Characterization of biodegradable bi-layer films from thermoplastic starch and poly-l-lactic acid
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2024Author
Parlak, Mahmut EkremUzuner, Kubra
Ozdemir, Sebahat
Kirac Demirel, Fatma Tuba
Dundar, Ayse Neslihan
Sahin, Oya Irmak
Dagdelen, Adnan Fatih
Odabas, Halil Ibrahim
Saricaoglu, Furkan Turker
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Characterization of biodegradable bi-layer films from thermoplastic starch and poly-l-lactic acid Mahmut Ekrem Parlak, Kubra Uzuner, Sebahat Ozdemir, Fatma Tuba Kirac Demirel, Ayse Neslihan Dundar, Oya Irmak Sahin, Adnan Fatih Dagdelen … See all authors First published: 01 March 2024 https://doi.org/10.1002/app.55378Abstract
This study aimed to enhance the oxygen barrier properties of polylactic acid (PLA) film, a biodegradable packaging material with high oxygen permeability (OP). Bi-layer films were produced by coating thermoplastic starch (TPS) onto PLA films in various ratios while maintaining constant film thickness. The mechanical, optical, barrier, thermal, hydrophobicity, moisture sorption, and microstructural properties of the films were analyzed. Increasing the TPS ratio elevated moisture content (MC), water uptake, solubility, and opacity while enhancing UV barrier properties. TPS coating reduced tensile and burst strength but increased the burst deformation of the bi-layer films. Bi-layer film production resulted in a water vapor permeability increase of 59.26%–94.44% compared with neat PLA while decreasing OP by 2.52%–29.66%. The equilibrium moisture content (EMC) rose with higher TPS ratios, displaying type II isotherms. FTIR analysis indicated no chemical interactions between PLA and TPS. Increasing the TPS ratio decreased PLA crystallinity, supporting the mechanical and barrier properties of the bi-layer films. Neat and bi-layer films exhibited smooth, homogeneous surfaces, with a visible interface in the cross-section of the bi-layer films. In conclusion, TPS shows promise as an alternative to improve oxygen barrier properties in PLA films without adversely affecting other properties. © 2024 Wiley Periodicals LLC.