Development and properties of biodegradable film from peach palm (Bactris gasipaes).

Formulations of biodegradable films using macrocarpa peach palm flour (low amylose starch), chitosan and glycerol, were developed and the effects of the drying temperature on films by assessing their physicochemical, mechanical, barrier, optical, structural, antioxidant properties, and the biodegradability in soil were evaluated. Chitosan enhanced the mechanical properties of the films, but they showed no antimicrobial activity against the tested food-borne pathogens, except for Listeria monocytogenes, for which the inhibition zone was from 0.1 to 0.6 cm. Films with higher concentrations of peach palm flour are opaquer, with better antioxidant characteristics and content of phenolic compounds compared to films made with lower concentrations of flour. The films presented a yellowish color because of the carotenoids found in peach palm flour, 29.63 µg 100 g-1, and exhibited a C-type X-ray pattern, characteristic peak of materials where amylose and amylopectin are present. After 15 days in soil, the films lost 30% of their initial weight. Therefore, these results suggest that the development of films as food preservative is a promising field and that the material used in the study are suitable for their formulation.

Phenolic compounds and antioxidant activity in vitro and in vivo of Butia and Opuntia fruits.

Despite the consumption recommendations and the potential health benefits, Brazilian biodiversity has a large number of fruit species that are still unexplored, such as Butia catarinensis (Butiá da Praia), Butia eriospatha (Butiá da Serra) and Opuntia elata (Arumbeva). The phenolic compounds of these fruits were determined by HPLC-DAD-MS/MS. Morever, in vitro assays of antioxidant capacity on hydroethanolic extracts against hydrogen peroxide (H2O2), hydroxyl (OH), peroxyl (ROO) and ABTS radicals were evaluated. In vivo assays evaluating the survival of worms and reactive oxygen species (ROS) generation were performed using the nematode Caenorhabditis elegans. Eighteen, twenty-eight and seventeen phenolic compounds were identified in Butiá da Praia, Butiá da Serra and Arumbeva, respectively. The main groups of phenolic compounds found in the fruits were hydroxybenzoic acids (60.5, 26.5 and 96.1% of the total phenolic compounds for Butiá da Praia, Butiá da Serra and Arumbeva, respectively), flavan-3-ols (23.6 and 61.2% of the total phenolic compounds for Butiá da Praia and Butiá da Serra) and flavonols (2.6% of the total phenolic compounds for Arumbeva). The hydroethanolic extracts of these fruits were free radical scavenger, sources of phenolic compounds and did not cause toxic effects in vivo. In hydroethanolic extracts of Butiá da Praia and Arumbeva, the total phenolic content increased by around 67% and 35%, respectively. Besides the health benefits, these proved to be promising sources of natural antioxidants, with phenolic composition variating among species and collection site. The obtained results enable future applications of studied fruits extracts in food and/or pharmaceutical products, encouraging and valuing the sustainable use of biodiversity.

Mucilage and cladode flour from cactus (Opuntia monacantha) as alternative ingredients in gluten-free crackers.

Cactus cladode offers innovative ingredients such as cactus mucilage (CM) and cladode flour (CF) for producing gluten-free snacks. Five different crackers were formulated: C-C (control cracker prepared with 2% of commercial gums), C-CM (cracker containing 2% of CM instead of commercial gums), C-CF5, C-CF10, and C-CF15 (crackers incorporated of 5%, 10%, and 15% CF, respectively - free of commercial gums). CF characterization is also presented, demonstrating its great technological potentiality. The proximate composition of C-CM and C-CF mostly differed for ash and fiber content as compared to C-C. In general, crackers' physical properties were not impacted by CM or CF addition, except for the darker color of CF-supplemented crackers. The C-CM and CF-incorporated crackers showed higher total phenolics and antioxidant activity. Additionally, the latter samples were enhanced with carotenoids. Sensory evaluation revealed that C-CM and C-CF5 were those most accepted. Therefore, CM and CF are interesting alternatives for gluten-free cracker formulation.

Incorporation of zeaxanthin nanoparticles in yogurt: Influence on physicochemical properties, carotenoid stability and sensory analysis.

Zeaxanthin nanoparticles (Zea-NP) and zeaxanthin nanoemulsion (Zea-NE) were incorporated in yogurt. Control yogurt (CY), yogurt added of nanoparticles (Y-NP) and yogurt added of nanoemulsion (Y-NE) were evaluated weekly regarding pH, titratable acidity, color, textural parameters, viscosity and syneresis during 28 days. Zeaxanthin retention in Y-NP and Y-NE was also determined over storage. Sensory attributes and morphology were evaluated in all yogurt samples, and zeaxanthin bioaccessibility after in vitro digestion was analyzed in Y-NP and Y-NE after preparation. At the end of storage time, zeaxanthin retention was higher in Y-NP (22.31 ±â€¯2.53%) than in Y-NE (16.84 ±â€¯0.53%). Despite the lower firmness and viscosity observed in Y-NP, these changes were not sensory perceived. The bioaccessibility after in vitro digestion suggested that nanoencapsulation provided a controlled release of the carotenoid. Zea-NP can be incorporated in yogurt, allowing the dispersion of a hydrophobic compound in a hydrophilic matrix, providing stability.

Nanoencapsulation of linseed oil with chia mucilage as structuring material: Characterization, stability and enrichment of orange juice.

Linseed oil was nanoencapsulated with chia seed mucilage (CSM) as structuring material. Linseed oil nanoparticles (LO-NP) were evaluated regarding particle size distribution, zeta potential, pH, viscosity, encapsulation efficiency, loading capacity, morphology, FT-IR and thermal properties. Furthermore, the nanoparticles were spray-dried, and oxidative stability was evaluated during 28 days under storage at accelerated conditions (40 °C). The bioaccessibility of spray dried nanoparticles (SP LO-NP) was also evaluated after in vitro digestion. Thereafter, SP LO-NP were utilized in the enrichment of orange juice, and physicochemical and sensory evaluation of pure orange juice and orange juice with SP LO-NP were evaluated. Nanoparticles in suspension presented a mean diameter of 356 ±â€¯2.83 nm, zeta potential of -22.75 ±â€¯3.89 mV and encapsulation efficiency of 52%. No significant differences regarding consumer acceptance were observed between pure orange juice and orange juice with SP LO-NP. The results suggest that CSM can be used as structuring material to nanoencapsulate hydrophobic compounds, allowing its solubility in foods with high water content. Furthermore, the SP LO-NP provided a good bioaccessibility to linseed oil after in vitro digestion, which represents an advantage to incorporate the nanoparticles in food.