Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-24T10:50:41.793Z Has data issue: false hasContentIssue false

Technological investigation into duck meat and its products - a potential alternative to chicken

Published online by Cambridge University Press:  15 October 2019

S. BISWAS
Affiliation:
Department of Livestock Products Technology, West Bengal University of Animal & Fishery Sciences, Kolkata 700 037, India
R. BANERJEE*
Affiliation:
Department of Livestock Products Technology, West Bengal University of Animal & Fishery Sciences, Kolkata 700 037, India
D. BHATTACHARYYA
Affiliation:
Department of Livestock Products Technology, West Bengal University of Animal & Fishery Sciences, Kolkata 700 037, India
G. PATRA
Affiliation:
Department of Livestock Products Technology, West Bengal University of Animal & Fishery Sciences, Kolkata 700 037, India
A.K. DAS
Affiliation:
Senior Scientist, ICAR-IVRI Eastern Regional Station, Kolkata 700 037, India
S.K. DAS
Affiliation:
Assistant Director, Research, DREF, West Bengal University of Animal & Fishery Sciences, Kolkata 700 037, India
*
Corresponding author: [email protected]
Get access

Abstract

Duck production has the potential to play a major role in agricultural economy. Asian countries alone contribute 84.2% of total duck meat produced in the world. Driven by the demand of processed foods among consumers, the global duck meat market is expected to grow at a steady pace, reaching a value of about $11.23 billion in the coming years. Duck meat has higher muscle fibre content in breast meat compared to chicken, and is considered as red meat. Moreover, due to a higher fat content (13.8%) than chicken and a stronger gamey flavour, duck meat can be less appreciated by the consumer. Development and diversification of ready-to-eat duck meat products is expected to increase consumption levels. Hence, the status of duck meat production, physicochemical properties, processing, including traditional products, and development of novel value-added ready-to-eat products from spent duck meat is discussed in detail to explore its importance as an alternative to chicken.

Type
Review
Copyright
Copyright © World's Poultry Science Association 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

ADAMSKI, M., BERNACKI, Z. and KUZNIACKA, J. (2005) The effects origin and sex on rearing results of ducks from two ancestral paternal strains. Acta Scientiarum Polonorum. Zootechnica 4: 13-18.Google Scholar
ALI, M., KANG, G.-H., YANG, H.-S., JEONG, J.-Y., HWANG, Y.-H., PARK, G.-B. and JOO, S.-T. (2007) A comparison of meat characteristics between duck and chicken breast. Asian-Australasian Journal of Animal Sciences 20: 1002-1006.Google Scholar
ARONAL, A., HUDA, N. and AHMAD, R. (2012) Amino acid and fatty acid profiles of peking and muscovy duck meat. International Journal of Poultry Science 11: 229-236.Google Scholar
BAEZA, E. (1995) The meat of duck: Production and main characteristics. INRA Production Animals 8: 117-125.Google Scholar
BAEZA, E. (2006) Effects of genotype, age and nutrition on intramuscular lipids and meat quality. Proceedings of the 2006 Symposium COA/INRA Scientific Cooperation in Agriculture. Tainan, Tainan, pp. 79-82.Google Scholar
BAHS (2017) Basic animal husbandry & fisheries statistics Annual Report - 2017, Government of India, Ministry of Agriculture & Farmers welfare, Department of Animal Husbandry, Dairying and Fisheries, Krishi Bhawan, New Delhi.Google Scholar
BHATTACHARYYA, D., BISWAS, S. and SINHAMAHAPATRA, M. (2004) A comparative study on duck sausages prepared from prime and non-prime cuts of spent duck. Indian Journal of Poultry Science 39: 78-81.Google Scholar
BHATTACHARYYA, D., SINHAMAHAPATRA, M. and BISWAS, S. (2007) Preparation of sausage from spent duck-an acceptability study. International Journal of Food Science Technology 42: 24-29.Google Scholar
BHATTACHARYYA, D., SINHAMAHAPATRA, M. and BISWAS, S. (2013) Effects of packaging materials and methods on physical properties and food safety of duck sausage. International Journal of Developmental Research 3: 032-040.Google Scholar
BISWAS, S., CHAKRABORTY, A., PATRA, G. and DHARGUPTA, A. (2011) Quality and acceptability of duck patties stored at ambient and refrigeration temperature. International Journal of Livestock Production 2: 001-006.Google Scholar
BISWAS, S., CHAKRABORTY, A. and SARKAR, S. (2006a) Comparison among the qualities of patties prepared from chicken broiler, spent hen and duck meats. The Journal of Poultry Science 43: 180-186.Google Scholar
BISWAS, S., VIJAYKUMAR, K.S., V., JANA, C., BHATTACHARYYA, D. and SINHAMAHAPATRA, M. (2006b) Effect of storage on duck meat sausages. Indian Journal of Poultry Science 41: 74-79.Google Scholar
CHARTRIN, P., METEAU, K., JUIN, H., BERNADET, M., GUY, G., LARZUL, C., REMIGNON, H., MOUROT, J., DUCLOS, M. and BAÉZA, E. (2006) Effects of intramuscular fat levels on sensory characteristics of duck breast meat. Poultry Science 85: 914-922.Google Scholar
CHEN, G., SONG, H. and MA, C. (2009) Aroma-active compounds of beijing roast duck. Flavour Fragrance Journal 24: 186-191.Google Scholar
COBOS, A., VEIGA, A. and DÍAZ, O. (2000) Chemical and fatty acid composition of meat and liver of wild ducks (anas platyrhynchos). Food Chemistry 68: 77-79.Google Scholar
DAUN, C. and ÅKESSON, B. (2004) Comparison of glutathione peroxidase activity, and of total and soluble selenium content in two muscles from chicken, turkey, duck, ostrich and lamb. Food Chemistry 85: 295-303.Google Scholar
ERISIR, Z., POYRAZ, O., ONBASILAR, E., ERDEM, E. and OKSUZTEPE, G. (2009) Effects of housing system, swimming pool and slaughter age on duck performance, carcass and meat characteristics. Journal of Animal and Veterinary Advances 8: 1864-1869.Google Scholar
ESTÉVEZ, M., MORCUENDE, D., VENTANAS, S. and CAVA, R. (2003) Analysis of volatiles in meat from iberian pigs and lean pigs after refrigeration and cooking by using spme-gc-ms. Journal of Agricultural and Food Chemistry 51: 3429-3435.Google Scholar
ETUK, I., OJEWOLA, G. and ABASIEKONG, S. (2006) Performance of muscovy ducks under three management systems in south eastern nigeria. International Journal of Poultry Science 5: 474-476.Google Scholar
FAO (2017) Food and Agriculture Organization of The United Nations Statistics Division database.Google Scholar
FAOSTAT (2017) Food and Agriculture Organisation of the United Nations. FAOSTAT Database on Agriculture. Rome, Italy: 2017Google Scholar
HUANG, C.-C., WANG, T.-Y., HUANG, A.J.-F. and LIN, S.C.-C. (2001) Studies on the quality of restructured pressed smoked duck steak. Asian-Australasian Journal of Animal Sciences 14: 1316-1320.Google Scholar
HUDA, N., PUTRA, A. and AHMAD, R. (2011) Potential application of duck meat for development of processed meat products. Current Research in Poultry Science 1: 1-11.Google Scholar
JATURASITHA, S., SRIKANCHAI, T., KREUZER, M. and WICKE, M. (2008) Differences in carcass and meat characteristics between chicken indigenous to northern thailand (black-boned and thai native) and imported extensive breeds (bresse and rhode island red). Poultry Science 87: 160-169.Google Scholar
JOSEPH, J., BALOGUN, O. and FAMUYIWA, M. (1992) Carcass evaluation and organoleptic assessment of quality attributes of some selected nigerian birds. Bulletin of Animal Health Production in Africa 40: 97-102.Google Scholar
KHAN, M.A., ALI, S., ABID, M., AHMAD, H., ZHANG, L., TUME, R.K. and ZHOU, G. (2014) Enhanced texture, yield and safety of a ready-to-eat salted duck meat product using a high pressure-heat process. Innovative Food Science & Emerging Technologies 21: 50-57.Google Scholar
KHAN, M.A., ALI, S., YANG, H., KAMBOH, A.A., AHMAD, Z., TUME, R.K. and ZHOU, G. (2019) Improvement of color, texture and food safety of ready-to-eat high pressure-heat treated duck breast. Food Chemistry 277: 646-654.Google Scholar
KIM, T.-K., SHIM, J.-Y., HWANG, K.-E., KIM, Y.-B., SUNG, J.-M., PAIK, H.-D. and CHOI, Y. -S. (2018) Effect of hydrocolloids on the quality of restructured hams with duck skin. Poultry Science 97: 4442-4449.Google Scholar
KUMAR, R., BISWAS, S., BHATTACHARYYA, D., RAM, M. and SINGH, V. (2014) Study on nuggets prepared from different ratios of spent duck and spent hen meat. Indian Journal of Poultry Science 49: 228-230.Google Scholar
KUMAR, R., BISWAS, S., SINGH, V., RAM, M. and KALIMUDDIN, M. (2016) Comparison of physico-chemical and sensory quality of sausages prepared from spent duck and hen meat. Exploratory Animal and Medical Research 6: 89-93.Google Scholar
LAVILLA, M., OLABARRIETA, I., LASA, D., MARTÍNEZ, B., SERRANO, G., ADURIZ, A.L. and MARTÍNEZ-DE-MARAÑÓN, I. (2019) Improvement of gastronomical properties of duck foie gras by high hydrostatic pressure. International Journal of Gastronomy Food Science 17: 100155.Google Scholar
LIU, C., PAN, D., YE, Y. and CAO, J. (2013) ¹H NMR and multivariate data analysis of the relationship between the age and quality of duck meat. Food Chemistry 141: 1281-1286.Google Scholar
LORENZO, J., PURRIÑOS, L., TEMPERAN, S., BERMÚDEZ, R., TALLÓN, S. and FRANCO, D. (2011) Physicochemical and nutritional composition of dry-cured duck breast. Poultry Science 90: 931-940.Google Scholar
MARUYAMA, K., SOLOMON, M.B. and ONO, Y. (1996) Testosterone on turkey growth: 2. Effects of castration and testosterone implant on carcass yield, carcass conformation and chemical composition. Japanese Poultry Science 33: 153-161.Google Scholar
MAZANOWSKI, A. and BERNACKI, Z. (2004) Comparison of meat traits, carcass slaughter value and chemical composition of duck meat from three maternal strains. Annals of Animal Sciences 31: 39-54.Google Scholar
MUTHIA, D., NURUL, H. and NORYATI, I. (2010) The effects of tapioca, wheat, sago and potato flours on the physicochemical and sensory properties of duck sausage. International Food Research Journal 17: 877-884.Google Scholar
NURKHOERIYATI, T., HUDA, N. and AHMAD, R. (2011) Gelation properties of spent duck meat surimi-like material produced using acid-alkaline solubilization methods. Journal of Food Science 76: S48-S55.Google Scholar
OMOJOLA, A. (2007) Carcass and organoleptic characteristics of duck meat as influenced by breed and sex. International Journal of Poultry Science 6: 329-334.Google Scholar
ORDÓÑEZ, J.A., HIERRO, E.M., BRUNA, J.M. and HOZ, L.D.L. (1999) Changes in the components of dry-fermented sausages during ripening. Critical Reviews in Food Science and Nutrition 39: 329-367.Google Scholar
OTEKU, I., IGENE, J. and YESSUF, I. (2006) An assessment of the factors influencing the consumption of duck meat in Southern Nigeria. Pakistan Journal of Nutrition 5: 474-477.Google Scholar
RAMADHAN, K., HUDA, N. and AHMAD, R. (2012) Physicochemical and sensory characteristics of burger made from duck surimi-like material. Poultry Science 91: 2316-2323.Google Scholar
RAMADHAN, K., HUDA, N. and AHMAD, R. (2014) Effect of number and washing solutions on functional properties of surimi-like material from duck meat. Journal of Food Science and Technology 51: 256-266.Google Scholar
RUSSELL, E., LYNCH, A., GALVIN, K., LYNCH, P. and KERRY, J. (2003) Quality of raw, frozen and cooked duck as meat affected by dietary fat and tocopheryl acetate supplementation. International Journal of Poultry Science 5: 324-334.Google Scholar
SAUCIER, L., GIL, M., SANCHEZ-CARILLO, F. and RATTI, C. (2016) Safety of duck foie gras processed under less severe sterilization treatments. Meat Science: 184.Google Scholar
SMITH, D., FLETCHER, D., BUHR, R. and BEYER, R. (1993) Pekin duckling and broiler chicken pectoralis muscle structure and composition. Poultry Science 72: 202-208.Google Scholar
SMITH, D., FLETCHER, D. and PAPA, C. (1992) Post-mortem biochemistry of pekin duckling and broiler chicken pectoralis muscle. Poultry Science 71: 1768-1772.Google Scholar
SOLOMON, J., AUSTIN, R., CUMBERBATCH, R., GONSALVES, J. and SEAFORTH, E. (2006) A comparison of live weight and carcass gain of pekin, kunshan and muscovy ducks on a commercial ration. Livestock Research for Rural Development 18: 154.Google Scholar
SONCIN, S., CHIESA, L.M., CANTONI, C. and BIONDI, P.A. (2007) Preliminary study of the volatile fraction in the raw meat of pork, duck and goose. Journal of Food Composition and Analysis. 20: 436-439.Google Scholar
STEIN, B. (2012) Introduction to commercial duck farming. Factsheet, department of primary industries, http://www.Dpi.Nsw.Gov.Au/__data/assets/pdf_file/0009/442854/introduction-to-commercial-duck-farming.Pdf. Accessed 10.07.19, Journal.Google Scholar
TAI, C. and TAI, J.-J.L. (2001) Future prospects of duck production in asia. The Journal of Poultry Science 38: 99-112.Google Scholar
USDA (2006a) National Nutrient Database for Standard Reference, release 19. http://www.nalusde.gov/fnic/foodcomp/cgi-bin/list_nut_edit.pl. Accessed 19.07.19.Google Scholar
USDA (2006b) Duck and goose from farm to table. US. United States Department of Agriculture Food Safety and Inspection Service. http://www.fsis.usda.gov/factsheets/Duck_&_Goose_from_Farm_to_Table/index.asp.Google Scholar
VIJAYAKUMAR, K. and BISWAS, S. (2006) Quality and storage stability of enrobed duck cutlet. Journal of Food Science Technology 43: 154-156.Google Scholar
WANG, D., XU, W., XU, X., ZHOU, G., ZHU, Y., LI, C. and YANG, M. (2009) Determination of intramuscular phospholipid classes and molecular species in gaoyou duck. Food Chemistry 112: 150-155.Google Scholar
WAWRO, K., WILKIEWICZ-WAWRO, E., KLECZEK, K. and BRZOZOWSKI, W. (2004) Slaughter value and meat quality of muscovy ducks, pekin ducks and their crossbreeds, and evaluation of the heterosis effect. Archives Animal Breeding 47: 287-299.Google Scholar
WU, C.M. and LIOU, S.E. (1992) Volatile components of water-boiled duck meat and cantonese style roasted duck. Journal of Agriculture and Food Chemistry 40: 838-841.Google Scholar
XU, W., XU, X., ZHOU, G., WANG, D. and LI, C. (2008) Changes of intramuscular phospholipids and free fatty acids during the processing of nanjing dry-cured duck. Food Chemistry 110: 279-284.Google Scholar
YANG, H., MA, C., QIAO, F., SONG, Y. and DU, M. (2005) Lipolysis in intramuscular lipids during processing of traditional xuanwei ham. Meat Science 71: 670-675.Google Scholar
YANG, H.S., ALI, M.S., JEONG, J.Y., MOON, S.H., HWANG, Y.H., PARK, G.B. and JOO, S.T. (2009) Properties of duck meat sausages supplemented with cereal flours. Poultry Science 88:1452-1458Google Scholar
ZHOU, X., XIE, F., WANG, Y., TANG, W., ZHOU, Y. and XIAO, Y. (2014) Evaluation of antioxidant activities of extract from beijing roast duck. Food Science Technology Research 20: 449-457.Google Scholar