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History, changing scenarios and future strategies to induce moulting in laying hens

Published online by Cambridge University Press:  07 May 2008

M. YOUSAF*
Affiliation:
School of Agriculture, Food and Rural Development, Newcastle University, Newcastle upon Tyne, NE1 7RU, United Kingdom
A.S. CHAUDHRY
Affiliation:
School of Agriculture, Food and Rural Development, Newcastle University, Newcastle upon Tyne, NE1 7RU, United Kingdom
*
Corresponding author: [email protected]
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Abstract

Moulting is a natural phenomenon in birds during which they replace old plumage with new feathers, reduce feed intake, lose body weight and suspend reproduction. Moulting in laying hens can be induced by using photoperiods, feed deprivation or restriction or diets containing minerals or variable amounts of other ingredients. Induced moulting can result in higher egg production and improved quality. It reduces mortality, production costs and investments in new farms and hatcheries. While feed withdrawal has been a most effective way to induce moult in poultry birds, it is illegal on welfare grounds in the UK and Europe. This may have implications for the global poultry industry. Therefore, efforts to find a non feed removal method as a desirable alternative to induce moulting in poultry birds are underway in different countries. This paper reviews the history of induced moulting and its future implications by examining different methods that have been tested in the past and their potential to become a more acceptable alternative to feed removal method of inducing moulting in laying hens.

Type
Review Article
Copyright
Copyright © World's Poultry Science Association 2008

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References

ADAMS, J.L. (1955) Progesterone-induced unseasonable moult in single comb White Leghorn pullets. Poultry Science 34: 702-707.Google Scholar
ADAMS, J.L. (1956) A comparison of different methods of progesterone administration to the fowl in affecting egg production and moult. Poultry Science 35: 323-326.CrossRefGoogle Scholar
AHMED, A.M.H., RODRIGUENZ-NAVARRO, A.B., VIDAL, M.L., GOUTRON, J., GARCIA-RUIZ, J.M. and NYS, Y. (2005) Changes in the eggshell properties, crystallographic texture and in matrix proteins induced by moult in hens. British Poultry Science 46: 268-279.Google Scholar
AVMA, (2002) New position on induced molting wins the favour. Journal of the American Veterinary Medical Association (www.avma.org.onlnews/javma/sep02/020901d.asp).Google Scholar
BAR, A., RAZAPHKOVSKY, V., WAX, E. and MALKA, Y. (2001) Effect of age at molting on post-molting performance. Poultry Science 80: 874-878.CrossRefGoogle Scholar
BAR, A., RAZAPHKOVSKY, V., SHINDER, V. and VAX, E. (2003) Alternative procedures for molt induction: Practical aspects. Poultry Science 82: 543-550.CrossRefGoogle ScholarPubMed
BATTLEY, P.F., PIERSMA, T., DIETZ, M.W., TANG, S., DEKINGA, A. and HULSMAN, K. (2000) Empirical evidence for differential organ reductions during trans-oceanic bird flight. Proceedings of the Royal Society 267: 191195.CrossRefGoogle ScholarPubMed
BELL, D.D., SWANSON, M.H. and JOHNSTON, G. (1976) A comparison of force molting methods. Progress in Poultry. University of California Cooperative Extension, Davis, CA.Google Scholar
BELL, D.D. (2003) Historical and current moulting practices in the U.S. table egg industry. Poultry Science 82: 965-970.Google Scholar
BELL, D.D., CHASE, B., DOUGLASS, A., HESTER, P., MENCH, J., NEWBERRY, R., SHEA-MOORE, M., STANKER, L., SWANSON, J. and ARMSTRONG, J. (2004) UEP uses scientific approach in its establishment of welfare guidelines. Feedstuffs 76(1): 13-21.Google Scholar
BERRY, W.D. (2003) The physiology of induced molting. Poultry Science 82: 971-980.CrossRefGoogle ScholarPubMed
BIGGS, P.E., PERSIA, M.E., KOELKEBECK, K.W. and PARSONS, C.M. (2004) Further evaluation of non feed removal methods for moulting programs. Poultry Science 83: 745-752.CrossRefGoogle Scholar
BRAKE, J. and THAXTON, P. (1979) Physiological changes in caged layers during a forced moult. 1. Body temperature and selected blood constituents. Poultry Science 58: 699-707.Google Scholar
BREEDING, S.W., BRAKE, J. and GARLICH, J.D. (1992) Moult induced by dietary zinc in a low calcium diet. Poultry Science 71: 168-180.CrossRefGoogle Scholar
BURKE, W.H. and ATTIA, Y.A. (1994) Moulting single comb White Leghorns with the use of the Lupron Depot formulation of leuprolide acetate. Poultry Science 73: 1226-1232.CrossRefGoogle ScholarPubMed
BURTON, M. and BURTON, R. (1980). The New International Wildlife Encyclopedia. N.C.L.C. Limited, London UK.Google Scholar
BUTLER, P.J. and WOAKES, A.J. (1990) The physiology of bird flight. In: Bird Migration (ed. E. Gwinner), pp. 300–318. Berlin: Springer.Google Scholar
CANTOR, A.H. and JOHNSON, T.H. (1984) Inducing pauses in egg production of Japanese quail with dietary zinc. Poultry Science 63 (Suppl. 1): 10 (Abstr.).Google Scholar
CHOWDHURY, V.S., NOSHIBORI, M. and YOSHIMURA, Y. (2004) Changes of the mRNA expression of TGFβ receptor types II and III in the interior pituitary during induced molting in hens. Journal of Poultry Science 41: 140-146.CrossRefGoogle Scholar
DAVIS, G.K. (1974) High level copper feeding of swine and poultry. Federation Proceedings of American Societies for Experimental Biology 33: 1194-1196.Google Scholar
DECUYPERE, E. and VERHEYEN, G. (1986) Physiological basis of induced molting and tissue regeneration in fowls. World's Poultry Science Journal 42: 56-68.Google Scholar
DICKERMAN, R.W. and BAHR, J.M. (1989) Moult induced by gonadotrophin releasing hormone agonist as a model for studying endocrine mechanisms of moulting in laying hens. Poultry Science 68: 1402-1408.Google Scholar
DONALSON, L.M., KIM, W.K., WOODWARD, C.L., HERRERA, P., KUBENA, L.F., NISBET, D.J. and RICKE, S.C. (2005) Utilizing different ratios of alfalfa and layer ration for molt induction and performance in commercial laying hens. Poultry Science 84: 362-369.Google Scholar
EDGE, S. (1998) Moulting laying hens. ADAS Gleadthorpe Research Centre, Mansfield, Notts, UK.Google Scholar
EL-DEEK, A.A. and AL-HARTHI, M.A. (2004) Postmoult performance of broiler breeder hens associated with moult induced by feed restriction, high dietary zinc and fasting. International Journal of Poultry Science 3(7): 456-462.Google Scholar
ETCHES, R.J., WILLIAMS, J.B. and RZASA, J. (1983) Corticosterone and nutritionally induced ovarian regression in the hen. Poultry Science 62: 1417 (Abstr.).Google Scholar
ETCHES, R.J. (1984) Maturation of ovarian follicles in Cynnghan. Reproductive Biology of Poultry pp. 51-73.Google Scholar
FURR, B.J.A., BONEY, R.C., ENGLAND, F.J. and CUNNINGHAM, F.J. (1973) Luteinizing hormone and progesterone in peripheral blood during the ovulatory cycle of the hen (Gallus domesticus). Endocrinology 57: 159-169.CrossRefGoogle ScholarPubMed
GAST, R.K. and RICKE, S.C. (2003) Symposium: Current and future prospects for induced moulting in laying hens. Poultry Science 82: 964.Google Scholar
GRIMINGER, P. (1977) Effect of dietary copper sulphate on egg production and shell thickness. Poultry Science 56: 359-361.CrossRefGoogle Scholar
HANSEN, R.S. (1960) The effect of method of force moulting on reproductive performance of chickens. Poultry Science 39: 1257 (Abstr.).Google Scholar
HANSEN, R.S. (1967) Periodic forced molting for a two-year lay. In: Pacific Poultryman (July), Watt Publishing, Mt. Morris, IL.pp. 24, 25, 60.Google Scholar
HARMS, R.H. (1981) Effect of removing salt, sodium, or chloride from the diet of commercial layers. Poultry Science 70: 333-336.Google Scholar
HEMBREE, D.J., ADAMS, A.W. and CRAIJ, J.V. (1980) Effects of force moulting by conventional and experimental light restriction method on performance and agonistic behaviour of hens. Poultry Science 59: 215-223.CrossRefGoogle Scholar
HERREMANS, M., VERHEYEN, M. and DECUYPERE, B. (1988) Effect of temperature during induced moulting on plumage renewal and subsequent production. British Poultry Science 29: 853-861.CrossRefGoogle ScholarPubMed
HOLT, P.S. (2003) Moulting and Salmonella enteritidis infection: The problem and some solutions. Poultry Science 82: 1008-1010.Google Scholar
HUSSEIN, A.S. (1996) Induced moulting procedures in laying fowl. World's Poultry Science Journal 52: 175-187.CrossRefGoogle Scholar
HUSSEIN, A.S., CANTOR, A.H. and JOHNSON, T.H. (1988) Use of high dietary levels of aluminium and zinc for inducing pauses in egg production of Japanese quails. Poultry Science 67: 1157-1165.Google Scholar
HUSSEIN, A.S., CANTOR, A.H. and JOHNSON, T.H. (1989) Comparison of the use of dietary aluminium with the use of feed restriction for forced moulting laying hens. Poultry Science 68: 891-896.CrossRefGoogle Scholar
JOHNSON, A.L. and VAN TIENHOVEN, A. (1981) Plasma concentrations of sex steroids and LH during the ovulatory cycle of the hen, Gallus domesticus. Biology of Reproduction 23: 386-393.CrossRefGoogle Scholar
KESHAVARZ, K. and QUIMBY, F.W. (2002) An investigation of different moulting techniques with an emphasis on animal welfare. Journal of Applied Poultry Research 11: 54-67.Google Scholar
KHOSHOEI, E.A. and KHAJALI, F. (2006) Alternative induced-moulting methods for continuous feed withdrawal and their influence on postmoult performance of laying hens. International Journal of Poultry Science 3(7): 47-50.Google Scholar
KIM, W.K., DONALSON, L.M., MITCHELL, A.D., KUBENA, L.F., NISBET, D.J. and RICKE, S.C. (2006) Effects of alfalfa and fructooligosaccharide on molting parameters and bone qualities using dual energy X-ray absorptiometry and conventional bone assays. Poultry Science 85: 15-20.Google Scholar
KOCH, J.M., MORITZ, J.S., LAY, D.C. and WILSON, M.E. (2005a) Melengestrol acetate in experimental diets as an effective alternative to induce a decline in egg production and reversible regression of the reproductive tract in laying hens. I. Determining an effective concentration of melengestrol acetate. Poultry Science 84: 1750-1756.CrossRefGoogle Scholar
KOCH, J.M., MORITZ, J.S., SMITH, D.L., LAY, D.C. and WILSON, M.E. (2005b) Melengestrol acetate as an effective alternative to induce a decline in egg production and reversible regression of the reproductive tract in laying hens. II. Effects on postmolt egg quality. Poultry Science 84: 1757-1762.Google Scholar
KOCH, J.M., LAY, D.C., MACMUNN, K.A., MORITZ, J.S. and WILSON, M.E. (2007) Motivation of hens to obtain feed during a molt induced by feed withdrawal, wheat middlings or melengestrol acetate. Poultry Science 86: 614-620.Google Scholar
KOELKEBECK, K.W., PARSONS, C.M., LEEPER, R.W. and WANG, X. (1993) Effect of supplementation of a low corn moult diet with amino acids on early postmoult laying hen performance. Poultry Science 72: 1528-1536.Google Scholar
KOELKEBECK, K.W., PARSONS, C.M., DOUGLAS, M.W., LEEPER, R.W., JIN, S., WANG, S., ZHANG, Y. and FERNANDEZ, S. (2001) Early postmolt performance of laying hens fed a low-protein corn molt diet supplemented with spent hen meal. Poultry Science 80: 353-357.Google Scholar
KOELKEBECK, K.W. and ANDERSON, K.E. (2007) Molting layers-alternative methods and their effectiveness. Poultry Science 86: 1260-1264.Google Scholar
KUBENA, L.F., BYRD, J.A., MOORE, R.W., RICKE, S.C. and NISBET, D.J. (2005) Effects of drinking water treatment on susceptibility of laying hens to Salmonella enteritidis during forced moult. Poultry Science 84: 204-211.Google Scholar
KUENZEL, W.J., WIDEMAN, R.F., CHAPMAN, M., GOLDEN, C. and HOOGE, D.M. (2005) A practical method for induced moulting of caged layers that combines full access to feed and water, thyroactive protein, and short day length. World's Poultry Science Journal 61: 599-624.Google Scholar
LE MAHO, Y. (1977) The emperor penguin: A strategy to live and breed in the cold. American Science Journal 65: 680–693.Google Scholar
LIPSTEIN, B. and HURWITZ, S. (1982) The nutritional value of sewage-grown, alum-flocculated micractnium algae in broiler and layer diet. Poultry Science 60: 2628-2638.CrossRefGoogle Scholar
LOFTS, B. and MURTON, R.K. (1972) Reproduction in birds. Avian biology. Academic press, New York.Google Scholar
MARTIN, G.A., MORRIS, T.B., GEHLE, M.H. and HARWOOD, D.G. (1973) Force- molting by limiting calcium intake. Poultry Science 52: 2058.Google Scholar
MASHALY, M.M. and WENTWORTH, B.C. (1974) A profile of progesterone in turkey sera. Poultry Science 53: 2030-2035.Google Scholar
MAZZUCO, H. and HESTER, P.Y. (2005) The effect of an induced moult and a second cycle of lay on skeletal integrity of White Leghorns. Poultry Science 84: 771-781.Google Scholar
MCCORMICK, C.C. and CUNNINGHAM, D.L. (1987) Performance and physiological profiles of high dietary zinc and fasting as methods of inducing a forced rest: direct comparison. Poultry Science 66: 1007-1013.Google Scholar
MCREYNOLDS, J.L., MOORE, R.W., KUBENA, L.F, BYRD, J.A., WOODWARD, C.L., NISBET, D.J. and RICKE, S.C. (2006) Effect of various combinations of alfalfa and standard layer diet on susceptibility of laying hens to Salmonella enteritidis during forced molt. Poultry Science 85: 1123-1128.CrossRefGoogle ScholarPubMed
MOORE, R.W., PARK, S.Y., KUBENA, L.F., BYRD, J.A., MCREYNOLDS, J.L., BURNHAM, M.R., HUME, M.E., BIRKHOLD, S.G., NISBET, D.J. and RICKE, S.C. (2004) Comparison of zinc acetate and propionate addition on gastrointestinal tract fermentation and susceptibility of laying hens to Salmonella enteritidis during forced molt. Poultry Science 83: 1276-1286.Google Scholar
MROSOVSKY, N. and SHERRY, D. (1980) Animal anorexias. Science 207: 837-842.Google Scholar
NABER, E.C., LATSHAW, J.D. and MARSH, G.A. (1984) Effectiveness of low sodium diets for recycling of egg production type hens. Poultry Science 63: 2419-2429.Google Scholar
OGUIKE, M.A., IGBOELI, G., IBE, S.N. and UZOUKWU, M. (2004) Effect of day length and feed/water regime on induction of feather moult and subsequent laying performance in the domestic fowl. International Journal of Poultry Science 3 (8): 507-512.Google Scholar
OCAK, N., SARICA, M., ERENER, G. and GARPOGLU, A.V. (2004) The effect of body weight prior to moulting in brown laying hens on egg yield and quality during second production cycle. International Journal of Poultry Science 3 (12): 768-772.Google Scholar
PEARCE, J., JACKSON, N. and STEVENSON, M.H. (1983) The effects of dietary intake and of dietary concentration of copper sulphate on the laying domestic fowl: effects on some aspects of lipid, carbohydrates and amino acid metabolism. British Poultry Science 24: 337-348.CrossRefGoogle ScholarPubMed
PENNINGTON, J.T. and CALLOWAY, D.H. (1973) Copper content of foods. Journal of American Dietary Association 63: 143-153.Google Scholar
PETHES, G.Y., SZELENYI, A. and PEEZELY, P. (1982) Changes in the plasma concentrations of thyroid hormones and sexual steroids during forced moult of male and female domestic chickens. Acta Veterineria Academica Hungarica 30: 193-201.Google Scholar
PIERSMA, T. and BAKER, A.J. (2000) Life history characteristics and the conservation of migratory shorebirds. In: Behaviour and Conservation (ed. L.M. Gosling and W.J. Sutherland), pp. 105–124. Cambridge: Cambridge University Press.Google Scholar
QUEEN, W.H., CHRISTENSEN, V.L. and MAY, J.D. (1997) Supplemental thyroid hormone and moulting in turkey breeder hens. Poultry Science 76: 887-893.Google Scholar
RICE, J.E. (1905) In: The Feeding of Poultry; The Poultry Book. W.D. Johnson and G.O. Brown, ed. Doubleday, New York.Google Scholar
RICE, J.E., NIXON, C. and ROGERS, C.A. (1908) The moulting of fowls. Bulletin No. 258. Cornell University, Ithaca, NY.Google Scholar
RICKE, S.C., KWON, Y.M., WOODWARD, C.L., BYRD, J.A., NISBET, D.J. and KUBENA, L.F. (2001) Limitation of Salmonella enteritidis colonization by diets containing low calcium and low zinc. Poultry Science 80 (1): 262 (Abstr.).Google Scholar
RICKE, S.C. (2003) The gastrointestinal tract ecology of salmonella enteritidis colonization in molting hens. Poultry Science 82: 1003-1007.Google Scholar
SAID, M.W., SULLIVAN, T.W., BIRD, H.R. and SUNDE, M.L. (1984) A comparison of the effect of two force moulting methods on performance of two commercial strains of laying hens. Poultry Science 63: 2399-2403.Google Scholar
SEKIMOTO, K., IMAI, K., SUZUKI, M., TAKIKAWA, H., HOSHINO, N. and TOTSUKA, K. (1987) Thyroxin-induced moulting and gonadal function in laying hens. Poultry Science 66: 752-756.Google Scholar
SHERRY, D.F., MROSOVSKY, N. and HOGAN, J.A. (1980) Weight loss and anorexia during incubation in birds. Journal of Comparative Physiology and Psychology 94: 89-98.Google Scholar
STAKE, P.E., FREDERICKSON, T.N., OKULICZ, W., SHIPPEE, R.L. and FOURNIER, D.J. (1979) Tamoxifen induced forced-rest/molt in laying hens. Poultry Science 58:1111Google Scholar
STEVENSON, M.H. and JACKSON, N. (1984) Comparison of dietary hydrated copper sulphate, dietary zinc oxide and a direct method for inducing moult in laying hens. British Poultry Science 25: 505-517.Google Scholar
SWANSON, M.H. and BELL, D.D. (1974a) Force molting of chickens-I Introduction. Leaflet 2649. University of California, Davis, CA.Google Scholar
SWANSON, M.H. and BELL, D.D. (1974b). Force molting of chickens. 2. Methods. Univ. California Coop. Ext. Bull. AXT-411.Google Scholar
UEP, , 2006. United Egg Producers animal husbandry guidelines for U.S. egg laying flocks. 2006 edition.Google Scholar
VAN TIENHOVEN, A. (1981) Neuroendocrinology of avian reproduction with special emphasis on the reproductive cycle of the fowl (Gallus domesticus). World's Poultry Science Journal 37: 155-176.Google Scholar
VERHEYEN, G., DECUYPERE, E., KUHN, E.R., FONTAINE, G. and DE GROOTE, G. (1983a) Moult induction in the hen. Effect of different methods on some performance traits and on thyroid hormone, prolactin. Ca, P, Na, and protein concentrations in blood serum. Reeub de I, Agriculture 36: 1535-1559.Google Scholar
WEBSTER, A.B. (2003) Physiology and behavior of the hen during induced moult. Poultry Science 82: 992-1002.Google Scholar
WOODWARD, C.L., KWON, Y.M., KUBENA, L.F., BYRD, J.A., MOORE, R.W., NISBET, D.J. and RICKE, S.C. (2005) Reduction of Salmonella enteritidis colonization and invasion by an alfalfa diet during moult in Leghorn hens. Poultry Science 84: 185-193.Google Scholar
YOUSAF, M. (1996) The impact of induced moult on the hormonal and haematochemical profile of the layers in the third production cycle. M.Sc. Thesis, Dept. of Poultry Husbandry Univ. of Agri., Faisalabad, Pakistan.Google Scholar
YOUSAF, M., AHMAD, N., AKRAM, M., ZIA-UR-REHAMAN, (1996) Effect of molting on the haematochemical and hormonal changes in layers reared under different management conditions. Proceedings of Poultry Congress, New Delhi, India, Sept. 5, 1996.Google Scholar
YOUSAF, M. (1998) Comparative study of induced moult methods in relation to plumage renewal and productive performance of layers under cage and litter floor systems. Ph.D. thesis, Department of Poultry Science, University of Agriculture, Faisalabad, Pakistan.Google Scholar
YOUSAF, M., AHMAD, N., AKRAM, M., ZIA-UR-REHAMAN, (1998) Changes in the concentration of various blood plasma parameters and hormones as influenced by induced moult in White Leghorn layers. Pakistan Veterinary Journal 18 (1): 36-42.Google Scholar
YOUSAF, M. (2004) Influence of different copper and aluminium levels on feather renewal and production characteristics of the layers in the second production cycle. Research project report submitted to Pakistan Science Foundation, Islamabad, Pakistan.Google Scholar
YOUSAF, M. (2005) Secrets of Feather Development. World Poultry 21(3):16-17.Google Scholar
YOUSAF, M. (2006a) Influence of different copper and aluminium levels on organ weights, feather renewal and production performance of molted layers. Pakistan Journal of Arid Agriculture 9(1): 35-39.Google Scholar
YOUSAF, M. and AHMAD, N. (2006) Effects of housing systems on productive performance of commercial layers following induced molting by aluminium oxide supplementation. Pakistan Veterinary Journal 26(3): 101-104.Google Scholar
YOUSAF, M. (2006b) Induced molting: Tips for success. Poultry International 45(4): 36-40.Google Scholar
ZIMMERMANN, N.N., ANDREWS, D.K. and MAGGINNIS, J. (1987) Comparison of several induced moulting methods on subsequent performance of Single Comb White Leghorn hens. Poultry Science 66: 408-417.Google Scholar