Physical properties and fatty acid composition of pomegranate seed oil microcapsules prepared by using starch derivatives/whey protein blends

Sahin-Nadeem, HİLAL; Özen, Murat

doi:10.1002/ejlt.201300355

Physical properties and fatty acid composition of pomegranate seed oil microcapsules prepared by using starch derivatives/whey protein blends

Atıf İçin Kopyala

Sahin-Nadeem H., Özen M. A.

EUROPEAN JOURNAL OF LIPID SCIENCE AND TECHNOLOGY, cilt.116, sa.7, ss.847-856, 2014 (SCI-Expanded)

Yayın Türü: Makale / Tam Makale
Cilt numarası: 116 Sayı: 7
Basım Tarihi: 2014
Doi Numarası: 10.1002/ejlt.201300355
Dergi Adı: EUROPEAN JOURNAL OF LIPID SCIENCE AND TECHNOLOGY
Derginin Tarandığı İndeksler: Science Citation Index Expanded (SCI-EXPANDED), Scopus
Sayfa Sayıları: ss.847-856
Anahtar Kelimeler: Microencapsulation, Pomegranate seed oil, Spray drying, Starch derivatives, Whey protein, FLAXSEED OIL, ENCAPSULATION EFFICIENCY, OXIDATIVE STABILITY, WALL MATERIAL, FISH-OIL, MICROENCAPSULATION, MALTODEXTRIN, OPTIMIZATION, EMULSIFICATION, METHODOLOGY
Akdeniz Üniversitesi Adresli: Evet

Effect of different product formulation on the properties of resulting pomegranate seeds oil (PSO) microcapsules during spray drying encapsulation was studied. PSO microencapsulation was optimized using Box-Behnken's response surface methodology. Emulsion droplet size (3.01-9.21 mu m) and viscosity (16-34 cP), product yield (50-76%), microencapsulation efficiency (76-88%), moisture (2.3-3.5 g/100 g dry matter), water activity (0.17-0.22), bulk density (262-522 kg/m(3)), hygroscopicity (14-23%), solubility (>97%), particle size (11.30-36.27 mu m), and microstructure were analyzed. Three saturated and six unsaturated fatty acids were identified in the PSO; punicic acid was predominant in both unprocessed and microencapsulated ones. The ratio of saturated and unsaturated fatty acids was stable during processing, however, distribution of fatty acids - especially C18:3 isomers - changed by microencapsulation. Optimum product formula which simultaneously maximized the product yield and microencapsulation efficiency was predicted as 75.5 g/100 g emulsion dry matter (EDM) of maltodextrin/modified starch N-LOK (70/30), 24.5 g/100 g EDM of whey protein concentrate, and 15 g oil/100 g EDM. Peroxide and p-anisidine values of the encapsulated PSO were within acceptable range after spray drying. However, the oxidative stability decreased at high temperature (60 degrees C) after 5 days of storage.

Effect of different product formulation on the properties of resulting pomegranate seeds oil (PSO) microcapsules during spray drying encapsulation was studied. PSO microencapsulation was optimized using Box–Behnken's response surface methodology. Emulsion droplet size (3.01–9.21 µm) and viscosity (16–34 cP), product yield (50–76%), microencapsulation efficiency (76–88%), moisture (2.3–3.5 g/100 g dry matter), water activity (0.17–0.22), bulk density (262–522 kg/m³), hygroscopicity (14–23%), solubility (>97%), particle size (11.30–36.27 µm), and microstructure were analyzed. Three saturated and six unsaturated fatty acids were identified in the PSO; punicic acid was predominant in both unprocessed and microencapsulated ones. The ratio of saturated and unsaturated fatty acids was stable during processing, however, distribution of fatty acids – especially C18:3 isomers – changed by microencapsulation. Optimum product formula which simultaneously maximized the product yield and microencapsulation efficiency was predicted as 75.5 g/100 g emulsion dry matter (EDM) of maltodextrin/modified starch N-LOK (70/30), 24.5 g/100 g EDM of whey protein concentrate, and 15 g oil/100 g EDM. Peroxide and p-anisidine values of the encapsulated PSO were within acceptable range after spray drying. However, the oxidative stability decreased at high temperature (60°C) after 5 days of storage.