Microencapsulation of linseed oil by spray drying for functional food application

Microencapsulation of linseed oil by spray drying for functional food application

Health benefits associated to ω-3 fatty acids consumption together with the high susceptibility to oxidation of ω-3 containing oils have led to the development of microencapsulated oils for nutraceutical and food enrichment applications. The aim of this work is to obtain different formulations for l...

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Veröffentlicht in:Food research international 2013-07, Vol.52 (2), p.473-482
Hauptverfasser: Gallardo, Gabriela, Guida, Leticia, Martinez, Vanina, López, María C., Bernhardt, Dana, Blasco, Ramiro, Pedroza-Islas, Ruth, Hermida, Laura G.
Format: Artikel
Sprache:eng
Schlagworte:
alpha-linolenic acid
Biological and medical sciences
Bread
breads
Cereal and baking product industries
Computational efficiency
Computing time
food enrichment
Food industries
Foods
Formulations
Functional bread
functional foods
Fundamental and applied biological sciences. Psychology
gum arabic
Linseed oil
manufacturing
methylcellulose
Microencapsulation
omega-3 fatty acids
Oxidation
Rancimat test
spray drying
whey protein isolate
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container_end_page 482
container_issue 2
container_start_page 473
container_title Food research international
container_volume 52
creator Gallardo, Gabriela
Guida, Leticia
Martinez, Vanina
López, María C.
Bernhardt, Dana
Blasco, Ramiro
Pedroza-Islas, Ruth
Hermida, Laura G.
description Health benefits associated to ω-3 fatty acids consumption together with the high susceptibility to oxidation of ω-3 containing oils have led to the development of microencapsulated oils for nutraceutical and food enrichment applications. The aim of this work is to obtain different formulations for linseed oil microencapsulation by spray-drying with high encapsulation efficiency and evaluate their resistance to oxidation through the accelerated Rancimat test. Four formulations were tested; using different combinations of gum arabic (GA), maltodextrin (MD), methyl cellulose (MC) and whey protein isolate (WPI). Microcapsules made of 100% GA and ternary mixtures of GA, MD and WPI presented the highest protection from oxidation and microencapsulation efficiencies higher than 90%. They also presented spherical structures with smooth surfaces which kept unaltered after 10-month storage. GA containing formulation was included in bread manufacturing. Fortified bread resulted similar in appearance to control bread without microcapsules, but α-linolenic acid content was reduced significantly after preparation. ► Linseed oil was encapsulated with gum arabic, maltodextrin and whey protein isolate. ► Microencapsulation efficiency was around 90% for all samples. ► The ternary mixture was the most stable to peroxidation as determined by Rancimat. ► Gum Arabic microcapsules containing linseed oil were tested for bread fortification. ► α-linolenic acid content was reduced significantly after bread manufacturing.
doi_str_mv 10.1016/j.foodres.2013.01.020
format Article
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subjects alpha-linolenic acid
Biological and medical sciences
Bread
breads
Cereal and baking product industries
Computational efficiency
Computing time
food enrichment
Food industries
Foods
Formulations
Functional bread
functional foods
Fundamental and applied biological sciences. Psychology
gum arabic
Linseed oil
manufacturing
methylcellulose
Microencapsulation
omega-3 fatty acids
Oxidation
Rancimat test
spray drying
whey protein isolate
title Microencapsulation of linseed oil by spray drying for functional food application
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