Effect of different levels of sodium in water on performance, carcass yield, and meat quality of slow-growing chickens.

The aim of this study was to evaluate the effects of sodium (Na) levels in the drinking water on the performance, carcass yield, and meat quality of slow-growing chickens. A completely randomized design with 4 treatments (4.90; 32.30; 60.53; and 101.0 mg/L of Na in water) and 6 replications, with 20 birds per experimental unit, was adopted. The treatments are evaluated in the following: 10 to 25, 10 to 39, and 10 to 54 days. For slow-growing chickens from 10 to 25 days, the Na levels in the drinking water promoted a quadratic effect for water and feed intake (p<0.05). The inclusion of Na in the drinking water offered to slow-growing chickens from 10 to 39 days resulted in a reduction in voluntary water intake (p<0.05). For slow-growing chickens from 10 to 54 days, the Na levels in the drinking water promoted a quadratic effect for water intake and feed conversion (p<0.05). After 54 days, the slow-growing chickens were slaughtered and it was observed that the Na inclusion in the drinking water offered to slow-growing chickens provided a quadratic effect for cold carcass, breast, and kidney weights and for kidney and liver yields (p<0.05). Liver weight was reduced with increasing Na levels in the drinking water (p<0.05). For the breast cut, the Na levels in the drinking water promoted a quadratic effect for pH24h, drip loss, cooking loss, protein, and fat and an increase in shear force (p<0.05). For the thigh cut, the Na levels in the drinking water increased the pH24h and reduced drip loss and shear force (p<0.05), and a quadratic effect was observed for moisture and fat (p<0.05). Levels of up to 60.53 mg/L of Na promote an increase in feed intake, which provided a higher breast weight and protein content with reduced fat and drip loss.

Grape skin flour obtained from wine processing as an antioxidant in beef burgers.

The objective of this study was to determine the best level of wine making by-product meal (WBM) as a natural antioxidant to replace butylhydroxytoluene (BHT) in beef burger stored at -20 °C for up to 120 days. The treatments consisted of control (basic formulation - BF, without antioxidant); BF with BHT; and BF with WBM0.5, WBM1.0, WBM1.5, and WBM2.0, with 0.5, 1.0, 1.5 and 2.0 g WBM/100 g BF, respectively. Up to 60 days of storage, the lipid oxidation value between BHT and WBM0.5 treatments did not differ and were lower than the values presented by the other treatments. On day 90 and 120, the lipid oxidation values of treatments BHT, WBM0.5, and WBM1.0 did not differ and were lower than the values presented by WBM1.5 and WBM2.0 treatments. Burgers from all treatments with WBM inclusion had crude fiber values above 3 g/100 g. WBM1.5 and WBM2.0 treatments had the worst scores for appearance, aroma, juiciness and tenderness, in addition to the highest cooking losses. WBM can be used at up to 1 g/100 g to replace BHT in frozen beef burgers. Higher levels of WBM inclusion increased lipid oxidation and negatively affected the sensory quality of burgers.