Browsing by Author "Pedrosa, Mariana C."
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- Lemna minor: unlocking the value of this duckweed for the food and feed industryPublication . Sosa, Diana; Alves, Felipe M.; Prieto, Miguel A.; Pedrosa, Mariana C.; Heleno, Sandrina A.; Barros, Lillian; Feliciano, Manuel; Carocho, MárcioDuckweed (Lemna minor L.) is a small floating aquatic plant that has an important economic impact in several industrial areas. With its high biomass production, reasonable protein content, and resilience to several climates, it has been attracting increasing interest for potential use in animal and human food systems. Historically consumed in southwest Asia, this duckweed is now gaining attention as a potential novel food in Europe. This manuscript explores the contributions of duckweed to various food and feed industries, including aquaculture and livestock, while also pointing out the incipient research carried out for human consumption. Most importantly, it highlights the potential of Lemna minor as a vegetable for future human consumption whether eaten whole or through extraction of its nutrients.
- Optimization of cinnamon (Cinnamomum verum J. Presl.) essential oils extraction using hydrodistillation (Clevenger apparatus)Publication . Pedrosa, Mariana C.; Heleno, Sandrina; Pintado, Manuela; Barros, Lillian; Carocho, Márcio
- Response surface methodology applied to essential oil extraction of eucalyptus leavesPublication . Hached, Hanine; Pedrosa, Mariana C.; Heleno, Sandrina; Barros, Lillian; Vaz, Josiana; Carocho, MarcioPlant volatiles are secondary metabolites with a wide range of applications in several industries, namely the textile, food, pharma, and perfumery. These molecules are usually from three major groups, the terpenoid, phenylpropanoid/benzenoid and fatty acid derivatives group. This work focused on applying the response surface methodology technique towards optimizing the yield in essential oils of Eucalyptus globulus Labill, extracted by hydro distillation. For this, three factors were varied, namely the time of extraction (variation between 180 to 270 min), particle size (varying between 1 and 3 mm), and solid/liquid ration (varying between 10 and 50 g/L). The response recorded was the amount (g) of recovered essential oil. Using the optimization function, the optimal points were set at 260 minutes of extraction time, particle size of 1.2 mm and 50 g/L ratio. The model was significant, and the lack of fit was not, allowing for an R2 of 0.9911 and an adjusted R2 of 0.9777. Figure 1 shows the 3D charts of the response-surface. The model predicted that, at the optimal point, the yield in essential oils is 0.707 g, an amount above the one found in any of the 17 extraction conditions performed. Overall, the most important of the three factors was the solid to liquid ratio, showing that this factor accounts for most variations in the amount of pure essential oil, followed by particle size and finally, the least important factor, extraction time. This study allows an optimization of the extraction of essential oils from eucalyptus by showing that larger amounts of extract render more oil, as well as smaller particle sizes, while the extraction time has a low influence, thus allowing for shorter extraction times, which corresponds to lower energetic waste. The results herein are important for the food industry, specifically for new food additives, but also as flavorings for grain-based foods.