羽毛断层带(Fault Bars)的形成机制及在家禽福利评价中的研究进展

doi:10.11843/j.issn.0366-6964.2025.12.003

Abstract

Abstract: Fault bars are structural deformities formed during feather growth due to disrupted keratin synthesis, leading to weakened or fractured barbules, loss of vane integrity, and consequently impaired flight capacity and survival adaptability in birds. Studies on wild birds have shown that the occurrence of feather fault bars may be associated with multiple factors, such as nutritional deficiencies, environmental stressors, disease infections, and genetic predispositions. Although the exact etiology remains unclear, it has been widely accepted that physiological or psychological stressors during feather growth can induce fault bars formation. In modern farming systems, poultry are frequently exposed to multiple stressors in the high-density environment, compromising their welfare status. However, evaluating stress level in poultry remains a persistent challenge in practical welfare assessments. Recently, fault bars have gained attention as a non-invasive, practical, and promising biomarker for poultry welfare evaluation. This review synthesizes the influencing factors and formation mechanisms of fault bars, as well as their current applications in poultry welfare assessment, aiming to provide insights for improving poultry welfare evaluation systems.

Key words: feather fault bars, stress, welfare assessment, poultry

CLC Number:

S852.2

YI Jinfan, GUO Feng, WANG Song, ZHANG Aoyu, ZHANG Yanhong. Formation Mechanism of Feather Fault Bars and Research Progress in the Welfare Assessment of Domestic Poultry[J]. Acta Veterinaria et Zootechnica Sinica, 2025, 56(12): 5963-5971.

References

[1] VÁGÁSI C I. The origin of feather holes: a word of caution [J]. Avian Biol, 2014, 45(5): 431-436.
[2] JOVANI R, DIAZ-REAL J. Fault bars timing and duration: the power of studying feather fault bars and growth bands together [J]. Avian Biol, 2012, 43(2): 97-101.
[3] JOVANI R, ROHWER S. Fault bars in bird feathers: mechanisms, and ecological and evolutionary causes and consequences [J]. Biol Rev Camb Philos Soc, 2017, 92(2): 1113-1127.
[4] SERRANO D, JOVANI R. Adaptive fault bar distribution in a long-distance migratory, aerial forager passerine? [J]. Bio J Linn Soc, 2005, 85(4): 455-461.
[5] SARASOLA J H, JOVANI R. Risk of feather damage explains fault bar occurrence in a migrant hawk, the Swainson's hawk Buteo swainsoni [J]. Avian Biol, 2006, 37(1): 29-35.
[6] ARRAZOLA A, TORREY S. The development of fault bars in domestic chickens (Gallus gallus domesticus) increases with acute stressors and individual propensity: implications for animal welfare [J]. Anim Welf, 2019, 28(3): 279-286.
[7] REIMERT I, WEBB L E, VAN MARWIJK M A, et al. Review: Towards an integrated concept of animal welfare [J]. Animal, 2023, 17(4): 100838.
[8] TAINIKA B, ŞEKEROǦLU A, AKYOL A, et al. Welfare issues in broiler chickens: overview [J]. World Poultry Sci J, 2023, 79(2): 285-329.
[9] STROCHLIC D E, ROMERO L M. The effects of chronic psychological and physical stress on feather replacement in European starlings (Sturnus vulgaris) [J]. Comp Biochem Phys A, 2008, 149(1): 68-79.
[10] SEARCY W A, PETERS S, NOWICKI S. Effects of early nutrition on growth rate and adult size in song sparrows Melospiza melodia [J]. Avian Biol, 2004, 35(3): 269-279.
[11] MURPHY M E, MILLER B T, KING J R. A structural comparison of fault bars with feather defects known to be nutritionally induced [J]. Can J Zoo, 1989, 67(5): 1311-1317.
[12] RIDDLE O. The genesis of fault-bars in feathers and the cause of alternation in light and dark fundamental bars [J]. Biol Bull-us, 1908, 14(6): 328-370.
[13] JOVANI R, MONTALVO T, SABATÉ S. Fault bars and bacterial infection [J]. J Ornithol, 2014, 155(3): 819-823.
[14] SLAGSVOLD T. Sex, size, and natural selection in the hooded crow corvus corone cornix [J]. Ornis Scand, 1982, 13(3): 165-175.
[15] BORTOLOTTI G R, DAWSON R D, MURZA G L. Stress during feather development predicts fitness potential [J]. J Anim Ecol, 2002, 71(2): 333-342.
[16] FREED L A, MEDEIROS M C, BODNER G R. Explosive increase in ectoparasites in Hawaiian forest birds [J]. J Parasitol, 2008, 94(5): 1009-1021.
[17] YETHON J A, WHITFIELD C. Lipopolysaccharide as a target for the development of novel therapeutics in gram-negative bacteria [J]. Curr Drug Targets Infect Disord, 2001, 1(2): 91-106.
[18] ROMANO A, RUBOLINI D, CAPRIOLI M, et al. Sex-related effects of an immune challenge on growth and begging behavior of barn swallow nestlings [J]. PLoS One, 2011, 6(7): e22805.
[19] WARNER N L. The immunological role of the avian thymus and bursa of fabricius [J]. Folia Biol (Praha), 1967, 13(1): 1-17.
[20] MØLLER A P, KIMBALL R T, ERRITZØE J. Sexual ornamentation, condition, and immune defence in the house sparrow Passer domesticus [J]. Behav Ecol Sociobiol, 1996, 39(5): 317-322.
[21] HOULE C, PELLETIER F, BÉLISLE M, et al. Impacts of environmental heterogeneity on natural selection in a wild bird population [J]. Evolution, 2020, 74(6): 1142-1154.
[22] DE AYALA R M, MARTINELLI R, SAINO N. Vitamin E supplementation enhances growth and condition of nestling barn swallows (Hirundo rustica) [J]. Behav Ecol Sociobiol, 2006, 60(5): 619-630.
[23] MØLLER A P, ERRITZØE J, NIELSEN J T. Frequency of fault bars in feathers of birds and susceptibility to predation [J]. Bio J Linn Soc, 2009, 97(2): 334-345.
[24] SAPOLSKY R M, ROMERO L M, MUNCK A U. How do glucocorticoids influence stress responses? Integrating permissive, suppressive, stimulatory, and preparative actions [J]. Endocr Rev, 2000, 21(1): 55-89.
[25] BORTOLOTTI G R, MARCHANT T A, BLAS J, et al. Corticosterone in feathers is a long-term, integrated measure of avian stress physiology [J]. Funct Ecol, 2008, 22(3): 494-500.
[26] DESROCHERS D W, REED J M, AWERMAN J, et al. Exogenous and endogenous corticosterone alter feather quality [J]. Comp Biochem Phys A, 2009, 152(1): 46-52.
[27] BORTOLOTTI G R, MARCHANT T, BLAS J, et al. Tracking stress: localisation, deposition and stability of corticosterone in feathers [J]. J Exp Biol, 2009, 212(Pt 10): 1477-1482.
[28] FAIRHURST G D, DAWSON R D, OORT H V, et al. Synchronizing feather-based measures of corticosterone and carotenoid-dependent signals: what relationships do we expect? [J]. Oecologia, 2014, 174(3): 689-698.
[29] LEISHMAN E M, VANDERHOUT R J, ABDALLA E A, et al. Genetic parameters of feather corticosterone and fault bars and correlations with production traits in turkeys (Meleagris gallopavo) [J]. Sci Rep, 2023, 13(1): 38-48.
[30] SODHI N S, SOH M C K, PRAWIRADILAGA D M, et al. Persistence of lowland rainforest birds in a recently logged area in central Java [J]. Bird Conserv Int, 2005, 15(2): 173-191.
[31] GRIESSER M, NYSTRAND M, EKMAN J. Reduced mortality selects for family cohesion in a social species [J]. Proc Biol Sci, 2006, 273(1596): 1881-1886.
[32] EGGERS S, LOW M. Differential demographic responses of sympatric Parids to vegetation management in boreal forest [J]. For Ecol Manage, 2014, 319: 169-175.
[33] MADERSON P F, HILLENIUS W J, HILLER U, et al. Towards a comprehensive model of feather regeneration [J]. J Morphol, 2009, 270(10): 1166-1208.
[34] RIDDLE O. A study of fundamental bars in feathers. [J]. Biol Bull-us, 1907, 12(3): 165-174.
[35] DUERDEN J E. Experiments with ostriches - X [J]. Agri J Union S Afr, 1909, 35(4): 474-487.
[36] MURPHY M E, KING J R, LU J. Malnutrition during the postnuptial molt of White-crowned Sparrows: feather growth and quality [J]. Can J Zoo, 1988, 66(6): 1403-1413.
[37] KING J R, MURPHY M E. Fault bars in the feathers of white-crowned sparrows: Dietary deficiency or stress of captivity and handling? [J]. The Auk, 1984, 101(1): 168-169.
[38] MØLLER A P, NIELSEN J T, ERRITZØE J. Losing the last feather: feather loss as an antipredator adaptation in birds [J]. Behav Ecol, 2006, 17(6): 1046-1056.
[39] MICHENER H, MICHENER J R. Bars in Flight Feathers [J]. Condor, 1938, 40(4): 149-160.
[40] FRANKLIN D C, LEGGE S, SKROBLIN A, et al. Wings of tropical finches: interspecific differences in shape are consistent with levels of mobility, but moult and feather fault patterns are more complex [J]. EMU, 2017, 117(4): 370-381.
[41] LEESON S, WALSH T. Feathering in commercial poultry I. Feather growth and composition [J]. World Poultry Sci J, 2004, 60(1): 42-51.
[42] RIBER A B, TAHAMTANI F M, STEENFELDT S. Effects of qualitative feed restriction in broiler breeder pullets on behaviour in the home environment [J]. Front Vet Sci, 2020, 7(1): 316-327.
[43] ARRAZOLA A, MOSCO E, WIDOWSKI T M, et al. The effect of alternative feeding strategies for broiler breeder pullets: 1.
Welfare and performance during rearing [J]. Poult Sci, 2019, 98(9): 3377-3390.
[44] PAP P L, BARTA Z, TÖKÖLYI J, VÁGÁSI I C. Increase of feather quality during moult: a possible implication of feather deformities in the evolution of partial moult in the great tit Parus major [J]. Avian Biol, 2007, 38(4): 471-478.
[45] RIBER A B, WURTZ K E. Impact of growth rate on the welfare of broilers [J]. Animals, 2024, 14(22): 3330-3352.
[46] TUCKER V A. The effect of molting on the gliding performance of a Harris' Hawk (Parabuteo unicinctus) [J]. The Auk, 1991, 108(1): 108-113.
[47] MACHMER M M, ESSELINK H, STEEGERI C, et al. The occurrence of fault bars in the plumage of nestling Ospreys [J]. Ardea, 1991, 80(2): 261-272.
[48] JOVANI R, BLAS J. Adaptive allocation of stress-induced deformities on bird feathers [J]. J Evol Biol, 2004, 17(2): 294-301.
[49] HEWSON C J. Can we assess welfare? [J]. Can Vet J, 2003, 44(9): 749-753.
[50] BOZZO G, DIMUCCIO M M. Implementation of animal welfare: Pros and cons [J]. Agriculture, 2023, 13(4): 748-751.
[51] VAN DER STAAY F J, GOERLICH V C, MEIJBOOM F L, et al. Animal welfare definitions, frameworks, and assessment tools: Advancing the measurement and laying the foundation for improved animal welfare through a three-step approach [J]. Anim Welf, 2025, 34: e30.
[52] HEMSWORTH P H, MELLOR D J, CRONIN G M, et al. Scientific assessment of animal welfare [J]. N Z Vet J, 2015, 63(1): 24-30.
[53] KWON B Y, LEE H G, JEON Y S, et al. Research Note: Welfare and stress responses of broiler chickens raised in conventional and animal welfare-certified broiler farms [J]. Poult Sci, 2024, 103(3): 103402.
[54] WEIMER S L, WIDEMAN R F, SCANES C G, et al. An evaluation of methods for measuring stress in broiler chickens [J]. Poult Sci, 2018, 97(10): 3381-3389.
[55] COTTER P F. An examination of the utility of heterophil-lymphocyte ratios in assessing stress of caged hens [J]. Poult Sci, 2015, 94(3): 512-517.
[56] RIBEIRO L R R, SANS E C O, SANTOS R M, et al. Will the white blood cells tell? A potential novel tool to assess broiler chicken welfare [J]. Front Vet Sci, 2024, 11(1): 1384802.
[57] ROMERO L M, FAIRHURST G D. Measuring corticosterone in feathers: Strengths, limitations, and suggestions for the future [J]. Comp Biochem Phys A, 2016, 202: 112-122.
[58] WILSON S C, CUNNINGHAM F J. Effect of photoperiod on the concentrations of corticosterone and luteinizing hormone in the plasma of the domestic hen [J]. J Endocrinol, 1981, 91(1): 135-143.
[59] ARRAZOLA A, TORREY S. Welfare and performance of slower growing broiler breeders during rearing [J]. Poult Sci, 2021, 100(11): 101434.
[60] HOCKING P M, JONES E K. On-farm assessment of environmental enrichment for broiler breeders [J]. Br Poult Sci, 2006, 47(4): 418-425.
[61] KWON B Y, LEE H G, JEON Y S, et al. Effects of grain-based pecking blocks on productivity and welfare indicators in commercial broiler chickens [J]. Anim Biosci, 2024, 37(3): 536-546.

Formation Mechanism of Feather Fault Bars and Research Progress in the Welfare Assessment of Domestic Poultry

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