• Title of article

    Gelation of charged bio-nanocompartments induced by associative and non-associative polysaccharides

  • Author/Authors

    Antunes، نويسنده , , Filipe E. and Coppola، نويسنده , , Luigi and Rossi، نويسنده , , Cesare Oliviero and Ranieri، نويسنده , , Giuseppe Antonio and Terenzi، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2008
  • Pages
    7
  • From page
    134
  • To page
    140
  • Abstract
    Vesicles composed of sodium oleate (NaO) and monoolein (MO) are adequate candidates for drug nanoencapsulation and controlled release due to their stability and perceived biocompatibility. The object of the present study is to design hydrogels based on those anionic vesicles and polymers of both non-associative and associative type. The selected macromolecules were k-carrageenan (KC), carboxymethyl cellulose (CMC) and hydrophobically modified carboxymethyl cellulose (HMCMC). While the polymer-vesicle association was probed by rheology, the influence of the polymer on the vesicle stability was monitored by cryo-TEM and calorimetric measurements. fects of the polymer on the rheological properties of surfactant aggregate solutions clearly depend on the polymer type: the storage moduli of the polymer–vesicle mixtures, compared to the vesicles alone, increases around 2 orders of magnitude if the polymer is non-associative and 4 orders of magnitude if the macromolecule is of associative type. vesicles are added, the non-associative polymer networks tend to be disrupted, while the networks formed by associative polymer get more robust. These observations can be explained by fundamental changes in electrostatic/hydrophobic interactions: vesicles entrapped in KC networks convert the polysaccharide in a highly charged entity and favor high electrostatic repulsions between the chains; this encourages network collapse. The opposite picture is experienced in HMCMC systems, i.e., such network is stabilized by the presence of vesicles. This is ascribed to the enhanced hydrophobic association, compensating the electrostatic repulsions between vesicles and polymer chains.
  • Keywords
    Monoolein , Networks , k-carrageenan , HMCMC , Carboxymethyl Cellulose , sodium oleate , Biovesicle
  • Journal title
    Colloids and Surfaces B Biointerfaces
  • Serial Year
    2008
  • Journal title
    Colloids and Surfaces B Biointerfaces
  • Record number

    1969394