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An Innovative Method for the Recycling of Waste Carbohydrate-Based Flours.

Carola Esposito CorcioneRaffaella StrianiFrancesca FerrariPaolo ViscontiDaniela RizzoAntonio Greco
Published in: Polymers (2020)
This work represents an innovative study that, for the first time, explores the possibility to use waste flours to produce thermoplastic polymeric bio-films. To the best of our knowledge, this is the first time that waste flours, derived from bakeries, pizzerias or pasta factories, have been proposed for the production of bio-polymers, as a replacement of neat starch. To this aim, durum waste flour derived from a pasta factory, soft waste flour derived from pizzerias and neat maize starch used as control material were firstly analyzed from dimensional, morphological and chemical points of view. Afterwards, waste flour films were produced by the addition of a nature-based plasticizer, glycerol. Mechanical characterization of the plasticized thermoplastic films, produced by compression molding, evidenced low performances, even in the case of the neat maize starch. In order to improve the mechanical properties, the possibility to include polylactic acid and cardanol-based plasticizer was also investigated. Mass transport properties of all the produced bio-films were investigated by measuring their water vapor permeability and hygroscopic absorption. The durability properties of the bio-films were assessed by accelerated ageing tests, while the bio-degradability of the waste-based films was evaluated by measuring the solubility and the degradation in water. The physicochemical analyses of the novel bio-films evidenced good mechanical properties; specifically, the waste-based films showed a lower hygroscopic absorption and water solubility than those of the blends containing neat starch.
Keyphrases
  • heavy metals
  • room temperature
  • sewage sludge
  • municipal solid waste
  • life cycle
  • carbon nanotubes
  • healthcare
  • drug delivery
  • risk assessment
  • mass spectrometry
  • cancer therapy
  • endothelial cells
  • ionic liquid