Microencapsulation of extra virgin olive oil by sequential emulsification and freeze drying processes: Effect of wall materials composition and emulsification method-Reference-Cited by-同舟云学术

Microencapsulation of extra virgin olive oil by sequential emulsification and freeze drying processes: Effect of wall materials composition and emulsification method

Published:2023-06-19 Issue:2 Volume:52 Page:235-244
ISSN:0139-3006
Container-title:Acta Alimentaria
language:
Short-container-title:AAlim

Author:

Chaabane D.¹,Yakdhane A.¹,Ayari E.²,Klosz K.¹,Albert K.¹,Gáspár I.¹,Ladányi M.³,Koris A.¹^ORCID,Nath A.¹

Affiliation:

1. Department of Food Process Engineering, Institute of Food Science and Technology, Hungarian University of Agriculture and Life Sciences, Ménesi út 44, HU-1118, Budapest, Hungary

2. Department of Refrigeration and Livestock Products Technology, Institute of Food Science and Technology, Hungarian University of Agriculture and Life Sciences, Ménesi út 43–45, HU-1118, Budapest, Hungary

3. Department of Applied Statistics, Institute of Mathematics and Basic Science, Hungarian University of Agriculture and Life Sciences, Villányi út 29–43, HU-1118, Budapest, Hungary

Abstract

AbstractFor a long time, olive oil has been considered for formulation of biopharmaceuticals and received a prestigious place in cuisine for its unique organoleptic and nutritional properties. Nevertheless, oxidation of fatty acids in olive oil provides short shelf-life and undesirable organoleptic properties. Thus, microencapsulation of olive oil is a considerable promising approach to maintain its quality and biological activities. The objective of this investigation was to prepare extra virgin olive oil microcapsule by sequential technologies, such as water emulsification of olive oil with wall material (matrix) and freeze drying of emulsion. The effect of wall material composition was examined to prepare microcapsule of extra virgin olive oil. Different ratios of wall materials such as maltodextrin (MD), carboxymethyl cellulose (CMC), and gum arabic (GA) were used. Furthermore, effects of emulsification technologies, such as homogenisation with rotor–stator homogeniser (RSH) and cross-flow membrane emulsification (CFME) were investigated. The stability of emulsion was higher when emulsion was prepared by RSH; however, the droplet mean diameter (D32) was lower in case of RSH compared to CFME. The highest encapsulation efficiency (EE) was found as 68.96 ± 2.6% when CFME was adopted and composition of wall materials was 15 g MD, 15 g GA, and 5 g CMC.

Publisher

Akademiai Kiado Zrt.

Subject

Food Science

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