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A Comparative Study of Carcass Characteristics and Meat Quality Traits of Breast Muscle Between Broiler and Cockerel Chicken

Md. Nazmul Hasan
Department of Animal Science, Bangladesh Agricultural University, Mymensingh, Bangladesh

Md. Ataul Goni Rabbani
Poultry Production Research Division, Bangladesh Livestock Research Institute (BLRI), Savar, Dhaka-1341, Bangladesh

Tahera Yeasmin
Department of Dairy and Poultry Science, Hajee Mohammad Danesh Science & Technology University, Dinajpur, Bangladesh

Moinul Hasan
Department of Surgery and Obstetrics, Bangladesh Agricultural University, Mymensingh, Bangladesh

Md. Harun Or Rashid
AG Agro Industries Limited, Begumganj, Noakhali, Bangladesh

Abstract/ Executive Summary:

Background and Objective: Poultry meat, especially broiler and cockerel, consumption is increasing gradually in the country. As income of common people has been upgrading, they are now choosing quality food for consumption considering nutrient contents, meat quality and so on. The current study aimed to compare the meat quality of broiler and cockerel chicken in terms of proximate composition, physico-chemical properties, meat color, microbial load and carcass characteristics. Materials and Methods: To achieve this, apparently healthy twenty (20) broilers of 42 days old weigh between 1320-1380 g and similar number of same aged cockerels weigh between 740-790 g were selected from the experimental house and related jobs were performed carefully. Results: Results showed that the crude protein content of cockerel breast meat was significantly higher (p<0.05) when compared to broiler. The drip loss, cooking loss and free fatty acid content of broiler breast meat were significantly (p<0.01) higher than the cockerel meat. Lightness (L*) and yellowness (b*) values were also significantly higher in broiler meat although redness (a*) was higher (p<0.01) in cockerel meat. In respect to microbial load, E. coli, S. aureus and TBARS value of broiler breast meat samples were found significantly higher (p<0.01) than the cockerel meat. The dressing percentage was found significantly higher (p<0.01) in broiler chickens. The results from this experiment showed that the broiler breast meat quality is comparatively lower than that of cockerel in terms of nutrient contents, pH, TBARS, free fatty acid, meat color and microbial load. Conclusion: Thus, it could be stated that meat quality of cockerel is better than broiler in terms of the above mentioned criteria.

Keywords: Broiler, Cockerel, Microbial analysis, Meat quality, Carcass characteristics, Proximate composition

Location: Departments of Animal Science, Department of Food Technology and Rural Industries at Bangladesh Agricultural University, Mymensingh

Start Date: 20-10-2017

End Date: 30-11-2017

Program Area: Animal Health and Management

Commodity: Broiler

Objectives:

To compare the meat quality traits by chemical composition, physico-chemical properties (pH, FFA, color, per-oxide value and lipid), color band and microbial load of the breast meat between broiler and cockerel.

Methodology:

Experimental birds and their management: For this experiment, 150 day old cockerel chicks (ISA Brown) and 150 broiler chicks (Cobb 500) were purchased from a reputed hatchery of the country. The experiment was conducted at local farm in Boiler village under Trishal upazila of Mymensingh district of Bangladesh during later part of 2017 (October 20 to November 30, 2017). The chicks were reared without any antibiotic or probiotic except vaccination under open sided poultry house. During the experimental period, Broiler starter (CP 21.5%, Fat 3.5%, CF 5%, Moisture 12%, ME 2900 kcal kg^–¹) feed was provided 0-16 days and Broiler Grower (CP 20%, Fat 3%, CF 5%, Moisture 12%, ME 3000 kcal kg^–¹) was maintained rest period (17-42 days). Identical management (brooding, lighting, biosecurity) and care were ensured throughout the experimental period to get optimum results. Sample collection and preparation: For this experiment, apparently healthy twenty broilers (42 days old and 1320-1380 g body weight) and twenty cockerels (42 days old and 740-790 g body weight) were collected from the experimental house. As far as possible, all connective tissues and visible fat were trimmed off. The muscles were rinsed and washed with clean water to remove blood and cut into small pieces. All of the meat pieces were mixed properly by hand. Lab location: Laboratory analyses of the experimental samples were carried out in the relevant laboratories of the Departments of Animal Science, Department of Food Technology and Rural Industries at Bangladesh Agricultural University, Mymensingh. Meat chemical analyses: Meat proximate chemical analysis was done according to AOAC. Dry matter: Five gram meat sample was taken in pre-weighed porcelain crucibles. The crucible was kept at 105°C in an oven for a period of 24 h. After that the crucible was cooled in desiccators. The meat dry matter was calculated as a difference between the meat sample weights before and after drying. Ether extract: Five gram ground meat sample was taken in a thimble and added 200 mL diethyl ether in a Soxhlet. At about 7-8 h extraction was done at 40-45°C. After extraction, the flask was dried at 100°C. Then the flask was cooled in desiccators and weighed. Ash: Five gram sample was taken in porcelain crucibles and pre-ashed at 105°C for 24 h. The crucible was then placed in a muffle furnace and heated at 550°C for 6 h. The crucible was then cooled in desiccators and weighed. pH: The meat pH was measured using a pH meter in meat homogenate, prepared by blending 10 g of meat with 50 mL distilled water. The laboratory pH meter was adjusted at room temperature (adjusted with buffer pH 7.0). Drip loss: From each sample, a standardized muscle cylinder (30 g) was suspended in an inflated plastic box (4°C) for 24 h. This work was done within 48 hours of postmortem. The drip loss was calculated by the following formula:Cooking loss: The meat sample was boiled to an internal temperature of hot water bath at 90°C for 30 min. Cooking loss was determined by the following calculation:

Color estimation: Samples were taken from the experimental longissimus dorsi (LD) muscles and Hunter color components lightness (L), redness (a) and yellowness (b) were recorded using Hunter Lab Tristimulus colorimeter model D25 m-2. Subsequently these samples were frozen and stored for cooking loss and shear force determinations. Peroxide value determination: The peroxide value was determined according to Sallam et al.

Where, S = Volume of titration (mL); N = Normality of sodium thiosulfate solution (n=0.01); W = Sample weight (g). Free fatty acid value: Free Fatty acid value was determined by Rukunudin et al. FFA (%) = mL titration×Normality of KOH×28.2/g of sample Crude protein: Determination of total protein was done by establishing the total nitrogen with the Kjeldahl method, which consists in extracting the total nitrogen from a mineralized sample [as ammonium sulphate-SO₄(NH₄)₂], then expressing it as ammonia (through distillation and caption on acid) and converting the total ammonia into protein with a correction factor. AOAC method was followed to determine CP using following formula:N% = [(mL standard acid×normality acid) - (mL standard NaOH×normality NaOH)]×1.4007/g sample Crude protein% (CP) = N%×6.25 TBARS determination: The TBARS value was measured according to Vyncke. TBARS, expressed as micromole of malondialdehyde per kilogram of meat, was calculated using TEP/malonic aldehyde as standard. Enumeration of Staphylococcus aureus : Baird Parker agar (Oxoid, England), a selective medium for the isolation and counting of coagulase positive staphylococci was used for the enumeration of Staphylococcus aureus as described by Bhandare et al. Enumeration of Escherichia coli: Escherichia coli were counted as colonies with distinct metallic sheen. Escherichia coli were enumerated on Eosin methylene blue agar (Oxoid, England) by plating an appropriate dilution on plates followed by aerobic incubation at 37°C for 24 h. Dressing percentage and other organs weight: Dressing percentage (DP) = (carcass weight/live weight)×100. Weight of heart, liver, pancreas, gizzard, abdominal fat and spleen were taken with an electronic balance and the percentage of these organs to the carcass weight, were measured. Statistical analysis: Data were analyzed using the SPSS version 20 for windows. Results were presented as mean±standard deviation and significance level was set at 5%.

Source of Information: International Journal of Poultry Science, 18: 144-150. 2019

Article Link (Online Journal): DOI: 10.3923/ijps.2019.7.13

Funding Source:

Budget:

Total Budget (Tk.) :

Achievement/Findings:

In the present study, the CP content of cockerel breast meat was found significantly higher than that of broiler while drip loss, cooking loss and free fatty acid and fat percentage of broiler breast meat were significantly higher. Lightness (L*) and yellowness (b*) were also significantly higher in broiler meat but redness (a*) was found higher in cockerel. While considering microbial load (E. coli, S. aureus and TBAFRS value), cockerel meat was found better but dressing percentage was higher in broiler. From the above results, it can be concluded that there exists wide range of differences in proximate and chemical composition, meat color, microbial loads and carcass characteristics of broiler and cockerel meat. Further study is required in this regard.

Knowledge Management: Journal