Abstract
Nanoclay particles have been usually introduced into protein-based bioplastics to obtain composite materials, showing enhanced mechanical properties. However, the addition of partially exfoliated nanoclay particles in these protein matrices may also involve an increase of others properties such as water absorption capacity, which may lead to the obtention of super absorbent biodegradable materials. Processing technologies exerted a remarkable influence on the techno-functional properties of the soy-based bioplastics studied in this research. On the one hand, extrusion technique led to bioplastics which showed enhanced mechanical properties. On the other hand, injection moulding technique yielded to non-exfoliated nanoclay particles within the protein matrix, which involved improvements of water absorption capacity. The development of superabsorbent protein-based biodegradable materials implied a deep knowledge of physicochemical properties of proteins and processing conditions of bioplastics. Extrusion or injection moulding techniques could be selected to obtain tailored protein-based bioplastics with enhanced properties.
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Acknowledgements
This work is part of a research project sponsored by MINECO/FEDER, “Ministerio de Economía y Competitividad”, from the Spanish Government (Ref. CTQ2015-71164-P). The authors also acknowledge University of Seville for a grant supported by VPPI-US.
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Felix, M., Martínez, I., Aguilar, J.M. et al. Development of Biocomposite Superabsorbent Nanomaterials: Effect of Processing Technique. J Polym Environ 26, 4013–4018 (2018). https://doi.org/10.1007/s10924-018-1262-z
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DOI: https://doi.org/10.1007/s10924-018-1262-z