Browsing by Author "Vaz, M."
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- Green tea as a promising extract of active food packagingPublication . Vilarinho, Fernanda; Martins, C.; Ramos, F.; Castilho, M.C.; Vaz, M.; Sanches-Silva, A.Introduction: Tea is one of the most popular and frequently consumed beverages in the world and its consumption dates back to more than 2000 years in China and then spread to other areas including Japan and later on to Europe (Zhao et al., 2014). Green tea is produced from Camellia sinensis (L.) Kuntze leaf infusion and is well known for its pleasant flavour and is associated with positive health effects. The biological activity of green tea is related with the considerable amount of catechins and other phenolic compounds, in particular flavonols and phenolic acids, present in its composition (Zhao et al., 2014). These phenolic compounds prevent the oxidative damage through their antioxidant activity and also reduce the risk of cancer, cardiovascular and neurodegenerative diseases (Lorenzo et al., 2014). The process of oxidation is one of the most common mechanisms of degradation of foodstuffs and it can alter food texture and colour, decrease nutritional quality, develop off-odours and also produce possible toxic compounds. As a consequence, the shelf-life and commercial acceptability of the food products decrease. Currently, one of the major concerns of the consumers is the impact of food on health. In line with this, food industry is trying to substitute synthetic additives by natural compounds. These can be directly added to food or incorporated in food packaging with the aim of being controlled released throughout the product shelf life. This concept is so-called Active packaging and allows the packaging to positively interact with foods to increase food shelf-life. This interaction can be due to the intended release of compounds from packaging to the foods or to their headspace, or due to the scavenging of compounds by the packaging from the packaged foods. Due to the antioxidant capacity of green tea, its extract can be proposed as an alternative to synthetic antioxidants (Giménez et al., 2013). In fact, it has already been applied in active food packaging. Material and Methods: The present review focuses on the application of green tea extract in active packaging. In this regard, an extensive bibliographic research was carried out in order to evaluate the polymers already used to incorporate green tea extract, as well as the mechanical and barrier properties and efficiency of these packaging systems in contact with foods. Results and Discussion: The chemical composition of tea leaves on active compounds with antioxidant activity is well documented. Bioactive constituents of the tea leaves include catechin gallates such as epigallocatechin gallate and gallocatechin gallate (López de Dicastillo et al., 2011). However the levels of these compounds depend on many factors, such as the edaphoclimatic conditions and drying conditions of the Camellia sinensis leaves. Moreover the extraction and analysis methods can also have a great influence in their content. Green tea extract has already been incorporated into different polymers. In fact, most of them are edible such as proteic films from distilled dry beans (Yang et al., 2016), agar (Lacey et al., 2014), chitosan (Siripatrawan et al., 2012; Siripatrawan et al., 2010) and gelatine (Hong et al (2009). Green tea extract (GTE) can offers protection against oxidation, significantly reducing rancidity and thereby extending the shelf-life of packaged foods. Moreover the sensory analysis also demonstrated that packaged food was unaffected by GTE (Carrizo et al., 2016). According to Yang et al. (2016), the incorporation of the GTE did not alter the physical properties of the films. According to Siripatrawan et al. (2010), the incorporation of GTE improved the mechanical and water vapour barrier properties. In general, GTE provides a very positive impact in the reduction of oxidation of all types of food, from aqueous to fatty (López de Dicastillo et al., 2011), although most of the studies selected meat (e.g. pork, pork sausages, pork loins), or fish products (e.g. fillets of hake, salted sardines) to test the efficiency of the active films. Conclusion: Green tea has great potential of application in active food packaging due to its antioxidant capacity. Therefore, in the near future, is it possible that new food packaging based on GTE will arise in the market. However, more studies are require to elucidate about the concentrations of GTE that do not affect or affect positively the mechanical or barrier properties of the packaging and that are effective as oxidation inhibitors of packaged foods
- Lipid oxidation of a meat product packaged with poly (lactic acid)/clay nanocompositesPublication . Vilarinho, Fernanda; Buonocore, Giovanna; Vaz, M.; Sanches-Silva, A.Introduction: Polylactic acid or polylactide (PLA, Poly) is a biodegradable thermoplastic aliphatic polyester derived from renewable resources, such as corn starch, tapioca roots, chips or starch, or sugarcane. Biopolymer nanocomposites are of great interest to the packaging industry as they can overcome the limitations of biopolymers compared to synthetic polymers. In the last two decades, the nanocomposites have been studied intensively, once the addition of fillers such as organoclays, in particular, montmorillonite (MMT), can improve rheological, thermal and mechanical properties of the biopolymers (Jollands M. et al. 2010). The presence of MMT can lead to materials which generally exhibit great property enhancements, mainly due to its intercalation or exfoliation into the polymer chains. In this work, PLA was incorporated with 5% (w/w) Cloisite Na+ prepared through a two-step process: first extrusion of pellets and secondly melted matter was pressed. The nanocomposite was used to pack a model food (salami) in order to evaluate of the ability of the new packaging to inhibit lipid oxidation. Thiobarbituric Acid Reactive Substances (TBARS) assay was used to evaluate the lipid oxidation stage. This assay allows to measure malondialdehyde (MDA) content, which is formed in the lipid oxidation of polyunsaturated fatty acids. Material and Methods: Packaged salami was homogenized with trichloroacetic acid (10 %) in 0.02 M of orthophosphoric acid and the solution was filtered. The filtered solution was homogenized with thiobarbituric acid aqueous solution (0.02 M) and heated at 100 °C for 40 min. Solutions were cooled down and absorbance was measured at 530 nm. Results were expressed as mg MDA per kg of salami. Results and Discussion: Salami slices were packaged with a control film and with the nanocomposite and analysed at initial time and after 15, 30, 60 and 90 days of contact. Results showed that salami packaged with the nanocomposite presented lower amount of MDA after all contact periods, except after 60 days, where there were no differences between control and nanofilm. Conclusion: Although the results showed that the new nanocomposite tends to reduce the production of MDA, further studies should be carried out to confirm the inhibition of lipid oxidation, such as the peroxide index, p-anisidine value, or the monitorization of a lipid oxidation indicator like hexanal.
- Monitorization of hexanal as lipid oxidation indicator in a processed meat product packaged with poly(lactic acid)/clay nanocomposite filmsPublication . Vilarinho, Fernanda; Buonocore, Giovanna; Stanzione, M.A.; Vaz, M.; Sanches-Silva, A.One of the most detrimental processes in fatty foodstuffs is lipid oxidation, which occurs during production and storage, and influences food composition and safety. Through the analysis of volatile lipid oxidation products we can have an insight into the oxidation, and some volatiles, such as hexanal, which can be markers of undergoing oxidation processes. Hexanal is formed when fatty acids are oxidized and is one of many well-documented aromatic components that contributes to flavour and aroma in common food products containing fatty acids. During the last decade, the interest in polymer layered silicate (PLS) nanocomposites has rapidly increased due to their potential for enhancing physical, chemical, and mechanical properties of conventional materials. Polymer nanocomposites are represented by a polymeric matrix reinforced with nanoscale fillers, among them the most common silicate clays are represented by montmorillonite (MMT), which is naturally occurring and readily available in large quantities. The presence of MMT can lead to materials which generally exhibit great property enhancements, mainly due to its intercalation or exfoliation into the polymer chains. In this work natural MMT Cloisite Na+ was incorporated in PLA. The PLA/Cloisite® Na+ films were prepared through a two-step process. In the first step, PLA pellets were fed into a corotating laboratory twin-screw extruder at 170 °C and 50 rpm for 2 min. Subsequently, Cloisite® Na+ powder (5%, w/w) were added and mixed. After extrusion, the melted matter was then pressed with a P300P hot press at 170 °C and 100 bar to obtain the PLA/Cloisite® Na+ films. Salami slices were packaged with PLA-OMMT film and with a control film (PLA). After different storage times (0, 15, 30, 60 and 90 days), salami slices were analysed regarding their hexanal content. The hexanal derivatization was performed in a solution of 2,4-dinitrophenylhydrazine in sulfuric acid during 4 h in the dark, and the hexanal extraction was performed with n-hexane and evaporation till dryness. The residue was dissolved in methanol, filtered and analysed. The quantification of hexanal was performed by Ultra High Performance Liquid Chromatography coupled with Diode Array Detector at 365 nm, with a Pre-column AcquityTM UPLC® BEH C18 (2.1 x 5 mm, 1.7 μm particle size) and a column AcquityTM UPLC® BEH C18 (2.1 × 50 mm, 1.7 μm particle size), the mobile-phase was acetonitrile-water (75:25, v/v). The amount of hexanal in packaged salami decreased in the first 60 days of storage. In this period of time the hexanal content of the salami packaged with the PLA/Cloisite® Na+ films was lower than the salami packaged with control film, except after 15 days of storage, where there was no difference between two films. After 90 days of storage, the amount of hexanal in the samples increased, although it was higher in the samples packaged with control film (94.7 ± 6.02 μg/100g salami) than salami packaged with PLA/Cloisite® Na+ films (65.1 ± 6.12 μg/100g salami). The presence of MMT in the polymer film can reduce the lipid oxidation of processed meat products, extending their shelf life. Further studies to evaluate differences between PLA and the nanocomposite (PLA-5%Cloisite®Na+) in what regards to the mechanical and barrier properties are in progress.
- Polylactic acid reinforced with nanocellulose: current applications and future trendsPublication . Vilarinho, Fernanda; Silva, Ana Sanches; Vaz, M.; Farinha, JoséIn recent years renewed interest on the development of biopolymers, based on constituents obtained from natural resources is gaining much attention. Reinforced biopolymer with natural fibres is the future of ‘‘green composites’’ addressing many sustainability issues. Among the available biopolymer, Polylactic acid (PLA) is the only natural resource polymer produced at a large scale of over 140,000 tonnes per year. PLA is a biodegradable thermoplastic aliphatic polyester derived from renewable resources, such as corn starch (in the United States and Canada), tapioca roots, chips or starch (mostly in Asia), or sugarcane (in the rest of the world). In 2010, PLA had the second highest consumption volume of any bioplastic of the world. Natural fibre reinforced PLA based biocomposites are widely investigated by the polymer scientists in the last decade to compete with non renewable petroleum based products. The type of fibre used plays an important role in fibre/matrix adhesion and thereby affects the mechanical performance of the biocomposites. For the processing of polymer nanocomposites, cellulose nanoparticles are an ideal candidate, because of their mechanical properties, reinforcing capabilities, abundance, low density, and biodegradability. Cellulose is probably the most used and well-known renewable and sustainable raw materialA comprehensive and exhaustive review was carried out based on the combination of nanocellulose with PLA to produce nanocomposite materials. The processing conditions to obtain the nanoscale materials are summarized and discussed. The main advantages and limitations of these nanomaterials are addressed. The addition of cellulose nanocrystals (CNC) to the biopolymers such as PLA, is pioneer of a new potential to create innovative bio-nanocomposite materials with improved properties and performance. However, safety issues of nanocellulose should be precisely monitored and controlled in order to confirm whether it has no harmful effects on human´s health and on environment.