Los aceites de sacha inchi de los ecotipos Plukenetia huayllabambana y Plukenetia volubilis se microencapsularon para protegerlos de factores ambientales como el oxígeno, la luz, humedad y de las condiciones de los procesos durante la elaboración de los alimentos. El estudio de la vida útil del producto microencapsulado es muy importante a la hora de utilizarlo como materia prima en el desarrollo de alimentos funcionales. Por todo lo comentado anteriormente, el objetivo del trabajo fue evaluar la vida útil de los aceites de sacha inchi microencapsulados con diferentes materiales de pared (Goma Arábiga (GA), Hi-Cap, Maltodextrina (MD) y proteína de suero de leche (WPI)), solos o en mezclas; empleando el método Rancimat® a las temperaturas de 70, 80, 90 y 100°C. Los resultados del tiempo de vida útil extrapolada a 25°C de los microencapsulados de los aceites de sacha inchi fue m...

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The sacha inchi oils of ecotypes of Plukenetia huayllabambana and P. volubilis were microencapsulated to protect from environmental factors such as oxygen, light, moisture and the process conditions during the food processing. The study of the shelf life of the microencapsulated are very important for using them as a raw material in the development of functional foods. The objective of this work was to evaluate the shelf life of sacha inchi oils microencapsulated with different wall materials (Gum Arabic (GA), Hi-Cap, Maltodextrin (MD) and whey protein (WPI) ), alone or in mixtures; using the Rancimat method at temperatures of 70, 80, 90 and 100 ° C, respectively. The results of the shelf life extrapolated at 25°C of sacha inchi oils microencapsules were longer than sacha inchi oils without microencapsular, oxidative stability index and induction period (PI ), also confirmed that the m...

Universidad Nacional Agraria La Molina. Escuela de Posgrado. Maestría en Tecnología de Alimentos

Ciclo Optativo de Especialización y Profesionalización en Gestión de Calidad Total y Productividad

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The aim of this work was to obtain sacha inchi oil (SIO) microcapsules from two different species, Plukenetia volubilis L. (SIVO) and Plukenetia huayllabambana L. (SIHO), using different biopolymers as wall materials and spray drying technology. The physicochemical characteristics such as encapsulation efficiency, particle size, morphology and oxidative stability were analyzed in order to select the best formulation that could potentially be used as an ingredient in the development of functional food. Bulk SIO and four formulations were tested for each oil ecotype, using different encapsulating agents: maltodextrin (MD), Arabic gum (AG), whey protein concentrate (WPC) and modified starch HI-CAP®-100 (H). Microcapsules made of H presented the highest oxidative stability and encapsulation efficiency compared to AG, AG:MD or AG:MD:WPC formulations.

Sacha inchi (Plukenetia huayllabambana) oil was co-microencapsulated with natural antioxidant extracts (NAE), such as camu-camu (Myrciaria dubia (HBK) Mc Vaugh) fruit, Añil variety Andean potato (Solanum tuberosum andigenum, and elderberry fruit (Sambucus peruviana). Gum Arabic and the ternary combination of gum Arabic (GA) + maltodextrin (MD) + whey protein isolate (WPI) at different formulations were used as coating materials for the encapsulation process using spray-drying. The moisture content, particle size distribution and morphology, total phenolic content, antioxidant activity, fatty acid and sterol composition, oxidative stability, and shelf-life were evaluated. Co-microcapsules of sacha inchi (P. huayllabambana) oil with camu camu skin extract (CCSE) at 200 ppm encapsulated with GA + MD + WPI had the highest total polyphenol content (4239.80 µg GAE/g powder), antioxidant acti...

Sacha inchi Plukenetia huayllabambana oil (SIPHO) was co-microencapsulated, by spray drying using gum arabic as a coating material, with antioxidant extracts of camu camu (Myrciaria dubia (HBK) McVaugh) (CCSE) and mango (Mangifera indica) (MSE) skins obtained by ultrasound–microwave-assisted extraction (UMAE). The physicochemical characteristics of the microcapsules, such as, particle size, morphology, and moisture, as well as the encapsulation efficiency, the fatty acid composition, and oxidative stability, were determined in order to select the best formulation for the design of functional powdered beverages. The formulation with the highest amounts of ¿3 acids and polyphenols was used to prepare a functional powdered beverage that contained ¿3 (52.74%), antioxidant activity (324.80 mg AAE/100 g powder), and acceptable sensory attributes.

nchsilva@ulima.edu.pe;mmontora@ulima.edu.pe;halarcon@ulima.edu.pe;neryvilca@hotmail.com; ggallar@inti.gob.ar;arogue@xanum.uam.mx;mcperezcamino@ig.csic.es

In this research, scallops (Argopecten purpuratus) visceral meal (SVM) and defatted meal (SVMD) were analysed for their proximal composition, protein solubility, and amino acid profile. Hydrolysed proteins isolated from the scallop’s viscera (SPH) were optimised and characterised using response surface methodology with a Box-Behnken design. The effects of three independent variables were examined: temperature (30–70 °C), time (40–80 min), and enzyme concentration (0.1–0.5 AU/g protein) on the degree of hydrolysis (DH %) as a response variable. The optimised protein hydrolysates were analysed for their proximal composition, yield, DH %, protein solubility, amino acid composition, and molecular profile. This research showed that defatted and isolation protein stages are not necessaries to obtain the hydrolysate protein. The conditions of the optimization process were 57 °C, 62 mi...