy level and gender on broiler performance in a moderate (21 şC) environment. Poultry Science 1985;64:1834-1839.

[20] Ribeiro AML, Magro N, Penz Jr. AM. Granulometria do milho em rações de crescimento de frangos de corte e seu efeito no desempenho e metabolismo. Brazilian Journal of Poultry Science 2002;4(1):47-53.

[21] Rostagno HS, Albino LFT, Donzele JL, Gomes PC, Oliveira RF, Lopes DC, Ferreira AS, Barreto SLT. Tabelas brasileiras para aves e suínos: composição de alimentos e exigências nutricionais. Viçosa: UFV;2005. 186p.

[22] Sas Institute. SAS/STAT. User's guide. Version 6.11. 4^th ed. Cary; 1996. v.2, 842 p.

[23] Scholtyssek S, Seeman M, Seeman G. Mastleistung und schlachtkorperqualitat nach wahlfutterung von broilern (I. Mittillung). Ark. Geflugelk 1983;47:166-174.

[24] Shull JM, Chandrasheka A, Kirleis AW, Ejeta G. Development of sorghum (Sorghum bicolor (L.) Moench) endosperm in varieties of varying hardness. Food Structure 1990;9(3):253-267.

[25] Silva DJ, Queiroz AC. Análise de alimentos: métodos químicos e biológicos. 3ed. Viçosa: Editora UFV;2002. 235p.

[26] Silva MMA, Furlan AC, Moreira I, Paiano D, Jobim CC, Barcellos LCG. Avaliação nutricional do milho com maior teor de óleo, nas formas de grãos secos e silagens, para suínos nas fases de crescimento e terminação. Revista Brasileira de Zootecnia 2006;35(3):830-839.

[27] Yo T, Siegel PB, Guerin H. Self-selection of dietary protein and energy by broilers grown under a tropical climate: effects of feed particle size on the feed choice. Poultry Science 1997;76:1446-1473.

[28] Zanotto DL, Albino LFT, Brum P. Efeito do grau de moagem no valor energético do milho para frangos de corte. Resumos da Reunião Anual da Sociedade Brasileira de Zootecnia;1994; Maringá, Paraná. Brasil: SBZ. p. 57.

[29] Zanotto DL, Bellaver C. Método de determinação da granulometria para uso em rações de suínos e aves. Concórdia: EMBRAPA, CNPSA; 1996. 5 p.