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Factors affecting poultry meat colour and consumer preferences - A review

Published online by Cambridge University Press:  25 April 2016

N. WIDEMAN ,
C.A. O'BRYAN  and
P.G. CRANDALL
N. WIDEMAN
Affiliation:
Department of Food Science, University of Arkansas, 2650 Young Ave., Fayetteville, AR 72704, USA
C.A. O'BRYAN
Affiliation:
Department of Food Science, University of Arkansas, 2650 Young Ave., Fayetteville, AR 72704, USA
P.G. CRANDALL*
Affiliation:
Department of Food Science, University of Arkansas, 2650 Young Ave., Fayetteville, AR 72704, USA
*
Corresponding author: [email protected]
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Abstract

Much of the dark meat from U.S. broilers continues to be exported to other countries because of local consumers’ long-standing and strong preference for white breast meat. In this review we will discuss what causes meat colour differences and how environmental and genetic factors influence the colour of poultry meat. It is well documented that the darker colour of leg/thigh meat is due to the larger amount of myoglobin and haem pigments, as well as a higher pH when compared to breast meat. Slaughtering older birds increases myoglobin content in the meat and selection of breeds for greater breast meat yield may be involved. Using a wheat-based diet tends to lighten the colour of breast meat but has less effect on the thigh meat. Several antimicrobials used in further processing can lead to either bleaching or a reddening of the meat. Changes to colour using chemical or physiological methods are theoretically possible, however may not be great enough to improve consumer acceptability. From a marketing perspective, increased media promotion of dark meat as being equal to white meat in healthiness and superior in flavour may have the greatest effect on increasing sales.

Keywords

poultry meat colourthigh meatconsumer preference
Type
Reviews
Information
World's Poultry Science Journal , Volume 72 , Issue 2 , June 2016 , pp. 353 - 366
Copyright
Copyright © World's Poultry Science Association 2016 

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References

ABDULLAH, A.Y., MUWALLA, M.M., MAHARMEH, H.O., MATARNEH, S.K. and ISHMAIS, M.A.A. (2010) Effects of strain on performance, and age at slaughter and duration of post-chilling aging on meat quality traits of broiler. Asian-Australasian Journal of Animal Science 23: 1645-1656.Google Scholar
AKIBA, Y., SATO, K., TAKAHASHI, K., MATSUSHITA, K., KOMIYAMA, H., TSUNEKAWA, H. and NAGAO, H. (2001) Meat colour modification in broiler chickens by feeding yeast Phaffia rhodozyma containing high concentrations of astaxanthin. Journal of Applied Poultry Research 10: 154-161.Google Scholar
ALLEN, C., RUSSELL, S. and FLETCHER, D. (1997) The relationship of broiler breast meat colour and pH to shelf-life and odor development. Poultry Science 76: 1042-1046.Google Scholar
ALLEN, C.D., FLETCHER, D.L., NORTHCUTT, J.K. and RUSSELL, S.M. (1998) The relationship of broiler breast colour to meat quality and shelf-life. Poultry Science 77: 361-366.Google Scholar
ALMASI, A., ANDRASSYNE, B.G., MILISITS, G., KUSTOSNE, P.O. and SUTO, Z. (2015) Effects of different rearing systems on muscle and meat quality traits of slow- and medium-growing male chickens. British Poultry Science 56: 320-324.Google Scholar
AMSA (2012) Meat colour measurement guidelines. Available at: http://www.meatscience.org/docs/default-source/publications-resources/Hot-Topics/download-the-ebook-format-pdf-of-the-meat-colour-measurement-guidelines.pdf?sfvrsn=0. Accessed 03 Sept 2015.Google Scholar
BALANGE, A.K. and BENJAKUL, S. (2009) Effect of oxidised tannic acid on the gel properties of mackerel (Rastrelliger kanagurta) mince and surimi prepared by different washing processes. Food Hydrocolloids 23: 1693-1701.CrossRefGoogle Scholar
BARBUT, S. (2001) Basic anatomy and muscle biology. Poultry Products Processing: An Industry Guide, CRC Press, pp. 31-60.Google Scholar
BERRI, C., WACRENIER, N., MILLET, N. and LE BIHAN-DUVAL, E. (2001) Effect of selection for improved body composition on muscle and meat characteristics of broilers from experimental and commercial lines. Poultry Science 80: 833-838.Google Scholar
BIANCHI, M., PETRACCI, M. and CAVANI, C. (2006) The Influence of genotype, market live weight, transportation, and holding conditions prior to slaughter on broiler breast meat colour. Poultry Science 85: 123-128.CrossRefGoogle Scholar
BOULIANNE, M. and KING, A.J. (1995) Biochemical and colour characteristics of skinless boneless pale chicken breast. Poultry Science 74: 1693-1698.CrossRefGoogle Scholar
BOULIANNE, M. and KING, A.J. (1998) Meat colour and biochemical characteristics of unacceptable dark-coloured broiler chicken carcasses. Journal of Food Science 63: 759-762.Google Scholar
BOWKER, B.C., ZHUANG, H. and BUHR, R.J. (2014) Impact of carcass scalding and chilling on muscle proteins and meat quality of broiler breast fillets. LWT Food Science and Technology 59: 156-162.Google Scholar
BREWER, V.B., KUTTAPPAN, V.A., EMMERT, J.L., MEULLENET, J.-F. and OWENS, C.M. (2012) Big-bird programs: Effect of strain, sex, and debone time on meat quality of broilers. Poultry Science 91: 248-254.Google Scholar
COX, N., MERCURI, A., JUVEN, B., THOMSON, J. and CHEW, V. (1974) Evaluation of succinic acid and heat to improve the microbiological quality of poultry meat. Journal of Food Science 39: 985-987.Google Scholar
DEBUT, M., BERRI, C., BAEZA, E., SELLIER, N., ARNOULD, C., GUEMENE, D., JEHL, N., BOUTTEN, B., JEGO, Y., BEAUMONT, C. and LE BIHAN-DUVAL, E. (2003) Variation of chicken technological meat quality in relation to genotype and preslaughter stress conditions. Poultry Science 82: 1829-1838.Google Scholar
DEL RÍO, E., PANIZO-MORÁN, M., PRIETO, M., ALONSO-CALLEJA, C. and CAPITA, R. (2007) Effect of various chemical decontamination treatments on natural microflora and sensory characteristics of poultry. International Journal of Food Microbiology 115: 268-280.Google Scholar
DU, M. and AHN, D.U. (2002) Effect of dietary conjugated linoleic acid on the growth rate of live birds and on the abdominal fat content and quality of broiler meat. Poultry Science 81: 428-433.CrossRefGoogle ScholarPubMed
ERS/USDA (2013) Assessing the growth of U.S. broiler and poultry meat exports. Available at: http://www.ers.usda.gov/media/1217411/ldpm-231-01-with-keywords.pdf. Accessed 18 Dec 2015.Google Scholar
ESHEL, G., SHEPON, A., MAKOV, T. and MILO, R. (2014) Land, irrigation water, greenhouse gas, and reactive nitrogen burdens of meat, eggs, and dairy production in the United States. Proceedings of the National Academy of Science U. S. A. 111: 11996-12001.Google Scholar
FLETCHER, D. (1999) Broiler breast meat colour variation, pH, and texture. Poultry Science 78: 1323-1327.CrossRefGoogle ScholarPubMed
FLETCHER, D. L., QIAO, M. and SMITH, D.P. (2000) The relationship of raw broiler breast meat colour and pH to cooked meat colour and pH. Poultry Science 79: 784-788.Google Scholar
FLEMING, B.K., FRONING, G.W. and YANG, T.S. (1991) Haem pigment levels in chicken broilers chilled in ice slush and air. Poultry Science 70: 2197-2200.Google Scholar
FLEMING, H.P., BLUMER, T.N. and CRAIG, H.B. (1960) Quantitative estimations of myoglobin and hemoglobin in beef muscle extracts. Journal of Animal Science 19:1164-1171.Google Scholar
FONT-I-FURNOLS, M. and GUERRERO, L. (20014) Consumer preference, behavior and perception about meat and meat products: An overview. Meat Science 98: 361-371.Google Scholar
FRONING, G.W. (1995) Colour of poultry meat. Poultry and Avian Biological Revues 6: 83-93.Google Scholar
FRONING, G.W., DADDARIO, J. and HARTUNG, T.E. (1968) Colour and myoglobin concentration in turkey meat as affected by age, sex and strain. Poultry Science 47:1827-1835.Google Scholar
GEORGIA DEPARTMENT OF AGRICULTURE (2015) Poultry market news. Available at: http://agr.georgia.gov/historical-data.aspx. Accessed 16 November 2015.Google Scholar
GIROLAMI, A., NAPOLITANO, F., FARAONE, D. and BRAGHIERI, A. (2013) Measurement of meat colour using a computer vision system. Meat Science 93: 111-118.Google Scholar
HALEY, M. (2001) Consumer demand for meat: the U.S. example. Available at: http://www.ers.usda.gov/media/293605/wrs011g_1_.pdf. Accessed 23 November 2015.Google Scholar
HOLLENDER, R., BENDER, F.G., JENKINS, R.K. and BLACK, C.L. (1993) Research note: consumer evaluation of chicken treated with a trisodium phosphate application during processing. Poultry Science 72: 755-759.Google Scholar
ISMAIL, I., HUDA, N. and FAZILAH, A. (2011) Surimi-like material from poultry meat and its potential as a surimi replacer. Asian Journal of Poultry Science 5: 1-12.CrossRefGoogle Scholar
JIANG, Z.Y., JIANG, S.Q., LIN, Y.C., XI, P.B., YU, D.Q. and WU, T.X. (2007) Effects of soybean isoflavone on growth performance, meat quality, and antioxidation in male broilers. Poultry Science 86: 1356-1362.CrossRefGoogle ScholarPubMed
KANG, S.P., EAST, A.R. and TRUJILLO, F.J. (2008) Colour vision system evaluation of bicolour fruit: A case study with ‘B74’ mango. Postharvest Biology and Technology 49: 77-85.CrossRefGoogle Scholar
KENNEDY, O.B., STEWART-KNOX, B.J., MITCHELL, P.C. and THURNHAM, D.I. (2005) Flesh colour dominates consumer preference for chicken. Appetite 44: 181-186.Google Scholar
KIM, J.S. and PARK, J.W. (2007) Mince from seafood processing by-product and surimi as food ingredients, in: SHAHIDI F. (Ed) Maximising the Value of Marine By-products, pp. 196-228 (Woodhead Publishing, Cambridge).Google Scholar
KIM, Y.J., LEE, G.D. and CHOI, I.H. (2014) Effects of dietary supplementation of red ginseng marc and alpha-tocopherol on the growth performance and meat quality of broiler chicken. Journal of the Science of Food and Agriculture 94: 1816-1821.CrossRefGoogle ScholarPubMed
KOLSARICI, N. and CANDOGAN, K. (1995) The effects of potassium sorbate and lactic acid on the shelf-life of vacuum-packed chicken meats. Poultry Science 74: 1884-1893.CrossRefGoogle ScholarPubMed
KRANEN, R., VAN KUPPEVELT, T., GOEDHART, H., VEERKAMP, C., LAMBOOY, E. and VEERKAMP, J. (1999) Hemoglobin and myoglobin content in muscles of broiler chickens. Poultry Science 78: 467-476.CrossRefGoogle ScholarPubMed
KRISTINSSON, H.G. and HULTIN, H.O. (2003) Changes in conformation and subunit assembly of cod myosin at low and high pH and after subsequent refolding. Journal of Agriculture and Food Chemistry 51: 7187-7196.Google Scholar
KRISTINSSON, H.G., THEODORE, A.E., DEMIR, N. and INGADOTTIR, B. (2005) A comparative study between acid- and alkali-aided processing and surimi processing for the recovery of proteins from channel catfish muscle. Journal of Food Science 70: C298-C306.Google Scholar
KUCUKYILMAZ, K., BOZKURT, M., CATLI, A.U., HERKEN, E.N., CINAR, M. and BINTAS, E. (2012) Chemical composition, fatty acid profile and colour of broiler meat as affected by organic and conventional rearing systems. South African Journal of Animal Science 42: 360-368.Google Scholar
LE BIHAN-DUVAL, E., MILLET, N. and REMIGNON, H. (1999) Broiler meat quality: effect of selection for increased carcass quality and estimates of genetic parameters. Poultry Science 78: 822-826.Google Scholar
LONERGAN, S., DEEB, N., FEDLER, C. and LAMONT, S. (2003) Breast meat quality and composition in unique chicken populations. Poultry Science 82: 1990-1994.CrossRefGoogle ScholarPubMed
LYON, B.G., SMITH, D.P., LYON, C.E. and SAVAGE, E.M. (2004) Effects of diet and feed withdrawal on the sensory descriptive and instrumental profiles of broiler breast fillets. Poultry Science 83: 275-281.Google Scholar
MAGDELAINE, P., SPIESS, M.P. and VALCESCHINI, E. (2008) Poultry meat consumption trends in Europe. World's Poultry Science Journal 64: 53-64.Google Scholar
MEHAFFEY, J.M., PRADHAN, S.P., MEULLENET, J.F., EMMERT, J.L. and OWENS, C.M. (2006) Meat quality evaluation of minimally aged broiler breast fillets from five commercial genetic strains. Poultry Science 85: 902-908.Google Scholar
MEILGAARD, M.C., CIVILLE, G.V. and CARR, B.T. (1991) Sensory Evaluation Techniques. Boca Raton, FL: CRC Press Inc.Google Scholar
MICHEL, L.M., PUNTER, P.H. and WISMER, W.V. (2011) Perceptual attributes of poultry and other meat products: a repertory grid application. Meat Science 87: 349-355.Google Scholar
MILLAR, S.J., MOSS, B.W. and STEVENSON, M.H. (2001) The effect of ionising radiation on the colour of leg and breast of poultry meat. Meat Science 55: 361-370.Google Scholar
MILLER, R.K. (1994) Sensory methods to evaluate muscle foods, in: KINSMAN, D.M. & KOTULA, A.W. (Eds) Muscle Foods (New York, NY: Chapman and Hall Publishers).Google Scholar
NAM, K.C., MIN, B.R., YAN, H., LEE, E.J., MENDONCA, A., WESLEY, I. and AHN, D.U. (2003) Effect of dietary vitamin E and irradiation on lipid oxidation, colour, and volatiles of fresh and previously frozen turkey breast patties . Meat Science 65: 513-521.Google Scholar
NASS (2014) Statistics by subject. Available at: http://www.nass.usda.gov/Statistics_by_Subject/. Accessed 15 Dec 2015.Google Scholar
NCC and NATIONAL CHICKEN COUNCIL (2012) Consumers speak about chicken breast meat/breast tenders. Chicken marketing seminar, http://www.nationalchickencouncil.org/wp-content/uploads/2012/08/2012-NCC-Consumer-Survey.pdf.Google Scholar
NGOKA, D.A., FRONING, G.W., LOWRY, S.R. and BABJI, A.S. (1982) Effects of sex, age, preslaughter factors, and holding conditions on the quality characteristics and chemical composition of turkey breast muscles. Poultry Science 61: 1996-2003.CrossRefGoogle Scholar
OMANA, D.A., MOAYEDI, V., XU, Y. and BETTI, M. (2010) Alkali-aided protein extraction from chicken dark meat: Textural properties and colour characteristics of recovered proteins. Poultry Science 89: 1056-1064.Google Scholar
PAPADAKIS, S.E., ABDUL-MALEK, S., KAMDEM, R.E. and YAM, K.L. (2000) A versatile and in-expensive technique for measuring colour of foods. Food Technology 5 (12): 48-51.Google Scholar
RESURRECCION, A.V.A. (2004) Sensory aspects of consumer choices for meat and meat products. Meat Science 66: 11-20.Google Scholar
RHEE, K.S. and ZIPRIN, Y.A. (1987) Lipid oxidation in retail beef, pork and chicken muscles as affected by concentrations of haem pigments and nonhaem iron and microsomal enzymic lipid peroxidation activity. Journal of Food Biochemistry 11: 1-15.CrossRefGoogle Scholar
RICKANSRUD, D.A. and HENRICKSON, R.L. (1967) Total pigments and myoglobin concentration in four bovine muscles. Journal of Food Science 32: 57-61.Google Scholar
RYU, Y.-C., RHEE, M.S., LEE, K.M. and KIM, B.C. (2005) Effects of different levels of dietary supplemental selenium on performance, lipid oxidation, and colour stability of broiler chicks. Poultry Science 84: 809-815.Google Scholar
SKRŘIVANOVÁ, E., MOLATOVA, Z., MATENOVA, M. and MAROUNEK, M. (2011) Inhibitory effect of organic acids on Arcobacters in culture and their use for control of Arcobacter butzleri on chicken skin. International Journal of Food Microbiology 144: 367-371.CrossRefGoogle Scholar
SMITH, D., LYON, C. and LYON, B. (2002) The effect of age, dietary carbohydrate source, and feed withdrawal on broiler breast fillet colour. Poultry Science 81: 1584-1588.Google Scholar
SOUZA, D.H., FREITAS, E.R., DOS SANTOS, E.O., CIPRIANO, R.M., FIGUEIREDO, C.W.S. and DANTAS, F.D.T. (2015) Inclusion of annatto seed by-product in diets containing sorghum for slow growth broilers. Ciencia e Agrotechnologia 39: 248-259.Google Scholar
THE HARRIS POLL (2010) EVOO and yummo! 30 Minute Meals is America's favorite cooking show. Available at: http://www.theharrispoll.com/business/EVOO_and_Yummo__30_Minute_Meals_is_America_s_Favorite_Cooking_Show.html. Accessed 17 November 2015.Google Scholar
UNDELAND, I., KELLEHER, S.D. and HULTIN, H.O. (2002) Recovery of functional proteins from herring (Clupea harengus) light muscle by an acid or alkaline solubilization process. Journal of Agriculture and Food Chemistry 50: 7371-7379.Google Scholar
USDA (2014) US beef industry statistics. Available at: http://www.ers.usda.gov/topics/animal-products/cattle-beef/statistics-information.aspx. Accessed 16 December 2015.Google Scholar
US POULTRY (2015) Economic data. Available at: http://www.uspoultry.org/economic_data/. Accessed 10 February 2016.Google Scholar
US POULTRY AND EGG ASSOCIATION (2014) Economic data. Available at: https://www.uspoultry.org/economic_data/. Accessed 17 November 2015.Google Scholar
WATTANACHANT, S., BENJAKUL, S. and LEDWARD, D.A. (2004) Composition, colour, and texture of Thai indigenous and broiler chicken muscles. Poultry Science 83:123-128.Google Scholar
WILLIAMS, W.D. (1992) Origin and impact of colour on consumer preference for food. Poultry Science 71:744-746.Google Scholar
WHO, WORLD HEALTH ORGANIZATION. INTERNATIONAL AGENCY FOR RESEARCH ON CANCER (IARC) (2015) Links between processed meat and colourectal cancer. Available at: http://www.who.int/mediacentre/news/statements/2015/processed-meat-cancer/en/. Accessed 23 November 2015.Google Scholar
YAM, K.L. and PAPADAKIS, S.E. (2004) A simple digital imaging methods for measuring and analyzing colour of food surfaces. Journal of Food Engineering 61: 137-142.Google Scholar
ZAMULA, E. (1985) Getting hooked on surimi. FDA Consumer. Available at: http://www.questia.com/googleScholar.qst?docId=5002117300. Accessed 11 Sept 2015.Google Scholar