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2. Effects of two different pretreatment methods on the nutritional composition, antioxidant capacity, and functional properties of mango (Mangifera indicavar. Kentand Brooks) peel powders usable as healthy ingredients

Author

Assoi, Sylvie, Niamké, Arthur Michel, Konan, N’Guessan Ysidore, Cissé, Mohamed, and Bamba, Bio Sigui Bruno

Abstract

Mango (Mangifera indica)peel is a waste that can be reused as functional ingredients and natural preservatives. However, pretreatments applied to the peel during its conversion into stable storable plant materials generally affect the characteristics of the final product. This work investigated the effects of thermal blanching (100 °C, 1.5 min) and sulphiting (0.1% w/v sodium metabisulphite solution 30 min) on proximate composition, physicochemical and functional properties of var. Kentand Brookspeel powders. Results revealed that control powders were overall acidic (pH ~ 4.2), mainly rich in Calcium followed by potassium then magnesium, and exhibited a light (L* ~ 60), reddish (a*, 8.11–11.20), and predominantly yellow (h*, 70.03–78.80) color. In addition, control powder of the peel of var. Kentexhibited much higher moisture, fat, and antioxidant capacity while control powder of the peel of var. Brooksdisplayed higher water absorption and swelling capacities. Regardless of the variety, each pretreatment significantly varied the chemical compositions, bioactive compound contents, antioxidant activities, functional properties, mineral contents, and color parameters compared to control samples. The principal component analysis revealed that each pretreatment significantly affected the peel’s characteristics. This study showed that pretreatments applied to mango (M. indica) peel during processing can generate tailored peel powders usable as functional ingredients in food formulations.

Published
2024
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6. Couplage photobioréacteur-microfiltration tangentielle pour la production et la récolte à petite échelle de biomasse microalgale

Author

Lozano, Paul, Bamba, Bio Sigui Bruno, Ouattara, Allassane, Abert Vian, Maryline, Adje, Anoh Félix, and Lozano, Yves

Subjects
Q02 - Traitement et conservation des produits alimentaires, M12 - Production de l'aquaculture
Abstract

Arthrospira platensis, plus couramment appelée spiruline, est une cyanobactérie dont les qualités nutritionnelles, reconnues de longue date, résultent de sa composition en protéines, en acides gras essentiels, en vitamines et en minéraux. Cette biomasse très digestible est utilisée dans les programmes de lutte contre la malnutrition et de réhabilitation nutritionnelle en Afrique. Dans les pays développés, la spiruline se positionne sur un marché de niche en nette expansion, porte par les productions a grande échelle mais aussi par le nombre croissant de petits producteurs qui se regroupent actuellement en associations pour nom1aliser et labelliser leurs productions. Cette microalgue est aussi cultivée de façon artisanale dans les pays en développement, notamment en Afrique. On utilise des bassins à ciel ouvert, quelquefois équipes de systèmes d'agitation en circuit ferme (raceways) pour améliorer la nutrition et l'oxygénation de la biomasse microlagale, ainsi que la photosynthèse. Ce type de production, généralement réalisés à grande échelle, contraint les producteurs du Sud à des investissements fonciers relativement onéreux. Ils ont souvent des problèmes sur la qualité de leur production, resultant de contaminations diverses de la biomasse produite, provenant de l'environnement du bassin qui est rarement protège par une serre. La maitrise, tant de la qualité que des couts de production, nous a conduits à rechercher une procédure de culture de microalgue répondant au mieux à cette problématique de production à petite échelle dans le contexte africain. Un procède innovant, peu couteux, pouvant produire à petite échelle de la biomasse de qualité selon un protocole reproductible de production microalgale, a été développé sur la base de la technique du photobioréacteur (PBR). Avec ce système semi-ferme de production, la qualité de la biomasse produite est constante et le rendement obtenu en matière sèche est reproductible. Pour chaque cycle de production de 30 j, le rendement est de 0,9 g.L-1 (85L). Ce PBR peut fonctiom1er dans un environnement de faible technicité et la technique de production s'affranchit des impacts non maitrises de l'environnement sur la culture: pollution, illumination, aération du milieu de culture. I1 peut être duplique localement, notamment pour augmenter la production totale de biomasse d'une même souche ou pour produire de la biomasse à partir diverses souches locales de microalgues. Le couplage de la production avec une technologie de récolte des microalgues, mettant en oeuvre des membranes minérales semi-industrielles sur le principe de la microfiltration tangentielle (MFT), permet la production de biomasses de microalgues de plus petites tailles que la spiruline, comme la chlorelle, l'isochrisis, ou d'autres petites souches locales qui présentent autant d'intérêt. De plus, la MFT permet la purification de l'eau utilisée pour le milieu de culture microalgale, le recyclage de l'eau après le cycle production pour son utilisation dans de nouveaux cycles ou son rejet dans le respect de l'environnement local.

Published
2014

7. Effect of In Vitro Digestion on Water-in-Oil-in-Water Emulsions Containing Anthocyanins from Grape Skin Powder.

Author

Xu, Weili, Yang, Yang, Xue, Sophia Jun, Shi, John, Lim, Loong-Tak, Forney, Charles, Xu, Guihua, and Bamba, Bio Sigui Bruno

Subjects
ANTHOCYANINS, GRAPES, EMULSIONS, CHEMICAL reactions, MOLECULAR dynamics
Abstract

The effects of in vitro batch digestion on water-in-oil-in-water (W/O/W) double emulsions encapsulated with anthocyanins (ACNs) from grape skin were investigated. The double emulsions exhibited the monomodal distribution (d = 686 ± 25 nm) showing relatively high encapsulation efficiency (87.74 ± 3.12%). After in vitro mouth digestion, the droplet size (d = 771 ± 26 nm) was significantly increased (p < 0.05). The double W1/O/W2 emulsions became a single W1/O emulsion due to proteolysis, which were coalesced together to form big particles with significant increases (p < 0.01) of average droplet sizes (d > 5 µm) after gastric digestion. During intestinal digestion, W1/O droplets were broken to give empty oil droplets and released ACNs in inner water phase, and the average droplet sizes (d < 260 nm) decreased significantly (p < 0.05). Our results indicated that ACNs were effectively protected by W/O/W double emulsions against in vitro mouth digestion and gastric, and were delivered in the simulated small intestine phase. [ABSTRACT FROM AUTHOR]

Published
2018
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8. Coencapsulation of Polyphenols and Anthocyanins from Blueberry Pomace by Double Emulsion Stabilized by Whey Proteins: Effect of Homogenization Parameters.

Author

Bamba, Bio Sigui Bruno, Shi, John, Tranchant, Carole C., Xue, Sophia Jun, Forney, Charles F., Lim, Loong-Tak, Xu, Weili, and Xu, Guihua

Subjects
*BLUEBERRIES, *FUNCTIONAL foods, *POLYPHENOLS, *EXTRACTS, *ANTHOCYANINS, *PHENOLS
Abstract

Blueberry pomace is a rich source of high-value bioactive polyphenols with presumed health benefits. Their incorporation into functional foods and health-related products benefits from coencapsulation and protection of polyphenol-rich extracts in suitable carriers. This study aimed to create a water-in-oil-in-water (W1/O/W2) double emulsion system suitable for the coencapsulation of total phenolics (TP) and anthocyanins (TA) from a polyphenol-rich extract of blueberry pomace (W1). The effect of critical physical parameters for preparing stable double emulsions, namely homogenization pressure, stirring speed and time, was investigated by measuring the hydrodynamic diameter, size dispersity and zeta potential of the oil droplets, and the encapsulation efficiency of TP and TA. The oil droplets were negatively charged (negative zeta potential values), which was related to the pH and composition of W2 (whey protein isolate solution) and suggests stabilization by the charged whey proteins. Increasing W1/O/W2 microfluidization pressure from 50 to 200 MPa or homogenization speed from 6000 to 12,000 rpm significantly increased droplet diameter and zeta potential and decreased TA and TP encapsulation efficiency. Increasing W1/O/W2 homogenization time from 15 to 20 min also increased droplet diameter and zeta potential and lowered TA encapsulation efficiency, while TP encapsulation did not vary significantly. In contrast, increasing W1/O homogenization time from 5 to 10 min at 10,000 rpm markedly increased TA encapsulation efficiency and reduced droplet diameter and zeta potential. High coencapsulation rates of blueberry polyphenols and anthocyanins around 80% or greater were achieved when the oil droplets were relatively small (mean diameter < 400 nm), with low dispersity (<0.25) and a high negative surface charge (−40 mV or less). These characteristics were obtained by homogenizing for 10 min at 10,000 rpm (W1/O), then 6000 rpm for 15 min, followed by microfluidization at 50 MPa. [ABSTRACT FROM AUTHOR]

Published
2018
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9. Influence of Extraction Conditions on Ultrasound-Assisted Recovery of Bioactive Phenolics from Blueberry Pomace and Their Antioxidant Activity.

Author

Bamba BSB, Shi J, Tranchant CC, Xue SJ, Forney CF, and Lim LT

Subjects
Antioxidants chemistry, Chromatography, High Pressure Liquid, Ethanol chemistry, Hydrogen-Ion Concentration, Phenols chemistry, Plant Extracts chemistry, Reference Standards, Solvents chemistry, Sonication, Temperature, Time Factors, Water, Antioxidants isolation & purification, Blueberry Plants chemistry, Phenols isolation & purification, Ultrasonics methods
Abstract

The increase in diet-related chronic diseases has prompted the search for health-promoting compounds and methods to ensure their quality. Blueberry pomace is a rich yet underutilized source of bioactive polyphenols. For these high-value bioactive molecules, ultrasound-assisted extraction (USAE) is an attractive and green alternative to conventional extraction techniques for improving purity and yields. This study aimed to assess the impact of USAE parameters (sonication time, solvent composition, solid/liquid ratio, pH and temperature) on the recovery of phenolic compounds from blueberry pomace and antioxidant activity of the extracts. Total phenolic, flavonoid and anthocyanin contents (TPC, TFC and TAC) and 2,2-diphenyl-1-picrylhydrazyl (DPPH) free radical scavenging activity were analysed. USAE in 50% ethanol/water was the most efficient, yielding the highest TPC (22.33 mg/g dry matter (DM)), TFC (19.41 mg/g DM), TAC (31.32 mg/g DM) and DPPH radical scavenging activity (41.79 mg Trolox/g DM). USAE in water showed the lowest values even at low (1/40) solid/liquid ratio (7.85 mg/g DM, 3.49 mg/g DM, and 18.96 mg/g DM for TPC, TFC and TAC, respectively). Decreasing the solid/liquid ratio in water or 50% ethanol significantly increased TPC, TFC, TAC and DPPH radical scavenging. With ethanol, increasing the temperature in the range 20⁻40 °C decreased TPC but increased TFC and DPPH radical scavenging activity. Anthocyanin profiles of water and ethanolic extracts were qualitatively similar, consisting of malvidin, delphinidin, petunidin and cyanidin. These findings indicate that USAE is a method of choice for extracting high-value bioactive phenolics from blueberry pomace. Selective enrichment of different phenolic fractions is possible under select extraction conditions.

Published
2018
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