Christu Tardei scite author profile

Active packaging materials are the subject of research because their performance exceeds that of traditional packaging. From this class, antimicrobial materials extend the shelf-life of products and reduce the risk of contamination by pathogens. In this paper, new composite materials with antimicrobial properties are obtained by using polyvinyl alcohol and bacterial cellulose powder. Potassium (2E,4E)-hexa-2,4-dienoate was used as the antimicrobial agent. The films thus obtained were characterised using Fourier-transform infrared spectroscopy and scanning electron microscopy. Mass transfer phenomena concerning the release of potassium (2E,4E)-hexa-2,4-dienoate were investigated. The results indicated that the new biocomposite films could be used as antimicrobial packaging materials.

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Pb2+ removal from aqueous synthetic solutions by calcium alginate and chitosan coated calcium alginate

Mousa

Simonescu

Pătescu

et al. 2016

Reactive and Functional Polymers

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Magnesium substitution effect on porous scaffolds for bone repair

Crăciunescu

Tardei²,

Moldovan

et al. 2011

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Of great interest in developing artificial bone is the incorporation of magnesium (Mg) ions into the ceramic lattice in order to improve the physico-chemical and structural properties of the material and to increase its morphological affinity towards newly formed osseous tissue. In the present study, we evaluated the morphological and biological properties of composite scaffolds fabricated by mixing a nanopowder of Mg-substituted beta-tricalcium phosphate with collagen type I in two dry weight ratios (variant I and II). We used biochemical methods, and electron and light microscopy to investigate their porosity, biodegradability and morphology. Osteoblast cell culture behavior in the presence of nanocomposite variants was also examined. Variant I scaffold presented a higher percentage of cross-links and a better resistance to collagenase degradation compared to variant II scaffold. Their porosity did not vary significantly. Osteoblasts cultivated in the presence of nanocomposite scaffolds for 72 h exhibited good cell viability and a normal morphology. When osteoblasts were injected into the scaffolds, a slightly higher proportion of adhered cells were observed for Mg-substituted samples after 7 days of cultivation. All these results showed that Mg-containing porous composite scaffolds had controlled degradation, allowed osteoblast proliferation and adhesion and are good candidates for bone repair.

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Size particle effects on the thermal stability of poly(lactic acid) / hydroxyapatite hybrids for biodegradable package

Zaharescu¹,

Tardei²,

Râpă

et al. 2020

Ceramics International

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Christu Tardei

Biodegradable Mg alloys for orthopedic implants – A review

Potassium sorbate release from poly(vinyl alcohol)-bacterial cellulose films

Pb2+ removal from aqueous synthetic solutions by calcium alginate and chitosan coated calcium alginate

Magnesium substitution effect on porous scaffolds for bone repair

Size particle effects on the thermal stability of poly(lactic acid) / hydroxyapatite hybrids for biodegradable package

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