beta-carotene and maltodextrin

Peanut skins are a low-value byproduct of the peanut processing industry. Following their removal during the preparation of common peanut products, they are either discarded or used as a minor component of animal feed. Studies have found peanuts skins to be rich in health promoting phenolic compounds and thus have potential as a functional food ingredient. The aim of this study was to evaluate a new product that included the encapsulated phenolic extract from peanut skins in a flavored coating for peanuts. The phenolic compounds were extracted from peanut skins and then encapsulated in 10.5% (w/w) maltodextrin in to reduce the bitter flavor. The encapsulated phenolic extract was added at varying concentrations to honey roast flavored and chili lime flavored coatings which were applied to roasted peanuts. The resulting total phenolic content and antioxidant potential of the coated peanuts were evaluated by the Folin-Ciocalteu, DPPH, and β-carotene bleaching assays. A best estimate sensory threshold for the peanut skin extract in the honey roasted and chili lime coating was found to be 12.8% (w/w) and 16.6% (w/w), respectively. The total phenolic content and antioxidant capacity for both the honey roasted and chili lime coated peanuts at their threshold was found to be significantly higher than control peanuts that did not contain peanut skins in the coating. The increased antioxidant activity and unaltered flavor profile at the sensory threshold levels of peanut skins demonstrated their potential as a functional food ingredient.. The ability of polyphenols to act as antioxidants suggests that extracts of peanut skins containing polyphenols can be used as functional ingredients in new food products. The encapsulation of peanut skin extract in maltodextrin allowed for the incorporation of the extracts into flavored coatings for peanuts at levels high enough to increase the antioxidant activity without impacting sensory profiles. Utilization of this by-product of the peanut can create an economic opportunity for the peanut industry.

Topics: Allergens; Antioxidants; Arachis; beta Carotene; Biphenyl Compounds; Calcium Compounds; Capsicum; Food Analysis; Free Radicals; Functional Food; Honey; Oxides; Phenols; Picrates; Plant Extracts; Polyphenols; Polysaccharides; Taste

Beta-carotene is important for fortification of nutritional products while its application is limited by instability. The influence of maltodextrin (MDX) on physicochemical properties and stability of beta-carotene emulsions stabilized by sodium caseinate (SC) was investigated. The emulsions were characterized by dynamic light scattering (DLS), laser diffraction (LD), transmission electron microscopy (TEM), rheometer, and turbiscan lab expert. The effects of pH, ionic strength, and freeze-thaw on stability of emulsions were observed. The emulsions could tolerate up to 2 mol/L NaCl or 10 mmol/L CaCl

Topics: beta Carotene; Drug Delivery Systems; Emulsions; Particle Size; Polysaccharides

Degradation of dispersed lipophilic compounds in hydrophilic solids depends upon matrix stability and lipid physicochemical properties. This study investigated effects of solid microstructure and size of lipid droplets on the stability of dispersed β-carotene in freeze-dried systems. Emulsions of β-carotene in sunflower oil were dispersed in maltodextrin systems (M040/DE6, M100/DE11, and M250/DE25.5) (8% w/w oil) and prefrozen at various freezing conditions prior to freeze-drying to control nucleation and subsequent pore size and structural collapse of freeze-dried solids. The particle size, physical state, and β-carotene contents of freeze-dried emulsions were measured during storage at various water activity (a(w)) using a laser particle size analyzer, differential scanning calorimeter, and high performance liquid chromatography (HPLC), respectively. The results showed that M040 stabilized emulsions in low temperature freezing exhibited lipid crystallization. Collapse of solids in storage at a(w) which plasticized systems to the rubbery state led to flow and increased the size of oil droplets. Degradation of β-carotene analyzed using a reversed-phase C(30) column followed first-order kinetics. Porosity of solids had a major effect on β-carotene stability; however, the highest stability was found in fully plasticized and collapsed solids.

Topics: beta Carotene; Calorimetry, Differential Scanning; Chromatography, High Pressure Liquid; Drug Stability; Emulsions; Freeze Drying; Kinetics; Particle Size; Polysaccharides; Temperature

The use of encapsulation in amorphous matrices of carbohydrate and/or polymer formed during dehydration processes to enhance the stability and retention of labile compounds is increasing in the food and pharmaceutical industries. Efforts to improve encapsulating properties have been made using mixtures of carbohydrates with proteins or gums in different proportions. The objective of the present work was to study the stability of encapsulated β-carotene and its degradation kinetics in maltodextrin/gum arabic and maltodextrin/gelatin matrices in relation to the physical properties and state of the dehydrated matrix.. The degradation of β-carotene followed a first-order kinetic model of fractional retention for all encapsulating matrices. The Guggenheim-Anderson-de Boer (GAB) model was adequate to describe the sorption isotherms of the studied systems. β-Carotene losses were observed mainly at relative humidities (RHs) above the glass transition temperatures (T(g) ) of the corresponding systems, where the matrices were fully plasticised and collapsed (75 and 92% RH). At these high RHs the best β-carotene retention was obtained in the system containing gum arabic.. The results showed that pigment degradation was determined by the physical state of the matrix, related to the degree of collapse. They represent a contribution to the knowledge of physical factors that affect the retention kinetics of labile biomolecules encapsulated in dehydrated matrices.

Topics: Adsorption; beta Carotene; Calorimetry, Differential Scanning; Desiccation; Food Additives; Food Coloring Agents; Food Handling; Food, Fortified; Freeze Drying; Gelatin; Gum Arabic; Kinetics; Models, Chemical; Physical Phenomena; Pigmentation; Polymers; Polysaccharides; Temperature; Transition Temperature; Water