Vitamin E Encapsulation within Oil-in-Water Emulsions: Impact of Emulsifier Type on Physicochemical Stability and Bioaccessibility

Fabrication of zein/alginate delivery system for nanofood model based on pumpkin

Gastrectomy is among the most crucial types of surgeries proposed to treat gastric cancer and obesity. Gastrectomy patients experience difficulties such as energy deficit, anorexia, and malnutrition. The objective of the present study was to introduce nanofood as a fruitful strategy to supply the needed energy and nutrients for these patients and particularly control the release of proteins, lipids, and carbohydrates on the simulated gastrointestinal tract (GIT). Cooked pumpkin puree (CPP), sodium caseinate, sesame oil, rice bran oil, rice starch, sugar and pectin were applied to prepare oil in water nanoemulsion. Six delivery systems were prepared including various concentrations of zein (0.02-0.15% w/v) and alginate (0.01-0.16% w/v) in acidic (2.45-2.81) and alkaline (11.45-11.82) pH ranges. The particle size (83.5-207.0 nm) and calorific values (467.2-498.4 Cal/100 g) of samples were measured. Encapsulated food matrix nanoemulsion with zein/alginate's biopolymers delivery system (0.15:0.16 w/v, pH = 8.30) with 489.9 Cal/100 g exhibited the least digestible nutrients in the mouth (0.10%>) and gastric phase (6.91%>). It has high release nutrients in the small intestine phase (72.14%>). Therefore, it is introduced as the optimal formulation. The use of CPP in nanoemulsion formulation besides other ingredients is a good strategy to prepare nanofood for gastrectomy patients.

Encapsulation of Lipid-Soluble Bioactives by Nanoemulsions

Lipid-soluble bioactives are important nutrients in foods. However, their addition in food formulations, is often limited by limited solubility and high tendency for oxidation. Lipid-soluble bioactives, such as vitamins A, E, D and K, carotenoids, polyunsaturated fatty acids (PUFA) and essential oils are generally dispersed in water-based solutions by homogenization. Among the different homogenization technologies available, nanoemulsions are one of the most promising. Accordingly, this review aims to summarize the most recent advances in nanoemulsion technology for the encapsulation of lipid-soluble bioactives. Modern approaches for producing nanoemulsion systems will be discussed. In addition, the challenges on the encapsulation of common food ingredients, including the physical and chemical stability of the nanoemulsion systems, will be also critically examined.

Emulsifying Properties of an Homologous Series of Medium- and Long-Chain d-Maltotriose Esters and their Impacts on the Viabilities of Selected Cell Lines

The development of functional as well as nutritional surfactants for the food industry remains a matter of great interest. In the present study, a series of 6″-O-acylmaltotriose monoesters bearing alkyl side chains of 10-18 carbons was prepared by enzymatic means. The emulsions derived from those monoesters incorporating palmitoyl, stearoyl, and oleoyl side chains generally displayed advantageous shelf-lives, superior resistance to environmental variations, and more favorable droplet size distributions as well as stronger cytotoxic effects against various cancer cell lines. Ester 6 was shown to significantly inhibit the proliferation of MCF-7 breast cancer cells by inducing G1 phase arrest. Specifically, the levels of the G1 phase-related markers cyclin D1 and cyclin E as well as the cycle-dependent kinase 4 were suppressed by this particular ester. This study thus reveals that maltotriose esters can not only serve as novel functional food emulsifiers but also act, in vitro, as notable cytotoxic agents through a well-defined mechanism-of-action.

Development of Next-Generation Nutritionally Fortified Plant-Based Milk Substitutes: Structural Design Principles

Consumers are increasingly interested in decreasing their dietary intake of animal-based food products, due to health, sustainability, and ethical concerns. For this reason, the food industry is creating new products from plant-based ingredients that simulate many of the physicochemical and sensory attributes associated with animal-derived foods, including milk, eggs, and meat. An understanding of how the ingredient type, amount, and organization influence the desirable physicochemical, sensory, and nutritional attributes of these plant-based foods is required to achieve this goal. A potential problem with plant-based diets is that they lack key micronutrients, such as vitamin B12, vitamin D, calcium, and ω-3 fatty acids. The aim of this review is to present the science behind the creation of next-generation nutritionally fortified plant-based milk substitutes. These milk-like products may be formed by mechanically breaking down certain plant materials (including nuts, seeds, and legumes) to produce a dispersion of oil bodies and other colloidal matter in water, or by forming oil-in-water emulsions by homogenizing plant-based oils and emulsifiers with water. A brief overview of the formulation and fabrication of plant-based milks is given. The relationship between the optical properties, rheology, and stability of plant-based milks and their composition and structure is then covered. Approaches to fortify these products with micronutrients that may be missing from a plant-based diet are also highlighted. In conclusion, this article highlights how the knowledge of structural design principles can be used to facilitate the creation of higher quality and more sustainable plant-based food products.

Bioaccessibility and stability of β-carotene encapsulated in plant-based emulsions: impact of emulsifier type and tannic acid

The effect of two plant-based emulsifiers (quillaja saponin, QS and gum arabic, GA) and a polyphenol (tannic acid) on the formation, stability, digestibility, and β-carotene (BC) bioaccessibility of flaxseed oil-in-water emulsions was investigated.