Addition of Pachira aquatica oil and Platonia insignis almond in cookies: Physicochemical and sensorial aspects.

This article investigated the use of Pachira aquatica (PA) fat and Platonia insignis (PI) nuts as ingredients in the preparation of cookies. Seven formulations containing PA fat and/or PI nuts were studied by changing the formulation proposed by AACC, and samples were evaluated considering physical-chemical, microbiological, and sensory characteristics. Formulations F1, F4, and F5 showed higher mass loss and lower expansion factor after cooking. Formulations F4, F6, and F7 presented a greater increase in diameter. In turn, formulations F5, F6, and F7 presented greater thickness. The content of fatty acids varied according to the composition of each biscuit, and formulations 2 and 3 presented the best lipid profile (oleic acid ~32%). In addition, it was observed that the addition of PI almond increased the fiber content (~7.15%). The sensory evaluation showed that formulation F5 obtained a score of 5, proving that the partial replacement of hydrogenated vegetable fat with PA fat and grated coconut with PI almond favored the panelists' purchasing decision. The results indicate that unconventional sources of lipids and nuts can be used without loss of quality in biscuits.

Microencapsulation of lactase by W/O/W emulsion followed by complex coacervation: Effects of enzyme source, addition of potassium and core to shell ratio on encapsulation efficiency, stability and kinetics of release.

This study evaluated the technological viability of the formation of lactase microcapsules by coacervation (gelatin/gum arabic) containing potassium ions (cofactor). The impacts of the encapsulation and the cofactor on the enzyme properties obtained from Aspergillus oryzae and Kluyveromyces lactis were evaluated as a function of different pH values, temperatures, and storage times. The best microcapsules formed by coacervation showed good functional properties, such as low water activity (≤ 0.4) and particle size (≤ 93.52 µm), as well as high encapsulation efficiency (≥ 98.67%). The potassium ions were capable of reducing the flexibility of the polypeptide backbone, thereby increasing the stability of the enzyme. The microcapsules were also capable of increasing the stability of the enzyme under unfavorable pH values, high temperatures and during storage. An in vitro experiment showed that microcapsules were effective in the retention of about 90% of the enzyme in simulated gastric fluid, but as much as 95% of the enzyme can be released from the capsules in simulated intestinal fluid. The released enzyme retained 83% and 66% of the total enzymatic activity for the capsules produced with lactase from Kluyveromyces lactis and A. oryzae, respectively. These results are promising and demonstrated that these microcapsules are a promising technology to protect and deliver bioactive proteins during storage and delivery in the GI tract.