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Encapsulation of bioactive compounds extracted from<i>Cucurbita moschata</i>pumpkin waste: the multi-objective optimisation study

Slađana Stajčić, Lato Pezo, Jasna Čanadanović‐Brunet, Gordana Ćetković, Anamarija Mandić, Vesna Tumbas Šaponjac, Jelena Vulić, Vanja Šeregelj, Jovana Petrović

2022Journal of Microencapsulation11 citationsDOI

Abstract

AIM: Artificial neural network (ANN) development to find optimal carriers (pea protein-P, maltodextrin-M, and inulin-I) mixture for encapsulation of pumpkin waste bioactive (β-carotene and phenolics). METHODS: Freeze-drying encapsulation and encapsulates characterisation in terms of bioactive contents and encapsulation efficiencies, water activity, hygroscopicity, densities, flowability, cohesiveness, particle size (laser diffraction), solubility, colour (CIELab), morphological (SEM), stability and release properties. RESULTS: Optimal encapsulates, OE-T (with highest total bioactive contents; P, M, and I of 53.9, 46.1, and 0%w/w) and OE-EE (with highest bioactive encapsulation efficiencies; P, M, and I of 45.5, 32.0, and 22.5%w/w) had particle diameters of 94.561 ± 1.341 µm and 90.206 ± 0.571 µm, the span of 1.777 ± 0.094 and 1.588 ± 0.089, highest release at pH 7.4 of phenolics of 71.03%w/w after 72 h and 66.22%w/w after 48 h, and β-carotene of 43.67%w/w after 8 h and 48.62%w/w after 6 h, respectively. CONCLUSION: ANN model for prediction of encapsulates' preparation, showed good anticipation properties (with gained determination coefficients of 1.000).

Topics & Concepts

MaltodextrinCucurbita moschataParticle sizeMaterials scienceSolubilityChemistrySpray dryingNuclear chemistryFood scienceChromatographyOrganic chemistryMedicineAlternative medicinePhysical chemistryPathologyMicroencapsulation and Drying ProcessesFood Drying and ModelingFreezing and Crystallization Processes
Encapsulation of bioactive compounds extracted from<i>Cucurbita moschata</i>pumpkin waste: the multi-objective optimisation study | Litcius