Oxidative stability of marine oils as affected by added wheat germ oil

Role of Solid Fat Content in Oxidative Stability of Low-Moisture Cracker Systems

Lipid oxidation is a major pathway for the chemical deterioration of low-moisture foods. Little is known about how the physical properties of the fat used in crackers impact lipid oxidation kinetics. Fully hydrogenated soybean fat + interesterified soybean oil, fully hydrogenated soybean fat + sunflower oil, fully hydrogenated soybean oil, and soybean oil and interesterified fat alone were formulated to have varying solid fat content (SFC) at 55 °C but the same linoleic acid and tocopherol contents, so the fats had similar susceptibility to oxidation. A fluorescence probe showed that lipid mobility increased with decreasing SFC in both cracker doughs and fat blends, suggesting the probe could be used to monitor SFC directly in foods. Decreasing SFC decreased oxidation in crackers. Crackers made from interesterified fat (13.7% SFC) were more oxidatively stable (hexanal lag phase = 33 days) than crackers made from fat blends (hexanal lag phase = 24 days). These results suggest that blended fats result in regions of liquid oil high in unsaturated fatty acids within a food product prone to oxidation. Conversely, interesterified fats where unsaturated and saturated fatty acids are more evenly distributed on the triacylglycerols are more stable. Thus, interesterified fats could allow for the formulation of products higher in unsaturated fatty acids to improve nutritional profiles without sacrificing shelf life.

Healthy beef burgers: Effect of animal fat replacement by algal and wheat germ oil emulsions

The present study aimed to reformulate beef burgers to make them healthier through total replacement of pork backfat by algal (Al) and/or wheat germ (WG) oils emulsions. The addition of oils emulsions increased the protein and decreased the proportions of lipids in the burgers between 26% and 38%. Colour and technological parameters were not affected by the addition of oils, but increased all TPA parameters. α-tocopherol (Vitamin E) increased in reformulated samples. The wheat germ oil reduced the SFA concentration. The use of algal and/or wheat germ oils emulsions increase PUFA concentration. Beef burgers containing algal oil can be claimed as "high omega-3 content". Both oils improved the n-6/n-3 and PUFA/SFA nutritional ratios. Sensory differences were observed in the flavour and overall quality parameters. The formulations containing algal oil emulsion were similar to the Control. As a general conclusion, the use of algal oil emulsion as pork backfat substitute improve nutritional characteristics of burger without affecting technological or sensory properties.