Effect of dehydration and butter-frying on chinicuil (Comadia redtenbacheri Hammershmidt) and maguey white worm (Aegiale hesperiaris Walker)

In the state of Hidalgo, México, chinicuil (CH) and maguey white worm (MW) are consumed as well as used in different culinary preparations. Few studies are available on the effect of butter-frying (BF) and dehydration (DN) on their chemical composition. The objective of this study was to compare the effect of DN and BF on the chemical composition and fatty acids (FA) content of CH and MW. CH and MW were purchased and then fried in butter. The fresh samples were dehydrated at 70 °C for 4 h, and their chemical analysis was performed. The Soxhlet method was used for the extraction of oils (DNCH, DNMW, BFCH, and BFMW), which were analysed with regard to the quality parameters (i.e. moisture, acidity, iodine, and peroxide). The FA contents were determined by gas chromatography coupled with mass spectrometer. The DNCH (72.82%) and DNMW (76.81%), revealed high concentrations of saturated FA. Free FA and hydro-peroxides were produced, which affected the percentage of saturated FA in the BFCH (15%) and BFMW (17%) samples, and unsaturated FA by 85 and 84%, respectively, along with the production of trans-FA. Therefore, it is necessary to regulate the frying conditions, as BF causes harmful changes in their chemical composition and in their fatty acid structure, in CH and MW, which can cause health problems to humans.

Fatty Acid Composition of Goat and Sheep Milk: Transformation during Yogurt Production

Introduction. Information on the structure of fatty acids is crucial for production and promotion of goat and sheep milk in dairy industry. The profile of fatty acids of milk fat can affect the nutrition value and market value of dairy products. Study objects and methods. The present research featured fatty acid structure of goat and sheep milk and its transformation during yogurt production. The fatty acid structure was studied using gas chromatography. The milk was obtained from goats of the Zaanensky breed and sheep of the North Caucasian breed. Their ratio in the yogurt was 1:1. Results and discussion. The content of saturated fatty acids was 12% less in goat milk than in sheep milk. Olein, stearin, and palmitic acids are the main fatty acids in the fatty phase of milk and yogurt. The research revealed some changes in concentration of individual fatty acids during milk processing and during the storage of yogurt. As a result of ripening and storage, the amount of saturated fatty acids in yogurt increased by 5% on day 7, in comparison with the initial dairy mix. The content of the polynonsaturated fatty acids decreased by 19.27%. Goat milk had the highest value of the ratio of the hypocholesteremic and hypercholesteremic fatty acids. Goat milk demonstrated the most acceptable fatty acid structure in terms of healthy nutrition and prevention of atherosclerosis and thrombogenesis. During yogurt production and storage, the monononsaturated and polynonsaturated fatty acids decreased, while the content of saturated fatty acids increased. Thus, goat milk can increase the amount of monononsaturated and polynonsaturated fatty acids in dairy products. However, the research also revealed a general tendency to decrease in monononsaturated and polynonsaturated fatty acids during yogurt production and storage, with a parallel increase in the content of saturated fatty acids. Unlike ship milk, goat milk had a lower value of the indices of atherogenicity and thrombogenesis. Conclusion. The indices of atherogenicity and thrombogenesis provided additional information on the functional properties of the product. The established features of the fatty acid profile and its transformation during yogurt production provide data that can help produce qualitatively new dairy drinks with a healthy fatty acid profile.

Production of green biofuel by using a goat manure supported Ni–Al hydrotalcite catalysed deoxygenation process

Deoxygenation pathway of oleic acid to bio-hydrocarbon involves decarboxylation/decarbonylation of oxygen content from fatty acid structure in the form of carbon dioxide (CO2)/carbon monoxide (CO), respectively, with the presence of goat manure supported Ni–Al hydrotalcite (Gm/Ni–Al) catalyst.