Microencapsulation and Storage Stability of Lycopene Extracted from Tomato Processing Waste

Ranveer, R. C.; Gatade, Abhijeet A.; Kamble, Harshwardhan A.; Sahoo, A. K.

doi:10.1590/s1516-89132015060366

Cited by 15 publications

(8 citation statements)

References 19 publications

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“…Rodrigues-Huezo et al (51) reported values for encapsulation efficiency between 25.6 and 87.5% for encapsulates obtained by spray drying of emulsions containing carotenoids using gum arabic, gellan gum and maltodextrin as encapsulation materials (49). In the study of Ranveer et al (52) the effect of different process parameters, core to wall ratio, sucrose to gelatin and inlet temperature on encapsulation yield and encapsulation efficiency of lycopene in encapsulates obtained by spray-drying technique were investigated. Highest encapsulation efficiency (92.6 %) and encapsulation yield (82.2%) was observed when the core to wall ratio was 1:4, sucrose to gelatin ratio was 7:3 and inlet temperature was 180 °C (52).…”

Section: Resultsmentioning

confidence: 99%

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Encapsulation of carotenoids extracted from tomato waste

et al. 2020

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Utilization of carotenoids as a nutraceutical ingredients or natural colorants within foods is currently limited due to their instability. Encapsulation is one of the prominent means used to improve carotenoid stability. In this study the content of bioactive compounds (lycopene, ?-carotene and phenolics) and antioxidant activity (DPPH, ABTS, superoxide anion and reducing power test) were investigated in the tomato waste extract. Based on the obtained results, tomato waste showed high contents of lycopene (13.72 mg/100 g DW), ?-carotene (12.36 mg/100 g DW) and phenolic compounds (203.33 mg/100 g DW). Also, high values of antioxidant activity were determined in all applied tests. To protect extracted sensitive carotenoid compounds (lycopene and ?-carotene) tomato waste extract was encapsulated with various encapsulating materials (soy protein, pea protein, inulin and gum arabica) by freeze drying method. The influence of applying different encapsulating materials on the encapsulation efficiency of carotenoids (lycopene and ?-carotene) was studied. Also, obtained encapsulates were characterized in terms of water activity, moisture content, hygroscopicity, flowability, density ratios and particles size. Encapsulate on the basis of gum arabic showed highest encapsulation efficiency of ?-carotene (53.47%), while encapsulate prepared with soy protein as encapsulating material showed highest encapsulation efficiency of lycopene (51.44%). The results of this study support the need for preparation of encapsulates with different encapsulating material and evaluation of their characteristics with the aim of development powder forms suitable for supplementation and food fortification.

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Section: Resultsmentioning

confidence: 99%

“…Among several strategies to protect carotenoids, encapsulation is one that has been often applied and was found to enhance the stability of carotenoids (12). The protective mechanism of encapsulation is to form a membrane (wall system) to enclose the droplets or particles of the encapsulated material (core) (13).…”

Section: Introductionmentioning

confidence: 99%

Encapsulation of carotenoids extracted from tomato waste

et al. 2020

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“…For instance, Ranveer et al . () reported that approximately 92.6% of the compounds were entrapped after spray‐drying in agreement with Rocha‐Selmi et al . (), who reported more than 90% EE using complex coacervation.…”

Section: Resultsmentioning

confidence: 99%

Encapsulationof lycopene from watermelon in calcium‐alginate microparticles using an optimised inverse‐gelation method by response surface methodology

Celli

Teixeira

Duke

et al. 2016

Int J of Food Sci Tech

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Summary Lycopene exhibits strong antioxidant activity due to its unsaturated molecular bonds, which also contributes to its susceptibility for degradation. Encapsulation techniques can reduce lycopene degradation, increasing its potential applications in functional foods and nutraceuticals. The objective of this study was to optimise the encapsulation of lycopene from watermelon in alginate microparticles using the inverse gelation method. Box–Behnken design was used for the optimisation of three variables: concentrations of alginate (w/v %) and CaCl2 (g L−1), and gelation time (min). Two types of alginate were investigated (low viscosity and high viscosity) and optimised separately using encapsulation efficiency and loading capacity as responses. Results indicated that the models had a good fit to the experimental data and the optimal conditions varied depending on the type of alginate. In general, particles prepared with low‐viscosity alginate exhibited higher encapsulation efficiency and loading capacity and could be used for further research.

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“…Na escolha da proporção dos materiais que integram a mistura física inicial, por não existirem pesquisas de uso do CH como biomaterial na formação de partículas, foram utilizadas como referência as pesquisas onde a gelatina tem sido usada como biomaterial carreador do licopeno mediante métodos convencionais (CHIU et al 2007;RANVEER et al 2015; ROCHA-SELMI; FÁVARO-TRINDADE; GROSSO, 2013;SHU et al 2006;SILVA et al 2012), pois a gelatina é um material de natureza similar ao CH.…”

Section: Preparo Da Mistura Física Inicialunclassified

“…Seu consumo tem sido promovido pois sua alta atividade antioxidante protege contra doenças influenciadas por reações de radicais livres, tais como o câncer de próstata, câncer de pâncreas, câncer de estomago, câncer de pele, e doenças cardiovasculares (KUN; LULE; XIAO-LIN, 2006;PERVEEN et al, 2015;SOARES et al, 2015). Porém, o licopeno é susceptível à isomerização e oxidação por fatores ambientais como a luz, temperatura e oxigênio, durante o processamento tecnológico e armazenamento (LEE;CHEN, 2002;RANVEER et al, 2015;SHI et al, 2002). Assim, uma maneira de protegê-lo, facilitar o uso como ingrediente e garantir sua presença e estabilidade nos produtos que o conterão (ROCHA; FÁVARO-TRINDADE; GROSSO, 2012) é mediante a formação de partículas em pó usando materiais carreadores biológicos de natureza polimérica (COCERO et al, 2009;ĐORĐEVIĆ et al, 2015; SALDAÑA; COIMBRA; CARDOZO-FILHO, 2015).…”

Section: Introductionunclassified

Estudo da formação de partículas de licopeno em colágeno hidrolisado usando CO<sub>2</sub> supercrítico

Tisnado¹,

Jesús²

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Microencapsulation and Storage Stability of Lycopene Extracted from Tomato Processing Waste

Abstract: The aim of this study was to optimize the encapsulation of lycopene using response surface methodology and to determine its stability.

Cited by 15 publications

References 19 publications

Encapsulation of carotenoids extracted from tomato waste

Encapsulation of carotenoids extracted from tomato waste

Encapsulationof lycopene from watermelon in calcium‐alginate microparticles using an optimised inverse‐gelation method by response surface methodology

Estudo da formação de partículas de licopeno em colágeno hidrolisado usando CO<sub>2</sub> supercrítico

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