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Development of biodegradable and antimicrobial electrospun zein fibers for food packaging

Type de document
journalArticle
Langue source
Anglais
Titre français
Développement de fibres de zéine électrofilées biodégradables et antimicrobiennes pour l'emballage alimentaire
Titre anglais
Development of biodegradable and antimicrobial electrospun zein fibers for food packaging
Auteur(s)
  • AYTAC Z.
  • HUANG R.
  • VAZE N.
  • EITZER B. D.
  • KROL W.
  • MCQUEEN L. A.
  • CHANG H.
  • BOUSFIELD D. W.
  • CHANG-PARK M. B.
Editeur(s)
Autre(s)
Id
CYDHZVNI
Version
2217
Url zotero
https://www.zotero.org/groups/2567444/items/CYDHZVNI
Date ajout
19 novembre 2020 12:02
Date modification
5 janvier 2021 10:44
Résumé
There is an urgent need to develop biodegradable and non-toxic materials from biopolymers and nature-derived antimicrobials to enhance food safety and quality. In this study, electrospinning was used as a one-step, scalable, green synthesis approach to engineer antimicrobial fibers from zein using non-toxic organic solvents and a cocktail of nature-derived antimicrobials which are all FDA- classified Generally Recognized as Safe (GRAS) for food use. Morphological and physicochemical properties of fibers, as well as the dissolution kinetics of antimicrobials were assessed along with their antimicrobial efficacy using state of the art analytical and microbiological methods. A cocktail of nature-derived antimicrobials was developed and included thyme oil, citric acid, and nisin. Its ability to inactivate a broad-spectrum of with food-related pathogens was demonstrated. Morphological characterization of the electrospun antimicrobial fibers revealed bead-free fibers 33 with a small average diameter of 165 nm, whereas physicochemical characterization showed high surface area-to-volume ratio (specific surface area:21.91 m2/g) and presence of antimicrobial analytes in the fibers. The antimicrobials exhibited initial rapid release from the fibers in 2 hours into various food simulants. Furthermore, the antimicrobial fibers effectively reduced E. coli and L. innocua populations by ~5 logs for after 24-hours and 1-hour of exposure, respectively. More importantly, due to the small diameter and high surface area-to-volume ratio of the fibers, only miniscule quantities of fiber mass and antimicrobials per surface area (2.50 mg/cm2 of fibers) are needed for pathogen inactivation. The scalability of this fiber synthesis process was also demonstrated using a multi-needle injector with production yield up to 1 g/h. This study shows the potential of using nature-derived biopolymers and antimicrobials to synthesize fibers for sustainable food packaging materials.
Note
None
CRAW tags
  • AB - Utile à l'AB
  • FREDO conservation des productions
  • FREDO durabilité
  • GEO Etats-Unis
  • biopolymers
  • electrospinning
  • emballage
  • food packaging
  • food quality
  • food safety
  • plastics
  • sustainable food packaging
  • zein
WEB tags
Titre de la publication
ACS Sustainable Chemistry & Engineering
Date caractères
09/2020
Date publication
1 septembre 2020
Url publication
http://diseasebiophysics.seas.harvard.edu/wp-content/uploads/2020/09/ACS-Food-Packaging.pdf