Wild Passiflora (Passiflora spp.) seed oils and their nanoemulsions induce proliferation in HaCaT keratinocytes cells

Nanoencapsulation of quinoa oil enhanced the antioxidant potential and inhibited digestive enzymes

Quinoa oil is rich in unsaturated fatty acids and vitamin E, but its instability limits its application in food, pharmaceutical, and cosmetic products. Nanoencapsulation emerges as a promising strategy to promote water dispersibility, preserve and enhance functional properties, and increase the bioavailability of bioactive compounds. This study encapsulated quinoa oil through O/W emulsification, using porcine gelatin (OG) and isolated whey protein (OWG) as encapsulating agents. The particles were characterized by different physical and chemical methods and evaluated in vitro for cytotoxicity using Chinese hamster ovary (CHO) cells, human hepatocarcinoma cells (HepG2) and epithelial cells, and bioactive potential through the determination of Total Antioxidant Capacity (CAT) (acidic and neutral media) and iron chelation, and inhibition of digestive enzymes (α-amylase and amyloglucosidase). OG and OWG particles presented smooth surfaces, with an average size between 161 ± 7 and 264 ± 6 nm, with a polydispersity index of 0.11 ± 0.03 and 0.130 ± 0.04, encapsulation efficiency of 74 ± 1.47 % and 83 ± 2.92 %, and water dispersibility >70 %, respectively. Free and nanoencapsulated quinoa oil did not show cytotoxic effects (cell viability >70 %). Nanoencapsulation promoted the enhancement of the antioxidant activity of quinoa oil in the range of 50-63 % in a neutral medium and 96-153 % in an acidic medium than free oil (p < 0.05). OG and OWG also enhanced the inhibition of the enzymes α-amylase (by 5-7 %) and amyloglucosidase (6-9 times more) than free oil (p < 0.05). The results showed that nanoencapsulation increased the potential for quinoa oil application, enabling the development of innovative products.

Tumbo, an Andean fruit: Uses, nutrition, processing, and biomolecules

Tumbo fruit has potential for industrialization due to its nutritional and functional properties, but scientific knowledge of this species is still limited compared to other species of the same genus, Passiflora. This review compiles the latest scientific advances on Tumbo, which cover the food technological aspects of Tumbo fruit, its uses and its potential as a source of bioactives for different industries, especially food, pharmaceutical, and cosmetics. The products (nectar, jellies, jams, wines, others) and by-products of the processing of the Tumbo fruit have various nutritional, sensory, and composition attributes for developing new food and non-food products. The potential applications of the fruit and its derivatives are broad, such as cosmetics, drugs, functional foods, and additives; these applications are due to its technological properties and its content of bioactive molecules. The Tumbo biorefinery presents an important perspective, especially for its bioactivity of high biological value for different industries.

From Benznidazole to New Drugs: Nanotechnology Contribution in Chagas Disease

Chagas disease is a neglected tropical disease caused by the protozoan Trypanosoma cruzi. Benznidazole and nifurtimox are the two approved drugs for their treatment, but both drugs present side effects and efficacy problems, especially in the chronic phase of this disease. Therefore, new molecules have been tested with promising results aiming for strategic targeting action against T. cruzi. Several studies involve in vitro screening, but a considerable number of in vivo studies describe drug bioavailability increment, drug stability, toxicity assessment, and mainly the efficacy of new drugs and formulations. In this context, new drug delivery systems, such as nanotechnology systems, have been developed for these purposes. Some nanocarriers are able to interact with the immune system of the vertebrate host, modulating the immune response to the elimination of pathogenic microorganisms. In this overview of nanotechnology-based delivery strategies for established and new antichagasic agents, different strategies, and limitations of a wide class of nanocarriers are explored, as new perspectives in the treatment and monitoring of Chagas disease.

Resveratrol-Loaded Attalea funifera Oil Organogel Nanoparticles: A Potential Nanocarrier against A375 Human Melanoma Cells

This study aimed to evaluate Attalea funifera seed oil with or without resveratrol entrapped in organogel nanoparticles in vitro against A375 human melanoma tumor cells. Organogel nanoparticles with seed oil (SON) or with resveratrol entrapped in the seed oil (RSON) formed functional organogel nanoparticles that showed a particle size <100 nm, polydispersity index <0.3, negative zeta potential, and maintenance of electrical conductivity. The resveratrol entrapment efficiency in RSON was 99 ± 1%. The seed oil and SON showed no cytotoxicity against human non-tumor cells or tumor cells. Resveratrol at 50 μg/mL was cytotoxic for non-tumor cells, and was cytotoxic for tumor cells at 25 μg/mL. Resveratrol entrapped in RSON showed a decrease in cytotoxicity against non-tumor cells and cytotoxic against tumor cells at 50 μg/mL. Thus, SON is a potential new platform for the delivery of resveratrol with selective cytotoxic activity in the treatment of melanoma.

Extracted saponin from Anabasis setifera plant as a biosurfactant for stabilization of oil in water (O/W) nano-emulsion based on date palm (Phoenix dactylifera) kernel oil

Saponin was extracted from the Anabasis setifera plant and used to stabilize an oil-in-water (O/W) emulsion based on date palm kernel oil. Different amounts of the extracted saponin were used with a constant oil concentration (1.5% w/w). The droplet size distribution, emulsion droplet size value (d-ave), polydispersity index (PDI) and zeta potential of the emulsions were determined using dynamic light scattering (DLS). These parameters were measured and compared after seven days of emulsion preparation. The best results (d-ave = 41.7 nm, PDI = 0.1 and zeta potential = −29.8 mV) were obtained for the CMC of saponin. Both the oil and the surfactant were specifically extracted and used from the nature of Saravan in the Baluchestan region of Iran. This research presents a green and cost-effective aspect for potential formulations of nano-emulsions that can be used in the food and cosmetic industries.