This thesis has an approved one-year embargo applied to it. Please, refer to the corresponding forms, and please, so not publish immediately until the embargo has been sorted out. The thesis contains two unpublish papers and patents pending. Thank you! / Conventional single-use plastic packaging has contributed significantly to the health and well-being of our society but also negatively impacted our environment due to its persistence after use. Since recycling is not a complete solution, rapidly biodegradable materials like thermoplastic starch (TPS) blends offer a more sustainable alternative. Additionally, to stave off the premature breakdown of starch-containing materials as well as extend the shelf life of enclosed foods, microbial control strategies need to be developed. To overcome the inherent brittleness of TPS, this work explores the potential of xylitol and erythritol as melt plasticizers for waxy corn starch (̴100% amylose). Characterizations revealed that both xylitol and erythritol can gelatinize and plasticize starch under 25% wt. Particularly, xylitol demonstrated superior plasticizing and compatibilizing effects, leading to a ductile TPS packaging film with uncharacteristically high elongation at break (EB, 422% ± 48%). The ductile TPS was blended with up to 70% Ecovio bioplastic without requiring compatibilizers and retaining much of its EB value (298 ± 24%). Using xylitol as a melt plasticizer also enhanced the mechanical and hydrophobic qualities of the TPS/Ecovio film as well as its oxygen permeability and puncture extension. Furthermore, polymerized curcumin copolymer (PCEG) was investigated as a grafted coating onto the developed TPS/Ecovio® blend. The antimicrobial activity of PCEG and PCEG coating film was evaluated against foodborne bacteria. The polymerized curcumin by itself demonstrated antimicrobial activity against the gram-negative bacteria Escherichia coli BL21 and Pseudomonas aeruginosa PA01, as well as the gram-positive bacterium Staphylococcus aureus. Additionally, the PCEG-coated films showed surface inhibition of Glutamicibacter soli (IAI-3), a gram-positive bacterium making polymerized curcumin copolymer coatings a suitable approach to add antimicrobial features in thermoplastic starch composites for biodegradable food packaging. / Thesis / Master of Applied Science (MASc) / Canada's Zero Plastics initiative represents a commitment to the environment while upholding the advancements in food safety and public health that come with single-use food packaging. Achieving this balance demands the creation of novel materials. These materials should mimic the qualities of synthetic polymers but have the added ability to decompose naturally in the environment upon reaching the end of their utility. A significant challenge in this effort is preventing the premature degradation of starch-containing packaging materials. Moreover, extending the shelf life of the food they enclose is equally crucial. To solve this paradox, the development of microbial control strategies becomes imperative. This study highlights the antimicrobial potential of a polymerized curcumin copolymer (PCEG) as a coating on a blend of thermoplastic starch (TPS)/xylitol/Ecovio®, creating an innovative packaging film. The curcumin copolymer coating exhibited antimicrobial properties, suggesting its potential use in thermoplastic starch composites for biodegradable food packaging.
Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/28896 |
Date | January 2023 |
Creators | Doratt Mendoza, Juan |
Contributors | Thompson, Michael, Liu, Qiang, Chemical Engineering |
Source Sets | McMaster University |
Language | English |
Detected Language | English |
Type | Thesis |
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