Application of time–intensity method to assess the sensory properties of Iberian dry-cured ham: effect of fat content and high-pressure treatment

High-pressure processing enhances saltiness perception and sensory acceptability of raw but not of cooked cured pork loins-leveraging salty and umami taste

The salt (NaCl) content in processed meats must be reduced because of its adverse effects on cardiovascular health. However, reducing salt in meat products typically leads to a lower taste intensity and, thus, consumer acceptability. Industry interventions must reduce salt content while maintaining taste, quality, and consumer acceptability. In this context, high-pressure processing (HPP) has been proposed to enhance saltiness perception, though there are contradictory reports to date. The present work aimed to conduct a targeted experiment to ascertain the influence of HPP (300/600 MPa) and cooking (71°C) on saltiness perception and sensory acceptability of meat products. HPP treatment (300/600 MPa) did enhance those two sensory attributes (approx. +1 on a 9-point hedonic scale) in raw (uncooked) cured pork loins but did not in their cooked counterparts. Further, the partition coefficient of sodium (PNa+), as an estimate of Na+ binding strength to the meat matrix, and the content of umami-taste nucleotides were investigated as potential causes. No effect of cooking (71°C) and HPP (300/600 MPa) could be observed on the PNa+ at equilibrium. However, HPP treatment at 300 MPa increased the inosine-5'-monophosphate (IMP) content in raw cured pork loins. Finally, hypothetical HPP effects on taste-mediating molecular mechanisms are outlined and discussed in light of boosting the sensory perception of raw meat products as a strategy to achieve effective salt reductions while keeping consumer acceptability.

Improvement on storage stability of iron-fortified soybean powder by microencapsulation

Full-fat soybean powder was a more difficult-to-fortify food vehicle than cereal flour and powdered milk products because of a large quantity of unsaturated fatty acids, particularly when iron was necessary to be fortified. Minimizing oxidation of lipids was extremely valuable in the fortified-food industry. However, very limited data were available on the effect of microencapsulation of iron compounds on lipid oxidation in full-fat soybean powder. In our study, ferric pyrophosphate (FP) was microencapsulated by the emulsifying-gelation technique and its effect on the storage stability of Yingyangbao (YYB) was evaluated. The results showed that microencapsulated FP (MFP) was regularly spherical and uniformly distributed. MFP could significantly (P < 0.05) decrease the sensory score of rancid odor for YYB. The formation of lipid oxidation products such as carbonyl compounds, malondialdehyde, pentanal, and hexanal in YYB during the accelerated test was significantly retarded, improving oxidative stability and delaying the sensory deterioration. The E-nose analysis showed that YYB with MFP had significantly (P < 0.05) lower levels of response values on the specific sensors than YYB containing FP with or without ascorbyl palmitate. MFP could significantly (P < 0.05) improve the sensory and oxidative stability of iron-fortified full-fat soybean powder such as YYB.