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Developments in understanding and assessment of egg and egg product quality over the last century

Published online by Cambridge University Press:  28 June 2013

M. ROSSI*
Affiliation:
Università degli Studi di Milano, Dept. of Food, Environmental and Nutritional Sciences (DeFENS), via Celoria 2, Milano 20133, Italy
Y. NYS
Affiliation:
INRA, UR83 Recherches Avicoles, Nouzilly, France
M. ANTON
Affiliation:
INRA, UR1268 Biopolymères Interactions Assemblage Nantes, France
M. BAIN
Affiliation:
University of Glasgow, Institute of Biodiversity, Animal Health and Comparative Medicine, Glasgow, United Kingdom
B. DE KETELAERE
Affiliation:
Katholieke Universiteit Leuven, Dept. of Biosystems, Heverlee, Belgium
K. DE REU
Affiliation:
Institute for Agricultural and Fisheries Research (ILVO), Technology and Food Science Unit, Melle, Belgium
I. DUNN
Affiliation:
University of Edinburgh, The Roslin Institute and Royal School of Veterinary Studies, Midlothian, United Kingdom
J. GAUTRON
Affiliation:
INRA, UR83 Recherches Avicoles, Nouzilly, France
M. HAMMERSHØJ
Affiliation:
Aarhus University, Dept. of Food Science, Tjele, Denmark
A. HIDALGO
Affiliation:
Università degli Studi di Milano, Dept. of Food, Environmental and Nutritional Sciences (DeFENS), via Celoria 2, Milano 20133, Italy
A. MELUZZI
Affiliation:
Università di Bologna, Dept. of Food Science (DISA), Ozzano Emilia, Italy
K. MERTENS
Affiliation:
Katholieke Universiteit Leuven, Dept. of Biosystems, Heverlee, Belgium
F. NAU
Affiliation:
INRA, UMR1253 Science et Technologie du Lait et de l’Œuf, Rennes, France
F. SIRRI
Affiliation:
Università di Bologna, Dept. of Food Science (DISA), Ozzano Emilia, Italy
*
Corresponding author: [email protected]
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Abstract

The hen's egg, in the form of table eggs and egg products, forms a staple part of the world's total protein consumption. In the last century, there has been considerable research effort focusing on ways of improving egg production and enhancing the quality of eggs. More recently, and with the development and application of new molecular technologies, our understanding and knowledge of how an egg is formed, what it actually consists of, in terms of its major versus minor components, and what the functional roles of each of these components might be, have been greatly enhanced. For example, new previously unknown molecules with specific activity or functional properties have been discovered in the egg albumen and yolk, some of which have potential uses in pharmaceutical and other food related applications. This review paper, which is the collaborative effort of members of Working Group 4 - Quality of Eggs and Egg Products - of the European Federation of WPSA, describes the scientific research behind a number of these major advances and provides some insight to the focus of current research in this area.

Type
Centennial Paper
Copyright
Copyright © World's Poultry Science Association 2013

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References

ABDEL-NOUR, N., NGADI, M., PRASHER, S. and KARIMI, Y. (2011) Prediction of egg freshness and albumen quality using visible/near infrared spectroscopy. Food and Bioprocess Technology 4: 731-736.CrossRefGoogle Scholar
ALBERS, G. (2010) Genomic selection in poultry and pig breeding – a breakthrough technology? British Poultry Abstracts 6: 13.Google Scholar
ARIAS, J.L., FINK, D.J., XIAO, S.Q., HEUER, A.H. and CAPLAN, A.I. (1993) Biomineralization and eggshells: cell-mediated acellular compartments of mineralized extracellular matrix. International Review of Cytology 145: 217-250.CrossRefGoogle ScholarPubMed
BAIN, M.M., MCDADE, K., SCHMUTZ, M., PREISINGER, R., WADDINGTON, D. and DUNN, I.C. (2009) The deposition of the cuticle on laying hens eggs is a moderately heritable trait. British Poultry Abstracts 5: 17.Google Scholar
BARON, F. and JAN, S. (2011) Egg and egg product microbiology, in: NYS, Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and the quality of eggs and egg products, Vol. 1: Egg chemistry, production and consumption, pp. 330-350 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
BOARD, R.G. (1982) Properties of avain eggshells and their adaptative value. Biological Review 57: 1-28.CrossRefGoogle Scholar
BROWN, M.S. and GOLDSTEIN, J.L. (1986) A receptor-mediated pathway for cholesterol homeostasis. Science 232: 34-47.CrossRefGoogle ScholarPubMed
BURLEY, R.W. and VADEHRA, D.V. (1989) The Avian Egg, Chemistry and Biology (Toronto, John Wiley and Sons).Google Scholar
CAPOZZI, F., CREMONINI, M.A., FRANCHINI, A. and PLACUCCI, G. (1999) Water proton relaxation rate changes during the thinning process of shell eggs albumen. Proceedings of the VIII European Symposium on the Quality of Eggs and Egg Products, Bologna, Italy, pp. 457-460.Google Scholar
CASTON, L. and LEESON, S. (1990) Research Note: dietary flax and egg composition. Poultry Science 69: 1617-1620.CrossRefGoogle Scholar
CHANG, C.M., POWRIE, W.D. and FENNEMA, O. (1977) Microstructure of egg yolk. Journal of Food Science 42: 1193-1200.CrossRefGoogle Scholar
CHERIAN, G. and SIM, J.S. (1991) Effect of feeding full fat flax and canola seeds to laying hens on the fatty acids composition of eggs, embryos and newly hatched chicks. Poultry Science 70: 917-922.CrossRefGoogle Scholar
CHIEN, Y.C., HINCKE, M.T., VALI, H. and MCKEE, M.D. (2008) Ultrastructural matrix-mineral relationships in avian eggshell, and effects of osteopontin on calcite growth in vitro. Journal of Structural Biology 163: 84-99CrossRefGoogle ScholarPubMed
CROGUENNEC, T., NAU, F. and BRULÉ, G. (2002) Influence of pH and salts on the hen egg white gelation. Journal of Food Science 67: 608-614.CrossRefGoogle Scholar
CRUICKSHANK, E.M. (1934) Studies in fat metabolism in the fowl I. The composition of the egg fat and depot fat of the fowl has affected by the ingestion of large amounts of different fats. Biochemistry Journal 28: 965-977.CrossRefGoogle ScholarPubMed
D'AMBROSIO, C., ARENA, S., SCALONI, A., GUERRIER, L., BOSCHETTI, E., MENDIETA, M.E., CITTERIO, A. and RIGHETTI, P.G. (2008) Exploring the chicken egg white proteome with combinatorial peptide ligand libraries. Journal of Proteome Research 7: 3461-3474.CrossRefGoogle ScholarPubMed
DAUPHAS, S., BEAUMAL, V., RIAUBLANC, A. and ANTON, M. (2006) Hen egg yolk low density lipoproteins film spreading at the air-water and oil-water interfaces. Journal of Agricultural and Food Chemistry 54: 3733-3737.CrossRefGoogle ScholarPubMed
DE REU, K., GRIJSPEERDT, K., MESSENS, W., HEYNDRICKX, M., UYTTENDAELE, M., DEBEVERE, J. and HERMAN, L. (2006a) Eggshell factors influencing eggshell penetration and whole egg contamination by different bacteria, including Salmonella Enteritidis. International Journal of Food Microbiology 112: 253-260.CrossRefGoogle ScholarPubMed
DE REU, K., HEYNDRICKX, M., GRIJSPEERDT, K., RODENBURG, B., TUYTTENS, F., UYTTENDAELE, M., DEBEVERE, J. and HERMAN, L. (2006b) Assessment of the vertical and horizontal aerobic bacterial infection of shell eggs. World's Poultry Science Journal 62(Supplement): 564.Google Scholar
DE REU, K., MESSENS, W., HEYNDRICKX, M., RODENBURG, B., UYTTENDAELE, M. and HERMAN, L. (2008) Bacterial contamination of table eggs and the influence of housing systems. World's Poultry Science Journal 64: 5-19.CrossRefGoogle Scholar
DENNIS, J.E., XIAO, S.Q., AGARVAL, M., FINK, D.J., HEUER, A.H. and CAPLAN, A.I. (1996) Microstructure of matrix and mineral components of eggshells from white leghorn chicken (Gallus gallus). Journal of Morphology 228: 287-306.3.0.CO;2-#>CrossRefGoogle Scholar
DESFOUGÈRES, Y., SAINT-JALMES, A., SALONEN, A., VIÉ, V., BEAUFILS, S., PÉZENNEC, S., DESBAT, B., LECHEVALIER, V. and NAU, F. (2011) Strong improvement of interfacial properties can result from slight structural modifications of proteins: the case of native and dry-heated lysozyme. Langmuir 27: 14947-14957.CrossRefGoogle ScholarPubMed
DUNN, I. (2011) Poultry breeding for egg quality: traditional and modern genetic approaches to selection for egg quality, in: NYS, Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and the quality of eggs and egg products, Vol. 1: Egg chemistry, production and consumption, pp. 245-260 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
DUNN, I.C., JOSEPH, N.T., BAIN, M., EDMOND, A., WILSON, P.W., MILONA, P., NYS, Y., GAUTRON, J., SCHMUTZ, M., PREISINGER, R. and and WADDINGTON, D. (2009) Polymorphisms in eggshell organic matrix genes are associated with eggshell quality measurements in pedigree Rhode Island Red hens. Animal Genetics 40: 110-114.CrossRefGoogle ScholarPubMed
DUNN, I.C., RODRÍGUEZ-NAVARRO, A.B., McDADE, K., SCHMUTZ, M., PREISENGER, R., WADDINGTON, D., WILSON, P.W. and BAIN, M.M. (2012) Genetic variation in eggshell crystal size and orientation is large and these traits are correlated with shell thickness and are associated with eggshell matrix protein markers. Animal Genetics 43: 410-418.CrossRefGoogle ScholarPubMed
EU (European Union), (2003) Regulation (EC) No 2295/2003, December 23, 2003. Council Official Journal of the European Union L340: 16-34.Google Scholar
EVANS, R.J., BAUER, D.H., BANDEMER, S.L., VAGHEFI, S.B. and FLEGEL, C.J. (1973) Structure of egg yolk very low density lipoprotein: Polydispersity of the very low density lipoprotein and the role of lipovitellenin in the structure. Archives of Biochemistry and Biophysics 154: 493-500.CrossRefGoogle ScholarPubMed
FARRELL, D.J. (1994) The fortification of hen's eggs with omega-3 long chain fatty acids and their effect in humans, in: SIM, J.S. & NAKAI, S. (Eds) Egg uses and processing technologies – New developments (Oxon, UK, CAB International).Google Scholar
GARCÍA-RUIZ, J.M. and RODRÍGUEZ-NAVARRO, A. (1994) The mineral structure of the avian eggshell: a case of competitive crystal growth, in: ALLEMAND, D. & CUIF, J.P. (Eds) Biomineralization 93, 7th international symposium on Biomineralization. 1. Fundamentals of biomineralization, pp. 85-94 (Monaco, Bulletin de l'institut océanographique).Google Scholar
GAUTRON, J., RÉHAULT-GODBERT, S., NYS, Y., MANN, K. and RIGHETTI, P.G. (2011) Use of high-throughput technology to identify new egg components, in: NYS Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and quality of eggs and eggs products. Vol. 1 Egg chemistry, production and consumption, pp. 133-150 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
GIUNCHI, A., BERARDINELLI, A., RAGNI, L., FABBRI, A. and SILAGHI, F.A. (2008) Non-destructive freshness assessment of shell eggs using FT-NIR spectroscopy. Journal of Food Engineering 89: 142-148.CrossRefGoogle Scholar
GRIFFIN, B.A. (2011) Eggs, dietary cholesterol and disease: facts and folklore, in: VAN IMMERSEEL, F., NYS Y. & BAIN, M. (Eds) Improving the safety and quality of eggs and eggs products. Vol. 2 Egg safety and nutritional quality, pp. 237-253 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
GRIFFIN, H.D. (1992) Manipulation of egg-yolk cholesterol-a physiologists view. World's Poultry Science Journal 48(2): 101-112.CrossRefGoogle Scholar
GROBAS, S., MENDEZ, J., LOPEZ BOTE, C., DE BLAS, C. and MATEOS, G.G. (2002) Effect of vitamin E and A supplementation on egg yolk α-tocopherol concentration. Poultry Science 81: 376-381.CrossRefGoogle Scholar
GUÉRIN-DUBIARD, C., ANTON, M., GAUTRON, J., NYS, Y. and NAU, F. (2010) Composition de l'oeuf, in: NAU, F., GUÉRIN-DUBIARD, C., BARON, F. & THAPON, J.L. (Eds) Science et technologie de l’œuf. Vol. 2 De l'oeuf aux ovoproduits, pp. 1-177 (Paris, Ed Tec & Doc Lavoisier).Google Scholar
HAMILTON, R.M.G. (1986) The microstructure of the hen's eggshell: a short review. Food microstructure 5: 99-110.Google Scholar
HAMMERSHØJ, M., PETERS, L.V. and ANDERSEN, H.J. (2004) The significance of critical processing steps in the production of dried egg albumen powder on gel textural and foaming properties . Journal of the Science of Food and Agriculture 84: 1039-1048.CrossRefGoogle Scholar
HAMMERSHØJ, M., PRINS, A. and QVIST, K.B. (1999) Influence of pH on surface properties of aqueous egg albumen solutions in relation to foaming behaviour. Journal of the Science of Food and Agriculture 79: 859-868.3.0.CO;2-C>CrossRefGoogle Scholar
HAMMERSHØJ, M., RASMUSSEN, H.C., CARSTENS, J.H. and PEDERSEN, H. (2006) Dry-pasteurization of egg albumen powder in a fluidized bed. II. Effect on functional properties: gelation and foaming. International Journal of Food Science and Technology 41: 263-274.CrossRefGoogle Scholar
HATTA, H., KAPOOR, P. and JUNEJA, L.R. (2008) Bioactive components in egg yolk, in: MINE, Y. (Ed.) Egg bioscience and Biotechnology, pp. 185-238 (Hoboken, New Jersey, John Willey and Sons).Google Scholar
HERNANDEZ-HERNANDEZ, A., VIDAL, M.L., GOMEZ-MORALES, J., RODRÍGUEZ-NAVARRO, A.B., LABAS, V., GAUTRON, J., NYS, Y. and GARCÍA-RUIZ, J.M. (2008) Influence of eggshell matrix proteins on the precipitation of calcium carbonate (CaCO3). Journal of Crystal Growth 310: 1754-1759.CrossRefGoogle Scholar
HERRON, K.L., VEGA-LOPEZ, S., CONDE, K., RAMJIGANESH, T., SHACHTER, N.S. and FERNANDEZ, M.L. (2003) Men classified as hypo- or hyper-responders to dietary cholesterol feeding exhibit differences in lipoprotein metabolism. Journal of Nutrition 133(4): 1036-1042.CrossRefGoogle Scholar
HIDALGO, A., ROSSI, M. and POMPEI, C. (1995) Furosine as a freshness parameter of shell eggs. Journal of Agricultural and Food Chemistry 43: 1673-1677.CrossRefGoogle Scholar
HINCKE, M.T., NYS, Y., GAUTRON, J., MANN, K., RODRÍGUEZ-NAVARRO, A. and MCKEE, M. (2012) The eggshell: structure, composition and mineralization. Frontiers in Bioscience 17: 1266-1280.CrossRefGoogle ScholarPubMed
HINCKE, M.T., WELLMAN-LABADIE, O., MCKEE, M.D., GAUTRON, J., NYS, Y. and MANN, K. (2008) Biosynthesis and structural assembly of eggshell components, in: MINE, Y. (Ed.) Egg Bioscience and Biotechnology, Chapter 2 (Hoboken, USA, John Wiley and Sons).Google Scholar
HOCKING, P.M. (2005) Review of QTL mapping results in chickens. World's Poultry Science Journal 61: 215-226.CrossRefGoogle Scholar
HONKATUKIA, M., REESE, K., PREISINGER, R., TUISKULA-HAAVISTO, M., WEIGEND, S., ROITO, J., MAKI-TANILA, A. and VILKKI, J. (2005a) Fishy taint in chicken eggs is associated with a substitution within a conserved motif of the FMO3 gene. Genomics 86: 225-232.CrossRefGoogle ScholarPubMed
HONKATUKIA, M., TUISKULA-HAAVISTO, M., DE KONING, D.J., VIRTA, A., MAKI-TANILA, A. and VILKKI, J. (2005b) A region on chicken chromosome 2 affects both egg white thinning and egg weight. Genetics Selection Evolution 37: 563-577.CrossRefGoogle ScholarPubMed
HOWELL, W.J. (2000) Food cholesterol and its plasma lipid and lipoprotein response: is food cholesterol still a problem or overstated, in: SIM, J.S., NAKAI, S. & GUENTER, W. (Eds) Egg Nutrition and Biotechnology, pp. 15-24 (New York, CAB Int. Publishing).Google Scholar
HUOPALAHTI, R., LÓPEZ-FANDIÑO, R., ANTON, M. and SHADE, R. (Eds) (2007) Bioactive Egg Compounds (Heidelberg, Germany, Springer-Verlag).CrossRefGoogle Scholar
INTERNATIONAL CHICKEN GENOME SEQUENCING CONSORTIUM, (2004) Sequence and comparative analysis of the chicken genome provide unique perspectives on vertebrate evolution. Nature 432: 695-716.CrossRefGoogle Scholar
JIANG, Y., MCGEACHIN, R. and BAILEY, C. (1994) Alpha-tocopherol, beta-carotene, and retinol enrichment of chicken eggs. Poultry Science 73: 1137-1143.CrossRefGoogle ScholarPubMed
JOLIVET, P., BOULARD, C., BEAUMAL, V., CHARDOT, T. and ANTON, M. (2006) Protein components of low-density lipoproteins purified from hen egg yolk. Journal of Agricultural and Food Chemistry 54: 4424-4429.CrossRefGoogle ScholarPubMed
JONCHÈRE, V., RÉHAULT-GODBERT, S., HENNEQUET-ANTIER, C., CABAU, C., SIBUT, V., COGBURN, L.A., NYS, Y. and GAUTRON, J. (2010) Gene expression profiling to identify eggshell proteins involved in physical defense of the chicken egg. BMC genomics 11: 57.CrossRefGoogle ScholarPubMed
KAROUI, R., KEMPS, B., BAMELIS, F., DE KETELAERE, B., MERTEN, K., SCHOONHEYDT, R., DECUYPERE, E. and DE BAERDEMAEKER, J. (2006) Development of a rapid method based on front face fluorescence spectroscopy for the monitoring of egg freshness: 1 - evolution of thick and thin egg albumens. European Food Research and Technology 223: 303-312.CrossRefGoogle Scholar
KATO, A., IBRAHIM, H.R., WATANABE, H., HONMA, K. and KOBAYASHI, K. (1989) New approach to improve gelling and surface properties of dried egg white by heating in the dry state. Journal of Agricultural and Food Chemistry 37: 433-437.CrossRefGoogle Scholar
KEMPS, B., DE KETELAERE, B., BAMELIS, F.R., MERTENS, K., DECUYPERE, E.M., DE BAERDEMAEKER, J.G. and SCHWÄGELE, F. (2007) Albumen freshness assessment by Combining Visible Near-Infrared Transmission and Low-Resolution Proton Nuclear Magnetic Resonance Spectroscopy. Poultry Science 86: 752-759.CrossRefGoogle ScholarPubMed
KNOPP, R.H., RETZLAFF, B.M., WALDEN, C.E., DOWDY, A.A., TSUNEHARA, C.H., AUSTIN, M.A. and NGUYEN, T. (1997) A double-blind, randomized, controlled trial of the effect of two eggs per day in moderately hypercholesterolemic and combined hyperlipidemic subjects taught the NCEP Step 1 Diet. Journal of American College Nutrition 16: 551-561.Google Scholar
KRITCHEVSKY, D. (2000) Dietary fat and disease; what do we know and where do we stand, in: SIM, J.S., NAKAI, S. & GUENTER, W. (Eds) Egg Nutrition and Biotechnology, pp. 3-13 (New York, USA, CAB Int. Publishing).Google Scholar
LE DENMAT, M., ANTON, M. and BEAUMAL, V. (2000) Characterisation of emulsion properties and of interface composition in oil-in-water emulsions prepared with hen egg yolk, plasma and granules. Food Hydrocolloids 14: 539-549.CrossRefGoogle Scholar
LECHEVALIER, V., JEANTET, R., ARHALIASS, A., LEGRAND, J. and NAU, F. (2007) Egg white drying: influence of processing steps on protein structure and functionalities. Journal of Food Engineering 83: 404-413.CrossRefGoogle Scholar
LI-CHAN, E.C.Y., POWRIE, W.D. and NAKAI, S. (1995) The chemistry of eggs and egg products, in: STADELMAN, W.J. & COTTERILL, O.J. (Eds) Egg Science and Technology, Chapter 6 (New York, USA, Food Product Press).Google Scholar
LÓPEZ-FANDIÑO, R., RECIO, I. and RAMOS, M. (2007) Egg-protein-derived peptides with antihypertensive activity, in: HUOPALAHTI, R., LÓPEZ-FANDIÑO, R., ANTON, M. & SHADE, R. (Eds) Bioactive Egg Compounds, pp. 199-211 (Heidelberg, Germany, Springer-Verlag).Google Scholar
MAGDELAINE, P. (2009) Future prospects for the European egg industry Proceedings of the XIII European Symposium on the Quality of Eggs and Egg Products, Turku, Finland, PL3.Google Scholar
MAGDELAINE, P. (2011) Egg and egg product production and consumption in Europe and the rest of the world, in: NYS, Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and quality of eggs and egg products, Vol. 1, pp. 3-16 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
MANN, K. (2007) The chicken egg white proteome. Proteomics 7: 3558-68.CrossRefGoogle ScholarPubMed
MANN, K. (2008) Proteomic analysis of the chicken egg vitelline membrane. Proteomics 8: 2322-2332.CrossRefGoogle ScholarPubMed
MANN, K. and MANN, M. (2008) The chicken egg yolk plasma and granule proteomes Proteomics 8: 178-91.CrossRefGoogle ScholarPubMed
MANN, K., MAČEK, B. and OLSEN, J.V. (2006) Proteomic analysis of the acid-soluble organic matrix of the chicken calcified eggshell layer Proteomics 6: 3801-3810.CrossRefGoogle ScholarPubMed
MARTIN, M.J., HULLEY, S.B., BROWNER, W.S., KULLER, L.H. and WENTWORTH, D. (1986) Serum cholesterol, blood pressure, and mortality: implications from a cohort of 361,662 men. Lancet 2: 933-936.CrossRefGoogle ScholarPubMed
MARTINET, V., SAULNIER, P., BEAUMAL, V., COURTHAUDON, J.L. and ANTON, M. (2003) Surface properties of hen egg yolk low-density lipoproteins spread at the air-water interface. Colloids and Surfaces B: Biointerfaces 31: 185-194.CrossRefGoogle Scholar
MATTILA, P., ROKKA, T., KONKO, K., VALAJA, J., ROSSOW, L. and RYHANEN, E.L. (2003) Effect of cholecalciferol-enriched hen feed on egg quality. Journal of Agricultural and Food Chemistry 51: 283-287.CrossRefGoogle ScholarPubMed
MCNAMARA, D.J. (2002) Eggs and heart disease risk: perpetuating the misperception. The American Journal of Clinical Nutrition 75: 333-335.CrossRefGoogle ScholarPubMed
MELUZZI, A., SIRRI, F., MANFREDA, G., TALLARICO, N. and FRANCHINI, A. (2000) Effects of dietary vitamin E on the quality of table eggs enriched with omega-3 long chain fatty acids. Poultry Science 79:539-545.CrossRefGoogle Scholar
MELUZZI, A., SIRRI, F., TALLARICO, N. and FRANCHINI, A. (2001) Effect of different vegetable lipid sources on the fatty acid composition of egg yolk and on hen performance. Archiv für Geflügelkunde 65: 207-213.Google Scholar
MERTENS, K., BAMELIS, F., KEMPS, B., KAMERS, B., VERHOELST, E., DE KETELAERE, B., BAIN, M., DECUYPERE, E. and DE BAERDEMAEKER, J. (2006) Monitoring of eggshell breakage and eggshell strength in different production chains of consumption eggs. Poultry Science 85: 1670-1677.CrossRefGoogle ScholarPubMed
MERTENS, K., KEMPS, B., PERIANU, C., DE BAERDEMAEKER, J., DECUYPERE, E., DE KETALAERE, B. and BAIN, M. (2011) Advances in egg defect detection, quality assessment and automated sorting and grading, in: NYS, Y., BAIN M. & VAN IMMERSEEL F. (Eds) Improving the Safety and Quality of Eggs and Egg Products, Vol. 1, pp. 209-241 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
MERTENS, K., VAESEN, I., LÖFFEL, J., KEMPS, B., KAMERS, B., PERIANU, C., ZOONS, J., DARIUS, P., DECUYPERE, E., DE BAERDEMAEKER, J. and DE KETELAERE, B. (2010) The transmission color value: A novel egg quality measure for recording shell color used for monitoring the stress and health status of a brown layer flock. Poultry Science 89: 609-617.CrossRefGoogle Scholar
MIKHAILOV, K.E. (1997) Avian eggshells: an Atlas of scanning electron micrographs, British Ornitologists’ Club Occasional Publications 3: 88.Google Scholar
MINE, Y. (1995) Recent advances in the understanding of egg white protein functionality. Trends in Food Science and Technology 6: 225-232.CrossRefGoogle Scholar
MINE, Y. and D'SILVA, I. (2008) Bioactive components in egg white, in: MINE, Y. (Ed.) Egg Bioscience and Biotechnology, pp. 141-184 (Hoboken, New Jersey, John Willey and Sons).Google Scholar
NABER, E.C. (1993) Modifying vitamin composition of eggs: a review. Journal of Applied Poultry Research 2: 385-393.CrossRefGoogle Scholar
NAGAOKA, S., MASAOKA, M., ZHANG, Q., HASEGAWA, M. and WATANABE, K. (2002) Egg ovomucin attenuates hypercholesterolemia in rats and inhibits cholesterol absorption in Caco-2 cells. Lipids 37(3): 267-272.CrossRefGoogle Scholar
NAU, F., NYS, Y., YAMAKAWA, Y. and REHAULT-GODBERT, S. (2010) Interêt nutritionnel de l’œuf en alimentation humaine. INRA Production Animale 23(2): 225-236.Google Scholar
NOH, S.K. and and KOO, S.I. (2003) Egg sphingomyelin lowers the lymphatic absorption of cholesterol and α-tocopherol in rats. Journal of Nutrition 133: 3571-3576.CrossRefGoogle ScholarPubMed
NYS, Y., BURLOT, T. and DUNN, I.C. (2008) Internal quality of eggs: any better, any worse? XXIII World's Poultry Congress, Brisbane (AUS), World's Poultry Science Association (Australian branch), 10 p. (Abstract p113). (CD-Rom).Google Scholar
NYS, Y., GAUTRON, J., GARCÍA-RUIZ, J.M. and HINCKE, M.T. (2004) Avian eggshell mineralization: biochemical and functional characterization of matrix proteins. Comptes Rendus Palevol 3: 549-562.CrossRefGoogle Scholar
NYS, Y. and GUYOT, N. (2011) Egg formation and chemistry, in: NYS, Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and quality of eggs and eggs products. Vol.1 Egg chemistry, production and consumption, Chapter 6, pp. 83-132 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
NYS, Y., HINCKE, M.T., ARIAS, J.L., GARCÍA-RUIZ, J.M. and SOLOMON, S. (1999) Avian eggshell mineralization. Poultry and Avian Biology Reviews 10: 143-166.Google Scholar
NYS, Y., ZAWADZKI, J., GAUTRON, J. and MILLS, A.D. (1991) Whitening of brown-shelled eggs: mineral composition of uterine fluid and rate of protoporphyrin deposition. Poultry Science 70: 1236-1245.CrossRefGoogle ScholarPubMed
PREISINGER, R. (2012) Applied genomic selection in layers. Zuchtungskunde 84: 4-11.Google Scholar
RAGNI, L., BERARDINELLI, A. and GUARNIERI, A. (2008) A dielectric technique based on a one-chip network analyser to predict the quality indices of shell eggs. Biosystems Engineering 100: 470-478.CrossRefGoogle Scholar
RASPOET, R., GANTOIS, I., DEVLOO, R., PASMANS, F., HAESEBROUCK, F., DUCATELLE, R. and VAN IMMERSEEL, F. (2011) Internal contamination of eggs by Salmonella Enteritidis, in: NYS, Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and the quality of eggs and egg products, Vol. 2: Egg safety and nutritional quality, pp. 46-61 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
RÉHAULT-GODBERG, S., HERVÉ-GREPINET, V., GAUTRON, J., CABAU, C. and NYS, Y. (2011) Molecule involved in chemical defence of the chicken egg, in: NYS, Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and quality of eggs and egg products, Vol 1: Egg chemistry, production and consumption, pp. 183-208 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
ROMANOFF, A.L. and ROMANOFF, A.J. (1949) The avian egg (New York, USA, John Willey & Sons Inc) pp. 918.Google Scholar
ROSSI, M., HIDALGO, A. and POMPEI, C. (2001) Reaction between albumen and 3,3’,5,5’-tetramethylbenzidine as a method to evaluate egg freshness. Journal of Agricultural and Food Chemistry 49: 3522-3526.CrossRefGoogle ScholarPubMed
ROSSI, M., POMPEI, C. and HIDALGO, A. (1995) Freshness criteria based on physical and chemical modifications occurring in eggs during aging. Italian Journal of Food Science 7(2): 147-156.Google Scholar
SCHADE, R., ZHANG, X.Y. and TERLOZO, H.R. (2007) Use of IgY antibodies in human and veterinary medicine, in: HUOPALATHI, R., LOPEZ-FANDINO, R., ANTON, M. & SCHADE, R. (Eds) Bioactive Egg Compounds, pp. 213-222 (Berlin, Germany, Springer).Google Scholar
SHARP, R.M. and SILYN-ROBERTS, H. (1984) Development of preferred orientation in the eggshell of the domestic fowl. Biophysical Journal 46: 175-179.CrossRefGoogle ScholarPubMed
SIMONS, P.C.M. (1970) Ultrastructure of the hen eggshell and its physiological interpretation. PhD thesis, Cent. Agric. Pub. Doc. WageningenGoogle Scholar
SIRRI, F. and BARROETA, A. (2007) Enrichment in vitamins., in: HUOPALAHTI, R., LOPEZ-FANDINO, R., ANTON, M. & SHADE, R. (Eds) Bioactive Egg Compounds, pp 171-182 (Berlin, Springer-Verlag).Google Scholar
SIRRI, F. and MELUZZI, A. (2011) Modifying egg lipids for human health, in: NYS, Y., BAIN, M. & VAN IMMERSEEL, F. (Eds) Improving the safety and quality of eggs and egg products, Vol. 2: Egg safety and nutritional quality, pp. 272-288 (Cambridge, UK, Woodhead Publishing Ltd).Google Scholar
SIRRI, F., MELUZZI, A., TALLARICO, N., FRANCHINI, A. and IAFFALDANO, N. (2001) Flaxseed and marine algae as substitutes of fish oil in fortifying chicken eggs with n-3 PUFA. Proceedings of the IX European Symposium on the Quality of Eggs and Egg Products. Kusadasi, Turkey, pp. 217-222.Google Scholar
SOLOMON, S.E. (1991) Egg and Eggshell quality (London, Wolfe Publ. Ltd).Google Scholar
SUGINO, H., NITODA, T. and JUNEJA, L.R. (1997) General chemical composition of hen eggs, in: YAMAMOTO, T., JUNEJA, L.R., HATTA, H. & KIM, M. (Eds) Hen Eggs, pp. 13-24 (New York, London, Tokyo, CRC Press Boca Raton).Google Scholar
SURAI, P.F., IONOV, I.A., BUZHIN, A. and BUZHINA, N. (1995) Vitamin E and egg quality. Proceedings of the VI European Symposium on the Quality of Eggs and Egg Products. Zaragoza, Spain, pp. 387-394.Google Scholar
TAKAHASHI, H., SASAKI, O., NIRASAWA, K. and FURUKAWA, T. (2010) Association between ovocalyxin-32 gene haplotypes and eggshell quality traits in an F-2 intercross between two chicken lines divergently selected for eggshell strength. Animal Genetics 41: 541-544.CrossRefGoogle Scholar
TUISKULA-HAAVISTO, M., HONKATUKIA, M., VILKKI, J., DE KONING, D. J., SCHULMAN, N. F. and MAKI-TANILA, A. (2002) Mapping of quantitative trait loci affecting quality and production traits in egg layers. Poultry Science 81: 919-927.CrossRefGoogle ScholarPubMed
TYLER, C. (1964) Wihhelm von Nathusius 1821-1899 on avian eggshells, University of reading, Reading.Google Scholar
U.S. DEPARTMENT OF AGRICULTURE (USDA), (1995) U.S. standards, grades and weight classes for shell eggs, 56.200 et seq. (Washington, DC, USDA Agricultural Marketing Service).Google Scholar
VANI, B. and ZAYAS, J.F. (1995) Foaming properties of selected plant and animal proteins. Journal of Food Science 60: 1025-1028.CrossRefGoogle Scholar
WANG, Y., WANG, J., ZHOU, B. and LU, Q. (2009) Monitoring storage time and quality attribute of egg based on electronic nose. Analytica Chimica Acta 650: 183-188.Google ScholarPubMed
ZHAO, J., LIN, H., CHEN, Q., HUANG, X., SUN, Z. and ZHOU, F. (2010) Identification of egg's freshness using NIR and support vector data description. Journal of Food Engineering 98: 408-414.CrossRefGoogle Scholar