Baldo, GAA; Almeida Paz, ICL; Alves, MCF; Nääs, IA; Garcia, RG; Caldara, FR; Gavilan, CWS

doi:10.1590/S1516-635X2013000400005

Abstract

Black bone syndrome (BBS) affects poultry industry, and it is caused by the darkening of the tissue adjacent to the bone due to leak age of bone marrow contents during cooking. The objective of this experiment was to estimate BBS incidence in chicken thighs. A completely randomized experimental design, with two treatments (refrigerated or frozen) of 50 replicates each, was applied. The influence of BBS on meat quality was assessed according to bone lightness (*L), and meat appearance and sensorial characteristics. Lightness was measured using a colorimeter (Minolta® 410R) positioned on the proximal epiphyseal growth plate. Meat quality was evaluated after roasting by assigning scores for appearance (acceptable = no darkening, intermediate = little darkened, and unacceptable = severe darkening). Twelve refrigerated and 12 frozen thighs were used for sensorial analysis (adjacent muscle appearance, odor, tenderness, and flavor), assessed using a hedonic scale (1 = bad to 10 = very good) by trained panelists. Lightness was submitted to ANOVA and Tukey's test (p<0.05), and the Wilcoxon test (p<0.05) was used to analyze other characteristics. Confidence intervals were established for BBS based on *L values (<37.5=BBS and >37.5=normal). The incidence of BBS was 35%,with a 16%increase thighs were frozen. Meat taste was not influenced by the treatments. Meat appearance, flavor, and tenderness were not affected by freezing or refrigeration, only by BBS degree. It was concluded that freezing increases the incidence of BBS and chicken thighs with bones presenting lower luminosity have worse meat quality.

Bone darkening; commercial processing plant; meat quality

Black bone syndrome in chiken meat

Baldo GAA^I; Almeida Paz ICL^II; Alves MCF^III; Nääs IA^IV; Garcia RG^IV; Caldara FR^IV; Gavilan CWS^I

^IUndergraduate student, Animal Science, FCA - UFGD, Dourados, MS, Brazil

^IIProfessor, FMVZ - UNESP, Botucatu, SP, Brazil

^IIIGraduate student, Animal Science, FCA -UFGD, Dourados, MS, Brazil

^IVProfessor, FCA - UFGD, Dourados, MS, Brazil

^{Corresponding author} Corresponding author: Email: ibiarapaz@fmvz.unesp.br

ABSTRACT

Black bone syndrome (BBS) affects poultry industry, and it is caused by the darkening of the tissue adjacent to the bone due to leak age of bone marrow contents during cooking. The objective of this experiment was to estimate BBS incidence in chicken thighs. A completely randomized experimental design, with two treatments (refrigerated or frozen) of 50 replicates each, was applied. The influence of BBS on meat quality was assessed according to bone lightness (*L), and meat appearance and sensorial characteristics. Lightness was measured using a colorimeter (Minolta^® 410R) positioned on the proximal epiphyseal growth plate. Meat quality was evaluated after roasting by assigning scores for appearance (acceptable = no darkening, intermediate = little darkened, and unacceptable = severe darkening). Twelve refrigerated and 12 frozen thighs were used for sensorial analysis (adjacent muscle appearance, odor, tenderness, and flavor), assessed using a hedonic scale (1 = bad to 10 = very good) by trained panelists. Lightness was submitted to ANOVA and Tukey's test (p<0.05), and the Wilcoxon test (p<0.05) was used to analyze other characteristics. Confidence intervals were established for BBS based on *L values (<37.5=BBS and >37.5=normal). The incidence of BBS was 35%,with a 16%increase thighs were frozen. Meat taste was not influenced by the treatments. Meat appearance, flavor, and tenderness were not affected by freezing or refrigeration, only by BBS degree. It was concluded that freezing increases the incidence of BBS and chicken thighs with bones presenting lower luminosity have worse meat quality.

Keywords: Bone darkening, commercial processing plant, meat quality.

INTRODUCTION

Brazilian poultry production presents outstanding results when compared to other meats produced in the country. For instance, in 2011, total poultry meat production achieved11.4 million tons, while beef production was only 9 million tons, and pork production, as 3.6 million tons (Avisite 2011). The main reasons of this result are reduction in cost of poultry products, the general increase of consumers income, of the Brazilian population, and of public health concerns (Zilli et al., 2005).

Consumers currently demand a wide range of poultry products, particular for convenient and value-added parts. This trend is explained by changes in the eating habits of the population and by consumers' concerns with convenience, nutritional quality, and food safety, as well as with affordable prices (Olivo, 2004). Deboned parts may show some meat defects, and may causer ejection by consumers, as well as poor sensorial characteristics, such as appearance and tenderness, which are highly valued by consumers (Beraquet, 1999).

Meat redness accompanied by the presence of blood is related to a meat defect called bone darkening or black bone syndrome, and it has been reported in cooked broiler meat parts. Black bone syndrome (BBS) is defined as a condition where the surface of the bone and adjacent muscle tissues become dark reddish brown or black after cooking (Smith & Northcutt, 2004). Measures to mitigate this problem have been sought since the early days of the meat processing industry, including the addition of D vitamin to broiler diets (Ellis & Woodroof, 1959), and different freezing regimens and cooking methods (Cunningham, 1974). This condition was previously reported by Lyon & Lyon (2002) and Saunders-Bladers & Korver (2006). However, recent observations of special chicken meat part son the shelves of supermarkets suggest that the problem is much more widespread than earlier reported (Smith & Northcutt, 2004). BBS is caused by a problem in the intramembranous ossification, and it impairs meat quality. It may also be related to poor broiler welfare during rearing (Whitehead, 2010).

In the supermarkets, darkened bones are frequently found, affecting the marketing of chicken meat. Recent reports mention that fast-food chains are using boneless chicken meat in order to reduce the problem (Lyon & Lyon, 2002). Therefore, due to the limited literature published on this subject and its impacts on the market, it is necessary to study how the effects of BBS can be reduced or eliminated.

This experiment aimed at evaluating the incidence of black bone syndrome in refrigerated and frozen broiler thighs.

MATERIAL AND METHODS

Sampling

One hundred pairs of chicken thighs were collected in a commercial processing plant located in Dourados, MS, Brazil. The meat derived from asame flock of male Cobb^®broilers, and the pair of thighs derived from each bird was individually packed to allow their identification. A completely randomized experimental design with two treatments of 50 replicates each was applied. Treatments consisted refrigerated (4 ºC) or frozen (-10 ºC) thighs.

Experimental procedure

Samples were submitted to the Laboratory of Meat Technology, School of Agrarian Sciences (FCA), Federal University of Grande Dourados (UFGD), to estimate the prevalence of BBS using qualitative meat characteristics (bone lightness, and meat appearance and sensorial analysis). Both thighs from each broiler carcass were used. The right thighs were deboned and submitted to lightness (L*) test, were the left thighs were used for meat quality analyses. The left thighs were roasted in an electric oven until internal temperature reached 90 ºC. Raw bone lightness was determined using the Minolta colorimeter^®410R, positioned on the growth plate of the proximal epiphysis of the thigh.

After roasting, thighs were visually assessed to determine the darkening of the femur adjacent muscle tissues. Their appearance were scored as acceptable (region close to the bone did no presented any darkening), intermediate (region close to the bone slightly darkened), and unacceptable (region close to the bone with severe darkening), as shown in Table 1.

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The sensorial assessment of refrigerated meat and frozen thighs was performed by a panel of testers, using a 0-10 hedonic scale, where0 = very bad and 10 = good appearance, tenderness and flavor.

Data were submitted to analysis of variance. Lightness was compared by the test of Tukeyand the Wilcoxon test was used to compare the other parameters. All tests adopted the confidence interval of 95% (p < 0.05).

RESULTS AND DISCUSSION

Thighs affected by BBS were characterized as a function of lightness values, and those with values lower than 37.5 were considered as presenting BBS. Thighs with lightness values within the range of 37.5 - 40 were considered normal (Table 1). The incidence of thighs presenting black bone syndrome in both treatments (refrigerated and frozen) was 35%. However, there was a 16% increase in the incidence of BBS in frozen thighs compared with refrigerated thighs. Some authors (Saunders-Bladers & Korver, 2006; Lyon & Lyon, 2002; Lyon et al., 1976; Spencer et al., 1961) also observed higher incidence of darkening in frozen chicken leg bones. According to Mota (2012), it is possible to increase the proportion of normal bones using dietary vitamin supplementation.

Visually, frozen thighs presented an 18% increase in the incidence of un acceptable black bone syndrome compared with refrigerated thighs (Figure 1). Similar results were obtained by Lyon & Lyon (2002) when evaluating the effect of temperature on chicken thigh meat color, and observed that low temperature storage darken sthigh meat adjacent to bone.

Relative to sensorial characteristics, meat taste was not influenced by treatments. Chiling or freezing did not affect meat appearance, odor, or tenderness, except when BBS was present (Table 2). When meat quality worsened, sensorial characteristics followed the same trend.

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When meat lightness was evaluated, it was observed that the exposure to freezing increased BBS incidence in the evaluated samples. Whitehead (2009) supplemented broiler diets with 0 to 69 mg of 25-hydroxyvitamin D or with regular vitamin D₃levels and measured the optical density reflected 10 to 15 mm of the proximal ends of tibias. The author verified that frozen browning was significantly lower (p <0.05) in birds supplemented with 25-hydroxyvitamin D, indicating that its supplementation may influence the reduction of BBS. Previously, Ellis & Woodroof (1959) found that diet may affect chicken bone darkening; particularly low calcium or high vitamin D levels may promote more severe darkening.

The gross evaluation of the thighs after roasting in an electric oven showed that the freezing also negatively affected the meat. This result maybe explained by freezing and thawing. Freezing causes the formation of ice crystals, which make muscle fiber swell and cause their physical separation. When the meat is subsequently thawed, bone marrow contents leak to the adjacent tissues, which results in the dark appearance of the meat before and during cooking, as the red color turns brown or gray and, in severe cases, black (De Oliveira, 2000). The red color in meat is due to the hemoglobin present in the bone marrow, which is relatively porous in young birds. During cooking, hemoglobin is oxidized, and blackens the blood (Whitehead, 2010).

According Pereira (2003), depending on the proportion of ice crystals in the bone marrow, disruption of tissues is more or less severe. The cooking process can further contribute to the darkening of meat (Whitehead, 2010).

However, Smith & Northcutt (2004) evaluated the lightness of thigh meat submitted to different cooking temperatures (after freezing) and did not observe any influence of cooking temperature on meat darkening. According to Saunders & Korver-Blades (2006), blood leakage and meat discoloration of whole thighs can be reduced when vitamin D₃is supplemented in broiler diets, increasing consumers' acceptance.

The degree of bone darkening affected meat sensorial characteristics (appearance, odor and tenderness), reducing pane lists acceptance as darkening increased. Consistent results were reported by AMSA (1995), reinforcing that blood leakage from the marrow may reduce the acceptance chicken thigh meat presenting BBS. In the study of Oliveira (2000), bone darkening did not affect meat taste, odor, or texture, but it resulted in poor meat appearance. That author also reported that precooking the before freezing reduces the rate of darkening.

Chicken thighs stored in the freezer presented higher BBS incidence (gross and light examinations) compared with the chilled samples. Leakage of bone marrow negatively affected meat appearance, odor, and tenderness. Therefore, the rejection of chicken meat affected with BBS in the market may cause future problems for the poultry industry. Variations in meat quality can be related to processing and storage conditions (Olivo, 2006).

One method of meat cold storage is industrial, and it is the most widespread conservation technique used for meat and other perishable foods. Freezing preserves foods seasonal characteristics, ensures their longdistance transport, allowing their use for processing or consumption (Pardi et al., 2001). It is one of the most valuable tools used in food technology because it enables the reduction of production costs, improves food quality, allows reducing losses and waste, and preserves food flavor, color, texture, and their initial qualities (Baruffaldi & Oliveira, 1998).

ACKNOWLEDGEMENT

The authors wish to thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico - CNPQ for funding this study, and the company BR Foods for donating the meat samples.

CONCLUSION

The cold storage (refrigeration or freezing) of chicken thighs increases the incidence of the black bone syndrome, tending to reduce consumers' acceptance of the product, despite the lack of influence of BBS on meat flavor or odor. Further studies need to be carried out on how to improve chicken bone quality, considering that chickens thighs are commonly marketed chilled or frozen.

Submitted: March/2012

Approved: May/2013

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AviSite. Produção Animal Avicultura. VBP da avicultura chega aos R$ 29 bilhões em 2011. AviSite 2011;5(4):14.
Baruffaldi R, Oliveira M. Fundamentos de Tecnologia de Alimentos. São Paulo: Atheneu; 1998. p.317.
Beraquet N. Influência de fatores ante e post mortem na qualidade da carne de aves. Revista Brasileira de Ciência Avícola 1999;1(3):155-166.
Cunningham FE. Effect of freezing temperature on bone darkening in cooked broilers. Poultry Science 1974;53:255-261.
Ellis C, Woodroof JG. Prevention of darkening in frozen broilers. Food Technology 1959;13:533-588.
Lyon CE, Townsend WE, Wilson JR RL. Objective color values of non-frozen and frozen broiler breasts and thighs.Poultry Science 1976;55:1307-1312.
Lyon BG, Lyon CE. Color of uncooked and cooked broiler leg quarters associated with chilling temperature and holding time. Poultry Science 2002;81:1916-1920.
Mota MM. Diferentes níveis vitamínicos na dieta de frangos de corte [dissertação]. Pirassununga (SP): Universidade de São Paulo; 2012.
Olivo R. Atualidades na qualidade da carne de aves. Revista Nacional da Carne 2004;331:38-50.
Olivo R. Estrutura, composição e funcionalidade do tecido muscular. In: Olivo R. O mundo do frango. Criciúma; 2006. p. 239-272.
Oliveira R. Congelação [acesso 2011 Ago 28]. Botucatu: Universidade Estadual de São Paulo; 2000. Disponível em: http://www.pucrs.campus2.br/~thompson/Roca109.pdf
Pardi MC, Santos IF, Souza ER, Pardi HS. Ciência, Higiene e Tecnologia da Carne. 2ed. Goiânia: Editora UFG; 2001. v.2
Pereira ASC. Efeito do congelamento e da maturação na qualidade da carne bovina. 2003 [acesso 2011 Set 8]. Disponível em: http://www.beefpoint.com.br/radares-tecnicos/qualidade-da-carne/efeito-docongelamento-e-da-maturacao-na-qualidade-da-carne-bovina-5010n. aspx
Saunders-Blades J, Korver D. HyD and poultry: bones and beyond. European Poultry Conference, Verona, Italy; 2006.
Smith DP, Northcutt JK. Red discoloration of fully cooked chicken products. Journal of Applied Poultry Science 2003;12:515-521.
Smith DP, Northcutt JK. Induced red discoloration of broiler breast meat: Effect of cook temperature and freezing. International Journal of Poultry Science 2004;3:253-258.
Spencer JV, Sauter EA, Stadelman WJ. Effect of freezing, thawing and storingbroilersonspoilage, flavor and bonedarkening. Poultry Science 1961;40:918-920.
Whitehead CC. Factores nutricionales que influyen en los problemas óseos actuales de los broilers [acesso em 2011 Out 31]. 2009. Proceeding of the 46th Symposium Científico de Avicultura. Available at: http://www.wpsa-aeca.es/aeca_imgs_docs/fact_nutricionales_problemas_oseos_broilers_whitehead_46_symp_aeca_texto.pdf
Whitehead CC. Update on current European Broiler bone problems. 21th Annual Australian Poultry Science Symposium; 2010 Fev 1-3; Sydney, New South Wales. Australian. p. 22 - 25.
Zilli JB, Sousa DP, Barros GSC. Produção de frango de corte: uma comparação sócio-econômica dos avicultores da região sul e da região centro-oeste do Brasil. Passo Fundo: Universidade de Passo Fundo; 2005.

Corresponding author:

Email:

ibiarapaz@fmvz.unesp.br

Publication Dates

Publication in this collection
16 Jan 2014
Date of issue
Dec 2013

History

Received
Mar 2012
Accepted
May 2013

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] American Meat Science Association. Research guidelines for cookery sensorial and instrumental tenderness measurement of fresh meat. Chicago; 1995. 582p.

[2] AviSite. Produção Animal Avicultura. VBP da avicultura chega aos R$ 29 bilhões em 2011. AviSite 2011;5(4):14.

[3] Baruffaldi R, Oliveira M. Fundamentos de Tecnologia de Alimentos. São Paulo: Atheneu; 1998. p.317.

[4] Beraquet N. Influência de fatores ante e post mortem na qualidade da carne de aves. Revista Brasileira de Ciência Avícola 1999;1(3):155-166.

[5] Cunningham FE. Effect of freezing temperature on bone darkening in cooked broilers. Poultry Science 1974;53:255-261.

[6] Ellis C, Woodroof JG. Prevention of darkening in frozen broilers. Food Technology 1959;13:533-588.

[7] Lyon CE, Townsend WE, Wilson JR RL. Objective color values of non-frozen and frozen broiler breasts and thighs.Poultry Science 1976;55:1307-1312.

[8] Lyon BG, Lyon CE. Color of uncooked and cooked broiler leg quarters associated with chilling temperature and holding time. Poultry Science 2002;81:1916-1920.

[9] Mota MM. Diferentes níveis vitamínicos na dieta de frangos de corte [dissertação]. Pirassununga (SP): Universidade de São Paulo; 2012.

[10] Olivo R. Atualidades na qualidade da carne de aves. Revista Nacional da Carne 2004;331:38-50.

[11] Olivo R. Estrutura, composição e funcionalidade do tecido muscular. In: Olivo R. O mundo do frango. Criciúma; 2006. p. 239-272.

[12] Oliveira R. Congelação [acesso 2011 Ago 28]. Botucatu: Universidade Estadual de São Paulo; 2000. Disponível em: http://www.pucrs.campus2.br/~thompson/Roca109.pdf

[13] Pardi MC, Santos IF, Souza ER, Pardi HS. Ciência, Higiene e Tecnologia da Carne. 2ed. Goiânia: Editora UFG; 2001. v.2

[14] Pereira ASC. Efeito do congelamento e da maturação na qualidade da carne bovina. 2003 [acesso 2011 Set 8]. Disponível em: http://www.beefpoint.com.br/radares-tecnicos/qualidade-da-carne/efeito-docongelamento-e-da-maturacao-na-qualidade-da-carne-bovina-5010n. aspx

[15] Saunders-Blades J, Korver D. HyD and poultry: bones and beyond. European Poultry Conference, Verona, Italy; 2006.

[16] Smith DP, Northcutt JK. Red discoloration of fully cooked chicken products. Journal of Applied Poultry Science 2003;12:515-521.

[17] Smith DP, Northcutt JK. Induced red discoloration of broiler breast meat: Effect of cook temperature and freezing. International Journal of Poultry Science 2004;3:253-258.

[18] Spencer JV, Sauter EA, Stadelman WJ. Effect of freezing, thawing and storingbroilersonspoilage, flavor and bonedarkening. Poultry Science 1961;40:918-920.

[19] Whitehead CC. Factores nutricionales que influyen en los problemas óseos actuales de los broilers [acesso em 2011 Out 31]. 2009. Proceeding of the 46th Symposium Científico de Avicultura. Available at: http://www.wpsa-aeca.es/aeca_imgs_docs/fact_nutricionales_problemas_oseos_broilers_whitehead_46_symp_aeca_texto.pdf

[20] Whitehead CC. Update on current European Broiler bone problems. 21th Annual Australian Poultry Science Symposium; 2010 Fev 1-3; Sydney, New South Wales. Australian. p. 22 - 25.

[21] Zilli JB, Sousa DP, Barros GSC. Produção de frango de corte: uma comparação sócio-econômica dos avicultores da região sul e da região centro-oeste do Brasil. Passo Fundo: Universidade de Passo Fundo; 2005.

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Black bone syndrome in chiken meat

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