The present invention relates to a water-in-oil emulsion comprising 30-90 wt. % of a structured continuous fat phase and 10-70 wt. % of a dispersed aqueous phase, said structured continuous fat phase comprising: 95-99.9 wt. % fat, said fat having a solid fat content at 20 C. (N.sub.20) of 5-50% and a liquid oil content at 20 C. that equals 100%-N.sub.20; particulate anhydrous non-defibrillated cell wall material from plant parenchymal tissue, said particulate anhydrous non-defibrillated cell wall material having a particle size of between 25 m and 500 m;
wherein the particulate anhydrous non-defibrillated cell wall material is present in the structured continuous fat phase in a concentration of 0.2-10% by weight of the liquid oil.

Incorporation of the aforementioned particulate cell wall material in the fat phase of the water-in-oil emulsion makes it possible to reduce the amount of high melting (hard stock) fat that is required in the production of the emulsion.

Composition of a hypoallergenic, plant-based vegan product by combining water with a hypoallergenic-substrate, and a plant-based butter and/or cream including at least one or more of sunflower seed butter and/or coconut cream. The resulting slurry is then subjected to a preservation process. In an alternative method, the resulting slurry is inoculated in order to reduce its pH.

Method for making a hypoallergenic, plant-based vegan product by combining water with a hypoallergenic-substrate, and a plant-based butter and/or cream including at least one or more of sunflower seed butter and/or coconut cream. The resulting slurry is then subjected to a preservation process. In an alternative method, the resulting slurry is inoculated in order to reduce its pH.

The present invention relates to a process of compacting a microporous fat powder, notably a microporous fat powder that can suitably be used as an oil structuring agent.

One aspect of the invention relates to a process for compacting a microporous fat powder, said process comprising: feeding the fat powder into the feed zone of an extruder having a forwarding screw and a barrel within which said screw is centrally positioned; rotating said forwarding screw to advance said fat powder feed through a compacting zone of the extruder where the barrel comprises a plurality of venting openings having a shorter dimension that exceeds the volume weighted average diameter of the fat powder feed and that is less than 10 mm; and expelling the compacted fat powder from the extruder;
wherein the temperature of the fat powder during passage through the extruder is maintained below 40 C. and wherein the compaction factor achieved exceeds 1.5

Another aspect of the invention relates to a compacted microporous fat powder having the following characteristics: a freely settled density in the range of 90-600 g/l; a particle size distribution with at least 90 vol. % of the particles having a diameter in the range of 20 to 600 m; a maximum G.sub.i/G.sub.d ratio of more than 2.0, wherein G represents the elastic modulus at 10 C. of a dispersion of 2 wt. % of the compacted fat powder in glycerol, and wherein the maximum ratio is determined by recording G.sub.i whilst increasing the frequency from 0.1 to 15 s.sup.1, by subsequently recording G.sub.d whilst decreasing said frequency from 15 to 0.1 s.sup.1, and by calculating the ratio G.sub.i/G.sub.d at the frequency at which said ratio is highest.

New surfactants with emulsifying, bio and eco-compatible properties, having long-chain aliphatic amides, obtained by a green method, deriving from amino acids, fatty acids and/or oils and/or butters, treated with microwave irradiation are provided.

Improved methods for preparing functional food ingredients comprising plant protein, the resulting enhanced functional food ingredients, and foods containing the same. The methods comprise providing a mixture or slurry of plant protein in an aqueous solution, reacting the plant protein with a modification agent selected from the group consisting of an acylating agent, transglutaminase, and protein glutaminase to yield a modified plant protein, and conjugating the modified plant protein with a hydrophilic polysaccharide to yield the functional food ingredient with synergistic improvements in properties.

The present disclosure relates to a foodstuff composition, in particular a spreadable food composition, more in particular an olive oil-based functional spread fat composed by olive oil fortified with a functional ingredientthe olive pomace active ingredient. This functional ingredient is a mixture of bioactive compounds, in particular hydroxytyrosol, tyrosol, sterols, tocopherols, triterpenes, coenzyme Q10, K, Mg and Ca, among others, obtained from olive pomace by mechanical pressing.

A low sugar content sweet food spread is provided said food spread comprising at least one of a cocoa product and a nut product, at least one vegetable oil and at least one sweetener. The at least one vegetable oil is substantially free or free of palm oil and the sugar content of the spread is less than about 20% by weight of the total spread. The food spread possesses excellent properties and is advantageously spreadable at low temperature.

A process is disclosed for modifying citrus fiber. Citrus fiber is obtained having a c* close packing concentration value of less than 3.8 w %, anhydrous basis. The citrus fiber can have a viscosity of at least 1000 mPa.Math.s, wherein said citrus fiber is dispersed in standardized water at a mixing speed of from 800 rpm to 1000 rpm, to a 3 w/w % citrus fiber/standardized water solution, and wherein said viscosity is measured at a shear rate of 5 s1 at 20 C. Citrus fiber can be obtained having a CIELAB L* value of at least 90. The citrus fiber can be used in food products, feed products, beverages, personal care products, pharmaceutical products or detergent products.

This disclosure provides a protein oleogel comprising plant protein dispersed in a liquid oil phase. The oleogel has a microstructure in the form of fibrils, sheets, or other particles with a high aspect ratio that are substantially not interconnected. It can be manufactured by a process that includes solubilizing and denaturing the protein in an aqueous liquid, flash freezing and drying the protein, and then gradually and gently adding a suitable oil or oil mixture. The protein microstructure releases some but not all of the oil when heated. The oleogel forms a spreadable emulsion in an aqueous liquid that is stable for at least six weeks without evidence of creaming. The oleogel may substitute for oils and fats of animal origin in food, food ingredients, cosmetics, and personal care products. This lessens the impact of food manufacturing on the environment, which helps mitigate climate change.