• Title of article

    Fabrication and characterization of filled hydrogel particles based on sequential segregative and aggregative biopolymer phase separation

  • Author/Authors

    Alison Matalanis، نويسنده , , Uri Lesmes، نويسنده , , Eric Andrew Decker، نويسنده , , David Julian McClements، نويسنده ,

  • Issue Information
    ماهنامه با شماره پیاپی سال 2010
  • Pages
    13
  • From page
    689
  • To page
    701
  • Abstract
    In this study, filled hydrogel particles were created based on the ability of proteins and ionic polysaccharides to phase separate through both aggregative (complexation) and segregative (incompatibility) mechanisms. At pH 7, a mixture of 3% (w/w) high-methoxy pectin and 3% (w/w) sodium caseinate phase separated through a segregative mechanism. Following centrifugation, the phase separated system consisted of an upper pectin-rich phase and a lower casein-rich phase. Casein-coated lipid droplets added to the phase separated pectin/caseinate system partitioning into the lower casein-rich phase. This was attributed to a reduction in the unfavorable osmotic stress in this phase associated with biopolymer depletion. When shear was applied this system formed an oil-in-water-in-water (O/W1/W2) emulsion consisting of oil droplets (O) contained within a casein-rich watery dispersed phase (W1) suspended in a pectin-rich watery continuous phase (W2). Acidification of the O/W1/W2 system from pH 7–5 promoted adsorption of pectin around the casein-rich W1 droplets, resulting in the formation of filled hydrogel particles (d = 3–4 μm) that remained stable to aggregation or dissociation when stored for 24 h at ambient temperature. These particles may be useful as encapsulation and delivery systems for lipophilic components in the food, cosmetics and pharmaceutical industries.
  • Keywords
    Pectin , Caseinate , Thermodynamic incompatibility , Hydrogel particles , Coacervation , electrostatic interactions , Segregation , aggregation
  • Journal title
    Food Hydrocolloids
  • Serial Year
    2010
  • Journal title
    Food Hydrocolloids
  • Record number

    978833