Development of cork biocomposites enriched with chitosan targeting antibacterial and antifouling properties

The demand for bio-based and safer composite materials is increasing due to the growth of the industry, human population, and environmental concerns. In this framework, sustainable and safer cork-polymer composites (CPC), based on green low-density polyethylene (LDPE) were devel- oped using melt-bas...

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Veröffentlicht in:	Molecules (Basel, Switzerland) Switzerland), 2023-01, Vol.28 (3), p.1-20
Hauptverfasser:	Fernandes, Emanuel Mouta, Lobo, Flávia Cristina Marques, Faria, Sara I., Gomes, Luciana C., Silva, Tiago H., Mergulhão, Filipe J. M., Reis, R. L.
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Schlagworte:	Extrusion Green materials Particle reinforcement Science & Technology Surface properties
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container_title	Molecules (Basel, Switzerland)
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creator	Fernandes, Emanuel Mouta Lobo, Flávia Cristina Marques Faria, Sara I. Gomes, Luciana C. Silva, Tiago H. Mergulhão, Filipe J. M. Reis, R. L.
description	The demand for bio-based and safer composite materials is increasing due to the growth of the industry, human population, and environmental concerns. In this framework, sustainable and safer cork-polymer composites (CPC), based on green low-density polyethylene (LDPE) were devel- oped using melt-based technologies. Chitosan and polyethylene-graft-maleic anhydride (PE-g-MA) were employed to enhance the CPC’s properties. The morphology, wettability, mechanical, thermal, and antibacterial properties of the CPC against Pseudomonas putida (P. putida) and Staphylococcus aureus (S. aureus) were examined. The CPC showed improved stiffness when compared with that of the LDPE matrix, preferably when combined with chitosan and PE-g-MA (5 wt. %), reinforcing the stiff- ness (58.8%) and the strength (66.7%). Chitosan also increased the composite stiffness and strength, as well as reduced the surface hydrophilicity. The CPCs’ antibacterial activity revealed that cork significantly reduces the biofilm on the polymer matrix. The highest biofilm reduction was found with CPC containing cork and 5 wt. % chitosan for both P. putida (54% reduction) and S. aureus (36% reduction), confirming their potential to extend the lifespan of products for packaging and healthcare, among other applications. This work leads to the understanding of the factors that influence biofilm formation in cork composites and provides a strategy to reinforce their behavior using chitosan. The work was also supported by the European Union’s Horizon 2020 research and innovation programme under grant agreement No 952471. L.C.G. thanks FCT for financial support of her work contract through the Scientific Employment Stimulus-Individual Call-[CEECIND/01700/2017], and F.C.M.L. acknowledges to FCT for the PhD grant 2021.07421.BD.
doi_str_mv	10.3390/molecules28030990
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The CPC showed improved stiffness when compared with that of the LDPE matrix, preferably when combined with chitosan and PE-g-MA (5 wt. %), reinforcing the stiff- ness (58.8%) and the strength (66.7%). Chitosan also increased the composite stiffness and strength, as well as reduced the surface hydrophilicity. The CPCs’ antibacterial activity revealed that cork significantly reduces the biofilm on the polymer matrix. The highest biofilm reduction was found with CPC containing cork and 5 wt. % chitosan for both P. putida (54% reduction) and S. aureus (36% reduction), confirming their potential to extend the lifespan of products for packaging and healthcare, among other applications. This work leads to the understanding of the factors that influence biofilm formation in cork composites and provides a strategy to reinforce their behavior using chitosan. The work was also supported by the European Union’s Horizon 2020 research and innovation programme under grant agreement No 952471. 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The CPC showed improved stiffness when compared with that of the LDPE matrix, preferably when combined with chitosan and PE-g-MA (5 wt. %), reinforcing the stiff- ness (58.8%) and the strength (66.7%). Chitosan also increased the composite stiffness and strength, as well as reduced the surface hydrophilicity. The CPCs’ antibacterial activity revealed that cork significantly reduces the biofilm on the polymer matrix. The highest biofilm reduction was found with CPC containing cork and 5 wt. % chitosan for both P. putida (54% reduction) and S. aureus (36% reduction), confirming their potential to extend the lifespan of products for packaging and healthcare, among other applications. This work leads to the understanding of the factors that influence biofilm formation in cork composites and provides a strategy to reinforce their behavior using chitosan. The work was also supported by the European Union’s Horizon 2020 research and innovation programme under grant agreement No 952471. 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In this framework, sustainable and safer cork-polymer composites (CPC), based on green low-density polyethylene (LDPE) were devel- oped using melt-based technologies. Chitosan and polyethylene-graft-maleic anhydride (PE-g-MA) were employed to enhance the CPC’s properties. The morphology, wettability, mechanical, thermal, and antibacterial properties of the CPC against Pseudomonas putida (P. putida) and Staphylococcus aureus (S. aureus) were examined. The CPC showed improved stiffness when compared with that of the LDPE matrix, preferably when combined with chitosan and PE-g-MA (5 wt. %), reinforcing the stiff- ness (58.8%) and the strength (66.7%). Chitosan also increased the composite stiffness and strength, as well as reduced the surface hydrophilicity. The CPCs’ antibacterial activity revealed that cork significantly reduces the biofilm on the polymer matrix. The highest biofilm reduction was found with CPC containing cork and 5 wt. % chitosan for both P. putida (54% reduction) and S. aureus (36% reduction), confirming their potential to extend the lifespan of products for packaging and healthcare, among other applications. This work leads to the understanding of the factors that influence biofilm formation in cork composites and provides a strategy to reinforce their behavior using chitosan. The work was also supported by the European Union’s Horizon 2020 research and innovation programme under grant agreement No 952471. L.C.G. thanks FCT for financial support of her work contract through the Scientific Employment Stimulus-Individual Call-[CEECIND/01700/2017], and F.C.M.L. acknowledges to FCT for the PhD grant 2021.07421.BD.</abstract><pub>Multidisciplinary Digital Publishing Institute (MDPI)</pub><doi>10.3390/molecules28030990</doi><oa>free_for_read</oa></addata></record>
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subjects	Extrusion Green materials Particle reinforcement Science & Technology Surface properties
title	Development of cork biocomposites enriched with chitosan targeting antibacterial and antifouling properties
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