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Roles of dietary fibre and ingredient particle size in broiler nutrition

Published online by Cambridge University Press:  28 March 2018

S.K. KHERAVII
Affiliation:
Animal Science, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia Animal Production, Faculty of Agriculture and Forestry, University of Duhok, 42003, Kurdistan region, Iraq
N.K. MORGAN
Affiliation:
Animal Science, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia
R.A. SWICK
Affiliation:
Animal Science, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia
M. CHOCT
Affiliation:
Animal Science, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia
S.-B. WU*
Affiliation:
Animal Science, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia
*
Corresponding author: shubiao.wu@une.edu.au
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Abstract

Increasing the structural components in the diet, namely through including coarse grain particles in diets and manipulating the dietary fibre composition, has been shown to improve gut health, feed utilisation and production efficiency. This is primarily because structural components physically stimulate activity in the fore gut. An example of this is dietary non-starch polysaccharides (NSP), namely insoluble NSP, which have been shown to instigate beneficial effects on gut health, litter quality and nutrient utilisation, by increasing crop and gizzard activity, stimulating digestive enzyme production and enhancing bacterial fermentation in the hind gut. However, there is a lack of consistency with regard to the direct effects of dietary fibre on chicken health and production. The aim of this review therefore is to explore the impact of feeding different sources of fibre and different size grain particles on gut health and microflora, nutrient utilisation, performance and litter quality in broilers.

Type
Review
Copyright
Copyright © World's Poultry Science Association 2018 

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References

ABDOLLAHI, M., RAVINDRAN, V., WESTER, T., RAVINDRAN, G. and THOMAS, D. (2011) Influence of feed form and conditioning temperature on performance, apparent metabolisable energy and ileal digestibility of starch and nitrogen in broiler starters fed wheat-based diet. Animal Feed Science and Technology 168: 88-99.Google Scholar
AFSHARMANESH, M. and POURREZA, J. (2005) Effects of calcium, citric acid, ascorbic acid, vitamin d 3 on the efficacy of microbial phytase in broiler starters fed wheat-based diets i. Performance, bone mineralization and ileal digestibility. International Journal of Poultry Science 4: 418-424.Google Scholar
AMERAH, A.M. (2008) Feed particle size, whole wheat inclusion and xylanase supplementation in broiler diets: Influence on the performance, digesta characteristics and digestive tract development. Massey University.Google Scholar
AMERAH, A., RAVINDRAN, V., LENTLE, R. and THOMAS, D. (2007a) Feed particle size: Implications on the digestion and performance of poultry. World's Poultry Science Journal 63: 439-455.Google Scholar
AMERAH, A.M., RAVINDRAN, V., LENTLE, R.G. and THOMAS, D.G. (2007b) Influence of feed particle size and feed form on the performance, energy utilization, digestive tract development, and digesta parameters of broiler starters. Poultry Science 86: 2615-2623.Google Scholar
AMERAH, A.M., RAVINDRAN, V., LENTLE, R.G. and THOMAS, D.G. (2008) Influence of feed particle size on the performance, energy utilization, digestive tract development, and digesta parameters of broiler starters fed wheat- and corn-based diets. Poultry Science 87: 2320-2328.CrossRefGoogle ScholarPubMed
ANNETT, C., VISTE, J., CHIRINO-TREJO, M., CLASSEN, H., MIDDLETON, D. and SIMKO, E. (2002) Necrotic enteritis: Effect of barley, wheat and corn diets on proliferation of clostridium perfringens type a. Avian Pathology 31: 598-601.Google Scholar
AUDISIO, M.C., OLIVER, G. and APELLA, M.C. (2000) Protective effect of enterococcus faecium j96, a potential probiotic strain, on chicks infected with salmonella pullorum. Journal of Food Protection 63: 1333-1337.Google Scholar
BAURHOO, B., FERKET, P. and ZHAO, X. (2009a) Effects of diets containing different concentrations of mannanoligosaccharide or antibiotics on growth performance, intestinal development, cecal and litter microbial populations, and carcass parameters of broilers. Poultry Science 88: 2262-2272.Google Scholar
BAURHOO, B., GOLDFLUS, F. and ZHAO, X. (2009b) Purified cell wall of saccharomyces cerevisiae increases protection against intestinal pathogens in broiler chickens. International Journal of Poultry Science 8: 133-137.Google Scholar
BAURHOO, B., LETELLIER, A., ZHAO, X. and RUIZ-FERIA, C. (2007) Cecal populations of lactobacilli and bifidobacteria and escherichia coli populations after in vivo escherichia coli challenge in birds fed diets with purified lignin or mannanoligosaccharides. Poultry Science 86: 2509-2516.Google Scholar
BEDFORD, M. and COWIESON, A. (2012) Exogenous enzymes and their effects on intestinal microbiology. Animal Feed Science and Technology 173: 76-85.CrossRefGoogle Scholar
BELLEY, A., KELLER, K., GÖTTKE, M., CHADEE, K. and GÖETTKE, M. (1999) Intestinal mucins in colonization and host defense against pathogens. The American Journal of Tropical Medicine and Hygiene 60: 10-15.Google Scholar
BIGGS, P. and PARSONS, C. (2009) The effects of whole grains on nutrient digestibilities, growth performance, and cecal short-chain fatty acid concentrations in young chicks fed ground corn-soybean meal diets. Poultry Science 88: 1893-1905.Google Scholar
BOGUSŁAWSKA-TRYK, M., SZYMECZKO, R., PIOTROWSKA, A., BURLIKOWSKA, K. and ŚLIŻEWSKA, K. (2015) Ileal and cecal microbial population and short-chain fatty acid profile in broiler chickens fed diets supplemented with lignocellulose. Pakistan Veterinary Journal 35: 212-216.Google Scholar
BRAKE, J., BOYLE, C., CHAMBLEE, T., SCHULTZ, C. and PEEBLES, E. (1992) Evaluation of the chemical and physical properties of hardwood bark used as a broiler litter material. Poultry Science 71: 467-472.Google Scholar
BRANTON, S.L., LOTT, B.D., DEATON, J.W., MASLIN, W.R., AUSTIN, F.W., POTE, L.M., KEIRS, R.W., LATOUR, M.A. and DAY, E.J. (1997) The effect of added complex carbohydrates or added dietary fiber on necrotic enteritis lesions in broiler chickens. Poultry Science 76: 24-28.Google Scholar
CALIXTO, J.B., CAMPOS, M.M., OTUKI, M.F. and SANTOS, A.R. (2004) Anti-inflammatory compounds of plant origin. Part ii. Modulation of pro-inflammatory cytokines, chemokines and adhesion molecules. Planta Medica 70: 93-103.Google Scholar
CAO, B., ZHANG, X., GUO, Y., KARASAWA, Y. and KUMAO, T. (2003) Effects of dietary cellulose levels on growth, nitrogen utilization, retention time of diets in digestive tract and caecal microflora of chickens. Asian Australasian Journal of Animal Sciences 16: 863-866.Google Scholar
CARRÉ, B., IDI, A., MAISONNIER, S., MELCION, J.-P., OURY, F.-X., GOMEZ, J. and PLUCHARD, P. (2002) Relationships between digestibilities of food components and characteristics of wheats (triticum aestivum) introduced as the only cereal source in a broiler chicken diet. British Poultry Science 43: 404-415.Google Scholar
CHANDRA, R. and LIDDLE, R.A. (2009) Neural and hormonal regulation of pancreatic secretion. Current Opinion in Gastroenterology 25: 441.Google Scholar
CHERRINGTON, C., HINTON, M., MEAD, G. and CHOPRA, I. (1991) Organic acids: Chemistry, antibacterial activity and practical applications. Advances in Microbial Physiology 32: 87-108.Google Scholar
CHEWNING, C., STARK, C. and BRAKE, J. (2012) Effects of particle size and feed form on broiler performance. The Journal of Applied Poultry Research 21: 830-837.Google Scholar
CHOCT, M. (1997) Feed non-starch polysaccharides: Chemical structures and nutritional significance. Feed milling international 191: 13-26.Google Scholar
CHOCT, M. (2009) Managing gut health through nutrition. British Poultry Science 50: 9-15.Google Scholar
CHOCT, M. and ANNISON, G. (1992) The inhibition of nutrient digestion by wheat pentosans. British Journal of Nutrition 67: 123-132.Google Scholar
CHOCT, M., HUGHES, R., WANG, J., BEDFORD, M., MORGAN, A. and ANNISON, G. (1996) Increased small intestinal fermentation is partly responsible for the anti-nutritive activity of non-starch polysaccharides in chickens. British Poultry Science 37: 609-621.Google Scholar
CLARK, P., BEHNKE, K. and FAHRENHOLZ, A. (2009) Effects of feeding cracked corn and concentrate protein pellets on broiler growth performance. The Journal of Applied Poultry Research 18: 259-268.CrossRefGoogle Scholar
CLASSEN, H. (1996) Cereal grain starch and exogenous enzymes in poultry diets. Animal Feed Science and Technology 62: 21-27.CrossRefGoogle Scholar
CLASSEN, H., APAJALAHTI, J., SVIHUS, B. and CHOCT, M. (2016) The role of the crop in poultry production. World's Poultry Science Journal 72: 459-472.Google Scholar
CUMMING, R. (1994) Opportunities for whole grain feeding. Proceedings of the 9th European poultry conference (Worlds Poultry Science Association: Glasgow, UK), pp. 219-222.Google Scholar
DAHIYA, J., WILKIE, D., VAN KESSEL, A. and DREW, M. (2006) Potential strategies for controlling necrotic enteritis in broiler chickens in post-antibiotic era. Animal Feed Science and Technology 129: 60-88.Google Scholar
DE JONG, I.C., GUNNINK, H. and VAN HARN, J. (2014) Wet litter not only induces footpad dermatitis but also reduces overall welfare, technical performance, and carcass yield in broiler chickens. The Journal of Applied Poultry Research 23: 51-58.CrossRefGoogle Scholar
DEN BESTEN, G., VAN EUNEN, K., GROEN, A.K., VENEMA, K., REIJNGOUD, D.-J. and BAKKER, B.M. (2013) The role of short-chain fatty acids in the interplay between diet, gut microbiota, and host energy metabolism. Journal of Lipid Research 54: 2325-2340.CrossRefGoogle ScholarPubMed
DUNLOP, M.W., MCAULEY, J., BLACKALL, P.J. and STUETZ, R.M. (2016b) Water activity of poultry litter: Relationship to moisture content during a grow-out. Journal of Environmental Management 172: 201-206.Google Scholar
DUNLOP, M.W., MOSS, A.F., GROVES, P.J., WILKINSON, S.J., STUETZ, R.M. and SELLE, P.H. (2016a) The multidimensional causal factors of ‘wet litter’ in chicken-meat production. Science of the Total Environment 562: 766-776.Google Scholar
EDWARDS, C., JOHNSON, I. and READ, N. (1988) Do viscous polysaccharides slow absorption by inhibiting diffusion or convection? European Journal of Clinical Nutrition 42: 307-312.Google Scholar
ENGBERG, R.M., HEDEMANN, M.S. and JENSEN, B.B. (2002) The influence of grinding and pelleting of feed on the microbial composition and activity in the digestive tract of broiler chickens. British Poultry Science 43: 569-579.CrossRefGoogle ScholarPubMed
FARRAN, M., PIETSCH, M. and CHABRILLAT, T. (2013) Effect of lignocellulose on the litter quality and the ready to cook carcass yield of male broilers. Actes des 10èmes Journées de la Recherche Avicole et Palmipèdes à Foie Gras du 26 au 28 mars, 2013, La Rochelle, France: 917-921.Google Scholar
FULLER, R. (2001) The chicken gut microflora and probiotic supplements. The Journal of Poultry Science 38: 189-196.Google Scholar
GABRIEL, I., MALLET, S. and LECONTE, M. (2003) Differences in the digestive tract characteristics of broiler chickens fed on complete pelleted diet or on whole wheat added to pelleted protein concentrate. British Poultry Science 44: 283-290.Google Scholar
GUPTA, N., MARTIN, P.M., PRASAD, P.D. and GANAPATHY, V. (2006) Slc5a8 (smct1)-mediated transport of butyrate forms the basis for the tumor suppressive function of the transporter. Life Sciences 78: 2419-2425.Google Scholar
GUYARD-NICODÈME, M., KEITA, A., QUESNE, S., AMELOT, M., POEZEVARA, T., LE BERRE, B., SÁNCHEZ, J., VESSEUR, P., MARTÍN, Á. and MEDEL, P. (2015) Efficacy of feed additives against campylobacter in live broilers during the entire rearing period. Poultry Science 95: 298-305.Google Scholar
HAMILTON, R. and PROUDFOOT, F. (1995) Ingredient particle size and feed texture: Effects on the performance of broiler chickens. Animal Feed Science and Technology 51: 203-210.Google Scholar
HETLAND, H. and SVIHUS, B. (2007) Inclusion of dust bathing materials affects nutrient digestion and gut physiology of layers. The Journal of Applied Poultry Research 16: 22-26.Google Scholar
HETLAND, H., SVIHUS, B. and CHOCT, M. (2005) Role of insoluble fiber on gizzard activity in layers. The Journal of Applied Poultry Research 14: 38-46.Google Scholar
HILL, K. (1971) The physiology of digestion. Physiology and biochemistry of the domestic fowl 1: 25-49.Google Scholar
HINTON, A. (Jr), CORRIER, D.E., SPATES, G.E., NORMAN, J.O., ZIPRIN, R.L., BEIER, R.C. and DELOACH, J.R. (1990) Biological control of salmonella typhimurium in young chickens. Avian Diseases 34: 626-633.Google Scholar
HOOPER, L.V., MIDTVEDT, T. and GORDON, J.I. (2002) How host-microbial interactions shape the nutrient environment of the mammalian intestine. Annual Review of Nutrition 22: 283-307.Google Scholar
HUSSEIN, S.M., YOKHANA, J.S. and FRANKEL, T.L. (2017) Supplementing the feeds of layer pullets, at different ages with two different fiber sources improves immune function. Poultry Science 96: 2718-2727.Google Scholar
JACOBS, C., UTTERBACK, P. and PARSONS, C. (2010) Effects of corn particle size on growth performance and nutrient utilization in young chicks. Poultry Science 89: 539-544.Google Scholar
JAMROZ, D., JAKOBSEN, K., KNUDSEN, K.E.B., WILICZKIEWICZ, A. and ORDA, J. (2002) Digestibility and energy value of non-starch polysaccharides in young chickens, ducks and geese, fed diets containing high amounts of barley. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 131: 657-668.CrossRefGoogle ScholarPubMed
JENSEN, M., COX, R. and JENSEN, B.B. (1995) Microbial production of skatole in the hind gut of pigs given different diets and its relation to skatole deposition in backfat. Animal Science 61: 293-304.Google Scholar
JIA, W., SLOMINSKI, B., BRUCE, H., BLANK, G., CROW, G. and JONES, O. (2009) Effects of diet type and enzyme addition on growth performance and gut health of broiler chickens during subclinical clostridium perfringens challenge. Poultry Science 88: 132-140.Google Scholar
JIMÉNEZ-MORENO, E., CHAMORRO, S., FRIKHA, M., SAFAA, H., LÁZARO, R. and MATEOS, G. (2011a) Effects of increasing levels of pea hulls in the diet on productive performance, development of the gastrointestinal tract, and nutrient retention of broilers from one to eighteen days of age. Animal Feed Science and Technology 168: 100-112.CrossRefGoogle Scholar
JIMÉNEZ-MORENO, E., DE COCA-SINOVA, A., GONZÁLEZ-ALVARADO, J. and MATEOS, G. (2016) Inclusion of insoluble fiber sources in mash or pellet diets for young broilers. 1. Effects on growth performance and water intake. Poultry Science 95: 41-52.CrossRefGoogle ScholarPubMed
JIMÉNEZ-MORENO, E., FRIKHA, M., DE COCA-SINOVA, A., GARCÍA, J. and MATEOS, G.G. (2013a) Oat hulls and sugar beet pulp in diets for broilers 1. Effects on growth performance and nutrient digestibility. Animal Feed Science and Technology 182: 33-43.Google Scholar
JIMÉNEZ-MORENO, E., FRIKHA, M., DE COCA-SINOVA, A., LÁZARO, R.P. and MATEOS, G.G. (2013b) Oat hulls and sugar beet pulp in diets for broilers. 2. Effects on the development of the gastrointestinal tract and on the structure of the jejunal mucosa. Animal Feed Science and Technology 182: 44-52.Google Scholar
JIMENEZ-MORENO, E., GONZALEZ-ALVARADO, J.M., GONZALEZ-SANCHEZ, D., LAZARO, R. and MATEOS, G. G. (2010) Effects of type and particle size of dietary fiber on growth performance and digestive traits of broilers from 1 to 21 days of age. Poultry Science 89: 2197-2212.Google Scholar
JIMÉNEZ MORENO, E., ROMERO, C., BERROCOSO, J., FRIKHA, M. and GONZALEZ MATEOS, G. (2011b) Effects of the inclusion of oat hulls or sugar beet pulp in the diet on gizzard characteristics, apparent ileal digestibility of nutrients, and microbial count in the ceca in 36 day old broilers reared on floor. Poultry Science 90 (Suppl. 1): 153 (Abstract).Google Scholar
JOERGER, R. (2003) Alternatives to antibiotics: Bacteriocins, antimicrobial peptides and bacteriophages. Poultry Science 82: 640-647.Google Scholar
JOHNSON, I. and GEE, J.M. (1981) Effect of gel-forming gums on the intestinal unstirred layer and sugar transport in vitro. Gut 22: 398-403.Google Scholar
JOZEFIAK, D., RUTKOWSKI, A., JENSEN, B.B. and ENGBERG, R.M. (2007) Effects of dietary inclusion of triticale, rye and wheat and xylanase supplementation on growth performance of broiler chickens and fermentation in the gastrointestinal tract. Animal Feed Science and Technology 132: 79-93.Google Scholar
JÓZEFIAK, D., RUTKOWSKI, A. and MARTIN, S. (2004) Carbohydrate fermentation in the avian ceca: A review. Animal Feed Science and Technology 113: 1-15.Google Scholar
JUNG, S., HOUDE, R., BAURHOO, B., ZHAO, X. and LEE, B. (2008) Effects of galacto-oligosaccharides and a bifidobacteria lactis-based probiotic strain on the growth performance and fecal microflora of broiler chickens. Poultry Science 87: 1694-1699.Google Scholar
KAWAGUCHI, K., KIKUCHI, S.-I., HASUNUMA, R., MARUYAMA, H., YOSHIKAWA, T. and KUMAZAWA, Y. (2004) A citrus flavonoid hesperidin suppresses infection-induced endotoxin shock in mice. Biological and Pharmaceutical Bulletin 27: 679-683.Google Scholar
KHEMPAKA, S., MOLEE, W. and GUILLAUME, M. (2009) Dried cassava pulp as an alternative feedstuff for broilers: Effect on growth performance, carcass traits, digestive organs, and nutrient digestibility. The Journal of Applied Poultry Research 18: 487-493.CrossRefGoogle Scholar
KHERAVII, S., SWICK, R., CHOCT, M. and WU, S.-B. (2017a) Potential of pelleted wheat straw as an alternative bedding material for broilers. Poultry Science 96: 1641-1647.CrossRefGoogle ScholarPubMed
KHERAVII, S., SWICK, R., CHOCT, M. and WU, S.-B. (2017b) Coarse particle inclusion and lignocellulose-rich fiber addition in feed benefit performance and health of broiler chickens. Poultry Science 96: 3272-3281.Google Scholar
KHERAVII, S., SWICK, R., CHOCT, M. and WU, S.-B. (2018b) Upregulated proventricular pepsinogens and improved feed efficiency in broilers by the combination of supplemented sugarcane bagasse and coarsely ground corn in pelleted diets. Proceedings of the 28th Australian Poultry Science Symposium.Google Scholar
KHERAVII, S., SWICK, R., CHOCT, M. and WU, S. (2018a) Nutrient digestibility response to sugarcane bagasse addition and corn particle size in normal and high na diets for broilers. Poultry Science: doi: 10.3382/ps/pex403.Google Scholar
KHERAVII, S.K., SWICK, R.A., CHOCT, M. and WU, S.-B. (2017c) Dietary sugarcane bagasse and coarse particle size of corn are beneficial to performance and gizzard development in broilers fed normal and high sodium diets. Poultry Science 96: 4006-4016.Google Scholar
KHERAVII, S.K., SWICK, R.A., CHOCT, M. and WU, S.-B. (2017e) Sugarcane bagasse upregulates the expression of pancreatic amylase and chymotrypsin of broilers fed corn-based diets. Proceedings of the Recent advances in animal nutrition, University of New England, Australia, pp. xvii-xviii.Google Scholar
KIM, G.-B., SEO, Y., KIM, C. and PAIK, I. (2011) Effect of dietary prebiotic supplementation on the performance, intestinal microflora, and immune response of broilers. Poultry Science 90: 75-82.Google Scholar
KIMIAEITALAB, M., CÁMARA, L., GOUDARZI, S.M., JIMÉNEZ-MORENO, E. and MATEOS, G. (2017) Effects of the inclusion of sunflower hulls in the diet on growth performance and digestive tract traits of broilers and pullets fed a broiler diet from zero to 21 d of age. A comparative study. Poultry Science 96: 581-592.Google Scholar
LAN, Y., VERSTEGEN, M., TAMMINGA, S. and WILLIAMS, B. (2005) The role of the commensal gut microbial community in broiler chickens. World's Poultry Science Journal 61: 95-104.Google Scholar
LANGHOUT, P. (2000) New additives for broiler chickens. World Poultry 16: 22-27.Google Scholar
LENTLE, R.G., RAVINDRAN, V., RAVINDRAN, G. and THOMAS, D.V. (2006) Influence of feed particle size on the efficiency of broiler chickens fed wheat-based diets. The Journal of Poultry Science 43: 135-142.Google Scholar
LEUNG, H., ARRAZOLA, A., TORREY, S. and KIARIE, E. (2018) Utilization of soy hulls, oat hulls, and flax meal fiber in adult broiler breeder hens. Poultry Science: doi: 10.3382/ps/pex434.Google Scholar
LEVRAT, M.-A., RÉMÉSY, C. and DEMIGNÉ, C. (1991) High propionic acid fermentations and mineral accumulation in the cecum of rats adapted to different levels of inulin. The Journal of nutrition 121: 1730-1737.Google Scholar
LI, Y. and OWYANG, C. (1993) Vagal afferent pathway mediates physiological action of cholecystokinin on pancreatic enzyme secretion. Journal of Clinical Investigation 92: 418.Google Scholar
M'SADEQ, S.A., WU, S., SWICK, R.A. and CHOCT, M. (2015) Towards the control of necrotic enteritis in broiler chickens with in-feed antibiotics phasing-out worldwide. Animal Nutrition 1: 1-11.CrossRefGoogle ScholarPubMed
MALONE, G., CHALOUPKA, G. and SAYLOR, W. (1983) Influence of litter type and size on broiler performance. 1. Factors affecting litter consumption. Poultry Science 62: 1741-1746.Google Scholar
MATEOS, G.G., JIMENEZ-MORENO, E., SERRANO, M.P. and LAZARO, R.P. (2012) Poultry response to high levels of dietary fiber sources varying in physical and chemical characteristics. The Journal of Applied Poultry Research 21: 156-174.Google Scholar
MATIN, H.R.H., SAKI, A.A., ALIARABI, H., SHADMANI, M. and ABYANE, H.Z. (2012) Intestinal broiler microflora estimation by artificial neural network. Neural Computing and Applications 21: 1043-1047.CrossRefGoogle Scholar
MCHAN, F. and SHOTTS, E.B. (1993) Effect of short-chain fatty acids on the growth of salmonella typhimurium in an in vitro system. Avian Diseases 37: 396-398.CrossRefGoogle Scholar
MILOSEVIC, N., DUKIC STROJCIC, M., PERIC, L. and VUKIC-VRANJES, M. (2015) Effect of lignocellulose on egg production and egg quality. Proceedings of the 20th European Symposium on Poultry Nutrition, Prague, Czech Republic, pp. 046.Google Scholar
MONTAGNE, L., PLUSKE, J.R. and HAMPSON, D.J. (2003) A review of interactions between dietary fibre and the intestinal mucosa, and their consequences on digestive health in young non-ruminant animals. Animal Feed Science and Technology 108: 95-117.Google Scholar
MROZ, Z., KOOPMANS, S.-J., BANNINK, A., PARTANEN, K., KRASUCKI, W., ØVERLAND, M. and RADCLIFFE, S. (2006) Carboxylic acids as bioregulators and gut growth promoters in nonruminants. Biology of Growing Animals 4: 81-133.Google Scholar
MURAI, A., SATOH, S., OKUMURA, J.-I. and FURUSE, M. (2000) Factors regulating amylase secretion from chicken pancreatic acini in vitro. Life Sciences 66: 585-591.Google Scholar
MUSCH, M.W., BOOKSTEIN, C., XIE, Y., SELLIN, J.H. and CHANG, E.B. (2001) Scfa increase intestinal na absorption by induction of nhe3 in rat colon and human intestinal c2/bbe cells. American Journal of Physiology-Gastrointestinal and Liver Physiology 280: G687-G693.Google Scholar
NADERINEJAD, S., ZAEFARIAN, F., ABDOLLAHI, M., HASSANABADI, A., KERMANSHAHI, H. and RAVINDRAN, V. (2016) Influence of feed form and particle size on performance, nutrient utilisation, and gastrointestinal tract development and morphometry in broiler starters fed maize-based diets. Animal Feed Science and Technology 215: 92-104.Google Scholar
NIR, I., HILLEL, R., PTICHI, I. and SHEFET, G. (1995) Effect of particle size on performance. 3. Grinding pelleting interactions. Poultry Science 74: 771-783.Google Scholar
NIR, I., HILLEL, R., SHEFET, G. and NITSAN, Z. (1994) Effect of grain particle size on performance. 2. Grain texture interactions. Poultry Science 73: 781-791.Google Scholar
PACHECO, W., STARK, C., FERKET, P. and BRAKE, J. (2013) Evaluation of soybean meal source and particle size on broiler performance, nutrient digestibility, and gizzard development. Poultry Science 92: 2914-2922.Google Scholar
PALMER, M.F. and ROLLS, B. (1983) The activities of some metabolic enzymes in the intestines of germ-free and conventional chicks. British Journal of Nutrition 50: 783-790.Google Scholar
PERRY, G.C. (2006) Avian gut function in health and disease (Cabi).Google Scholar
PETTERSSON, D. and RAZDAN, A. (1993) Effects of increasing levels of sugar-beet pulp in broiler chicken diets on nutrient digestion and serum lipids. British Journal of Nutrition 70: 127-137.Google Scholar
PROUDFOOT, F. and HULAN, H. (1989) Feed texture effects on the performance of roaster chickens. Canadian Journal of Animal Science 69: 801-807.Google Scholar
PRYDE, S.E., DUNCAN, S.H., HOLD, G.L., STEWART, C.S. and FLINT, H.J. (2002) The microbiology of butyrate formation in the human colon. FEMS Microbiology Letters 217: 133-139.Google Scholar
RANINEN, K., LAPPI, J., MYKKÄNEN, H. and POUTANEN, K. (2011) Dietary fiber type reflects physiological functionality: Comparison of grain fiber, inulin, and polydextrose. Nutrition Reviews 69: 9-21.Google Scholar
REECE, F., LOTT, B. and DEATON, J. (1985) The effects of feed form, grinding method, energy level, and gender on broiler performance in a moderate (21 c) environment. Poultry Science 64: 1834-1839.Google Scholar
REHMAN, H.U., VAHJEN, W., AWAD, W.A. and ZENTEK, J. (2007) Indigenous bacteria and bacterial metabolic products in the gastrointestinal tract of broiler chickens. Archives of Animal Nutrition 61: 319-335.Google Scholar
REZAEI, M., KARIMI TORSHIZI, M.A. and ROUZBEHAN, Y. (2011) The influence of different levels of micronized insoluble fiber on broiler performance and litter moisture. Poultry Science 90: 2008-2012.Google Scholar
RHODES, J. (1989) Colonic mucus and mucosal glycoproteins: The key to colitis and cancer? Gut 30: 1660.Google Scholar
RICKE, S. (2003) Perspectives on the use of organic acids and short chain fatty acids as antimicrobials. Poultry Science 82: 632-639.Google Scholar
ROLFE, R.D. (2000) The role of probiotic cultures in the control of gastrointestinal health. The Journal of Nutrition 130: 396S-402S.Google Scholar
ROUGIÈRE, N., GOMEZ, J., MIGNON-GRASTEAU, S. and CARRÉ, B. (2009) Effects of diet particle size on digestive parameters in d+ and d− genetic chicken lines selected for divergent digestion efficiency. Poultry Science 88: 1206-1215.Google Scholar
SACRANIE, A. (2010) How feed constituents regulate gut motility, feed utilisation and growth in broiler chickens., University of New England.Google Scholar
SANDERSON, I.R. (2004) Short chain fatty acid regulation of signaling genes expressed by the intestinal epithelium. The Journal of nutrition 134: 2450S-2454S.Google Scholar
SHAKOURI, M., KERMANSHAHI, H. and MOHSENZADEH, M. (2006) Effect of different non starch polysaccharides in semi purified diets on performance and intestinal microflora of young broiler chickens. International Journal of Poultry Science 5: 557-561.Google Scholar
SINGH, Y., RAVINDRAN, V., WESTER, T., MOLAN, A. and RAVINDRAN, G. (2014) Influence of feeding coarse corn on performance, nutrient utilization, digestive tract measurements, carcass characteristics, and cecal microflora counts of broilers. Poultry Science 93: 607-616.Google Scholar
SONNENBURG, J.L. and BÄCKHED, F. (2016) Diet-microbiota interactions as moderators of human metabolism. Nature 535: 56-64.Google Scholar
SPRING, P., WENK, C., DAWSON, K. and NEWMAN, K. (2000) The effects of dietary mannaoligosaccharides on cecal parameters and the concentrations of enteric bacteria in the ceca of salmonella-challenged broiler chicks. Poultry Science 79: 205-211.Google Scholar
SULEK, K., VIGSNAES, L.K., SCHMIDT, L.R., HOLCK, J., FRANDSEN, H.L., SMEDSGAARD, J., SKOV, T.H., MEYER, A.S. and LICHT, T.R. (2014) A combined metabolomic and phylogenetic study reveals putatively prebiotic effects of high molecular weight arabino-oligosaccharides when assessed by in vitro fermentation in bacterial communities derived from humans. Anaerobe 28: 68-77.Google Scholar
SVIHUS, B. (2011) The gizzard: Function, influence of diet structure and effects on nutrient availability. World's Poultry Science Journal 67: 207-224.Google Scholar
SVIHUS, B. (2014) Function of the digestive system. The Journal of Applied Poultry Research 23: 306-314.Google Scholar
SVIHUS, B., JUVIK, E., HETLAND, H. and KROGDAHL, Å. (2004a) Causes for improvement in nutritive value of broiler chicken diets with whole wheat instead of ground wheat. British Poultry Science 45: 55-60.Google Scholar
SVIHUS, B., KLØVSTAD, K., PEREZ, V., ZIMONJA, O., SAHLSTRÖM, S., SCHÜLLER, R., JEKSRUD, W. and PRESTLØKKEN, E. (2004b) Physical and nutritional effects of pelleting of broiler chicken diets made from wheat ground to different coarsenesses by the use of roller mill and hammer mill. Animal Feed Science and Technology 117: 281-293.Google Scholar
TELLEZ, G., HIGGINS, S., DONOGHUE, A. and HARGIS, B. (2006) Digestive physiology and the role of microorganisms. Journal of Applied Poultry Research 15: 136-144.Google Scholar
TING, S., YEH, H. and LIEN, T. (2011) Effects of supplemental levels of hesperetin and naringenin on egg quality, serum traits and antioxidant activity of laying hens. Animal Feed Science and Technology 163: 59-66.Google Scholar
TIMBERMONT, L., HAESEBROUCK, F., DUCATELLE, R. and VAN IMMERSEEL, F. (2011) Necrotic enteritis in broilers: An updated review on the pathogenesis. Avian Pathology 40: 341-347.Google Scholar
VAN DER HOEVEN-HANGOOR, E., RADEMAKER, C., PATON, N., VERSTEGEN, M. and HENDRIKS, W. (2014) Evaluation of free water and water activity measurements as functional alternatives to total moisture content in broiler excreta and litter samples. Poultry Science 93: 1782-1792.Google Scholar
VAN DER KLIS, J. and DE LANGE, L. (2013) Water intake in poultry. Proceedings of the 19th European Poultry Nutrition Symposium, Postdam, Germany, pp. 102-107.Google Scholar
VAN DER WIELEN, P.W., BIESTERVELD, S., NOTERMANS, S., HOFSTRA, H., URLINGS, B.A. and VAN KNAPEN, F. (2000) Role of volatile fatty acids in development of the cecal microflora in broiler chickens during growth. Applied and Environmental Microbiology 66: 2536-2540.Google Scholar
VAN IMMERSEEL, F., BUCK, J.D., PASMANS, F., HUYGHEBAERT, G., HAESEBROUCK, F. and DUCATELLE, R. (2004) Clostridium perfringens in poultry: An emerging threat for animal and public health. Avian Pathology 33: 537-549.Google Scholar
WASHBURN, K. (1991) Efficiency of feed utilization and rate of feed passage through the digestive system. Poultry Science 70: 447-452.Google Scholar
XU, Y. (2014) Interaction of dietary coarse corn with litter conditions on broiler live performance and gastrointestinal tract function. North Carolina State University.Google Scholar
XU, Y., LIN, Y., STARK, C., FERKET, P., WILLIAMS, C. and BRAKE, J. (2017) Effects of dietary coarsely ground corn and 3 bedding floor types on broiler live performance, litter characteristics, gizzard and proventriculus weight, and nutrient digestibility. Poultry Science 96: 210-2119.Google Scholar
XU, Y., STARK, C., FERKET, P., WILLIAMS, C., AUTTAWONG, S. and BRAKE, J. (2015a) Effects of dietary coarsely ground corn and litter type on broiler live performance, litter characteristics, gastrointestinal tract development, apparent ileal digestibility of energy and nitrogen, and intestinal morphology. Poultry Science 94: 353-361.Google Scholar
XU, Y., STARK, C., FERKET, P., WILLIAMS, C., NUSAIRAT, B. and BRAKE, J. (2015c) Evaluation of litter type and dietary coarse ground corn inclusion on broiler live performance, gastrointestinal tract development, and litter characteristics. Poultry Science 94: 362-370.Google Scholar
XU, Y., STARK, C., FERKET, P.R., WILLIAMS, C.M. and BRAKE, J. (2015) Effects of feed form and dietary coarse ground corn on broiler live performance, body weight uniformity, relative gizzard weight, excreta nitrogen, and particle size preference behaviors. Poultry Science 94: 1549-1556.Google Scholar