2026-04-20 バージニア工科大学(Virginia Tech)
<関連情報>
- https://news.vt.edu/articles/2026/04/cnre-research-bioplastics.html
- https://www.sciencedirect.com/science/article/abs/pii/S2214289426000402
水系スプレーコーティングプロセスを用いてPHAとHPMCから作製したバイオプラスチック多層フィルムの開発 Development of bioplastic multilayer films fabricated with PHA and HPMC using a water-based spray coating process
Kihyeon Ahn, Chenxi Cao, Zunhuang He, Su Jung Hong, Young-Teck Kim, Haibo Huang, Zhiwu Wang, Eunhye Lee, Yookyoung Shim
Food Packaging and Shelf Life Available online: 19 March 2026
DOI:https://doi.org/10.1016/j.fpsl.2026.101736
Graphical Abstract
Highlights
- A solvent-free strategy was developed for scalable multilayer bioplastic film fabrication.
- Aqueous PHA was spray-coated onto HPMC, but heat treatment was essential for layer formation.
- Hot pressing fused PHA particles, creating a well-laminated multilayer structure with smooth surface.
- Oxygen and moisture barrier properties were significantly improved via hot-pressed lamination.
- This method improves sustainability by using a water-based spray coating process.
Abstract
This study presents a scalable, aqueous-based method for fabricating multilayer biopolymer films using polyhydroxyalkanoate (PHA) in aqueous suspension, eliminating the need for organic solvents. Conventional solvent-based casting is often used due to the poor interfacial adhesion and incompatible thermal properties of bioplastics, which hinder co-extrusion. However, this process suffers from low processing efficiency, solvent dependency, and weak interlayer adhesion, limiting its large-scale applicability. To address these limitations, aqueous PHA suspension was spray-coated onto hydroxypropyl methylcellulose (HPMC) films, followed by hot pressing to form a cohesive multilayer structure. Spray-coating alone caused cavities and uneven PHA distribution. In contrast, hot pressing fused the particles, improving not only the surface smoothness from 5.66 to 0.08 μm (at 5 MPa) but also interfacial bonding among layers. This significantly enhanced barrier properties, lowering the oxygen transmission rate from 120.49 ± 4.63–52.24 ± 1.19 cm3/(m2·day) and the water vapor transmission rate from 1170.31 ± 12.85–423.14 ± 7.75 g/(m2·day). Tensile strength also increased from 42.29 ± 2.47–70.17 ± 3.11 MPa. These results demonstrate the potential of this solvent-free method for scalable production of sustainable, high-performance multilayer packaging films.
