Masoud Ghaani scite author profile

Background Intelligent packaging is the newest technology within the food packaging field. Even though this technology is still growing and not fully commercially viable, it has enormous potential to improve the safety, quality, and traceability of food products, as well as its convenience for consumers. Scope and Approach This paper first describes both the technical aspects and commercial applications of the most representative intelligent technologies-indicators, data carriers, and sensors-with special focus on systems and devices that are directly integrated into the package. Secondly, to provide useful guidelines for future research in the field, the paper discusses some important aspects that still hinder the full exploitation of intelligent technology within the food packaging industry.

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Enzymatic Hydrolysis in the Green Production of Bacterial Cellulose Nanocrystals

Rovera

Ghaani

Santo

et al. 2018

ACS Sustainable Chem. Eng.

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In this study, we extensively describe experimental models, with correlating experimental conditions, which were used to investigate the enzymatic hydrolysis of bacterial cellulose (BC) to obtain nanocrystals. Cellulase from Trichoderma reesei was used in five enzyme/BC ratios over a period of h. The turbidity data was modeled using both logistic regression and empirical regression to determine the fractal kinetics, resulting in unique kinetic patterns for the mixtures that were richest in BC and in enzymes. The evolution of the yield was inversely related to the turbidity, as confirmed through a semi-empirical approach that was adopted to model the experimental data. The yield values after 74 h of hydrolysis were higher for the substrate-rich mixtures (~20%) than for the enzyme-rich mixtures (~5%), as corroborated by cellobiose and glucose quantification. Transmission electron microscopy and atomic force microscopy analyses revealed a shift from a fibril network to a needlelike morphology (i.e., aggregated nanocrystals or individual nanocrystals ~6 nm width and 200-800 nm in length) as the enzyme/BC ratios went from lower to higher. These results were explained in terms of the heterogeneous substrate model and the erosion model. This work initiated a promising, environmental-friendly method that could serve as an alternative to the commonly used chemical hydrolysis routes.

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Nano-inspired oxygen barrier coatings for food packaging applications: An overview

Rovera

Ghaani

Farris

2020

Trends in Food Science & Technology

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Graphene Oxide Bionanocomposite Coatings with High Oxygen Barrier Properties

et al. 2016

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In this work, we present the development of bionanocomposite coatings on poly(ethylene terephthalate) (PET) with outstanding oxygen barrier properties. Pullulan and graphene oxide (GO) were used as main polymer phase and nanobuilding block (NBB), respectively. The oxygen barrier performance was investigated at different filler volume fractions (ϕ) and as a function of different relative humidity (RH) values. Noticeably, the impermeable nature of GO was reflected under dry conditions, in which an oxygen transmission rate (OTR, mL·m−2·24 h−1) value below the detection limit of the instrument (0.01 mL·m−2·24 h−1) was recorded, even for ϕ as low as 0.0004. A dramatic increase of the OTR values occurred in humid conditions, such that the barrier performance was totally lost at 90% RH (the OTR of coated PET films was equal to the OTR of bare PET films). Modelling of the experimental OTR data by Cussler’s model suggested that the spatial ordering of GO sheets within the main pullulan phase was perturbed because of RH fluctuations. In spite of the presence of the filler, all the formulations allowed the obtainment of final materials with haze values below 3%, the only exception being the formulation with the highest loading of GO (ϕ ≈ 0.03). The mechanisms underlying the experimental observations are discussed.

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Development of an electrochemical nanosensor for the determination of gallic acid in food

et al. 2016

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In the present work, a silver nanoparticle/delphinidin modified glassy carbon electrode (AgNP/Delph/GCE) was fabricated as a highly sensitive electrochemical sensor for gallic acid (GA) determination. Cyclic voltammetry experiments indicated a higher sensitivity and better selectivity for gallic acid when using the AgNP/Delph/GCE as compared with the bare GCE surface, which were attributed to AgNPs and delphinidin, respectively. Moreover, the calculated surface electron transfer rate constant (k s ), and the electron transfer coefficient (a) between the GCE and the electrodeposited delphinidin demonstrated that delphinidin is an excellent electron transfer mediator for the electrocatalytic process. The average catalytic rate constant (k 0 ) of the overall process was also estimated to be 7.40 Â 10 À4 cm s À1 for the AgNP/Delph/GCE in the presence of 1.50 mmol L À1 of GA. Amperometry experiments were used to determine the limit of detection of the AgNP/Delph/GCE electrochemical sensor, which was 0.28 mmol GA. The activity of the modified electrode was eventually investigated to assess the potential quantification of GA in real foods.

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Masoud Ghaani

An overview of the intelligent packaging technologies in the food sector

Enzymatic Hydrolysis in the Green Production of Bacterial Cellulose Nanocrystals

Nano-inspired oxygen barrier coatings for food packaging applications: An overview

Graphene Oxide Bionanocomposite Coatings with High Oxygen Barrier Properties

Development of an electrochemical nanosensor for the determination of gallic acid in food

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