Abstract: The present invention relates to a method for producing frozen confectionery products. In particular, the invention is concerned with a method which contributes to the improvement of textural and sensorial attributes of the confections obtained thereof, in particular of products based on lower fat formulations. The method includes the use of controlled heat (between 90° C. and 140° C. for 5 seconds to 30 minutes) on an acidified ice confection mix (pH between 5.6 and 6.5) to at least partially form a coagulated protein system including casein whey protein. Such a protein system is used according to the invention in frozen confection prepared by conventional freezing alone or combined with low temperature freezing wherein it improves the microstructure and stability on frozen products.

Abstract: A food composition including a solution of about 5,000 ppm to about 300,000 ppm steviol glycoside; about 1,000 ppm to about 995,000 ppm food grade non-aqueous solvent; with a balance being water.

Abstract: Disclosed is confectionery having a transparent or translucent hard candy shell and a water-in-oil emulsion centerfill. Also disclosed is a sugar-free liquid edible composition and use in confectionery products.

Abstract: A method and system for making a low-water activity filling, such as crème type fillings, is provided. The fillings advantageously can be used with rotary sandwiching machines without the need for a cooling tunnel downstream of the scraped-surface heat exchanger in the production line. The fillings produced herein comprise a fat component and sugar source, and the fat in the filling has the desired crystalinity. The process and system described herein unexpectedly achieve both a desired nucleation and crystallization rate and crystal structure, as well as the resulting increased filling firmness, in the fillings produced therewith.

Abstract: Provided is frozen noodles in which freezer burn is unlikely to occur. A method for producing frozen noodles comprises: a step of attaching a composition to cooked noodles, the composition comprising at least water, oil or fat and a polysaccharide thickener, and having a viscosity of from 30 to 2000 mPa·s at 60° C.; and a step of freezing the noodles to which the composition has attached.

Abstract: Provided is a method for producing frozen noodles comprising: a step of attaching a composition comprising xanthan gum and having a viscosity of from 30 to 2000 mPa·s at 60° C. to cooked noodles obtained by cooking fresh noodles produced by a rolling noodle-manufacturing method; and a step of freezing the noodles to which the composition has attached.

Abstract: A process for modifying starches comprises atomizing an aqueous slurry of a non-pregelatinized, granular, high amylose starch into to an internal chamber in a bi-fluid nozzle of a dryer and treating the atomized slurry, in the internal chamber, with medium pressure steam to produce a slurry of partially treated starch granules followed by discharging the slurry into a reactor where it is contacted with superheated steam to produce dry, particulate, cold water-swelling, intact, high amylose starch granules. The cold water-swelling, intact, high amylose starch granules have greater than 15% solubles. At a starch concentration of 1%, in UDMSO (9 volumes DMSO and 1 volume 6M urea) at 25° C., the ratio of apparent viscosity of said cold water-swelling, intact, high amylose starch granules to the apparent viscosity of the parent non-pregelatinized, granular, high amylose starch is lower than 1.00.

Abstract: The present invention relates to frozen aerated products including products manufactured by low-temperature extrusion with superior creaminess. In particular, the invention is concerned with a partially coagulated protein system induced by controlled coagulation of milk protein which imparts outstanding sensory attributes on frozen confectionery including low-temperature extruded frozen products, in particular when containing low fat. A method of producing such frozen aerated confectionery product and the products obtainable from the method are also part of the present invention.

Abstract: A system and a method for the production and provision of CO2 gas are disclosed. A sealable chamber is equipped with heating means and when a CO2 carrier material, such as sodium bicarbonate is placed in it and heated to its decomposition temperature CO2 gas is released. The released gas is conveyed into liquid within a container and when the pressure of the gas in the container raises more and more CO2 gas is dissolved. The heating may be done by conduction mechanism, a microwave heating mechanism or by induction mechanism. The sodium bicarbonate or any other material including carbon dioxide may be disposed in powder, solid, suspension, emulsion, solution or wet powder form. It may be disposed in thin envelope case.

Abstract: The invention provides a sweetener composition comprising a core nano particle in association with a sweetener carbohydrate.

Abstract: Provided herein are compositions with enhanced sweetness or reduced caloric content per weight when compared to the sweetener carbohydrate or sweetener polyol component thereof, and methods for the preparation thereof.

Abstract: Process for the production of a soft pastry bakery product in the form of an oblong bread roll, filled with a chocolate layer in the form of slab is disclosed. The steps include providing a semifinished product in the form of an oblong bread roll, obtained from a flour-based dough, leavened with natural yeast, followed by a baking step and then by a step of injecting a hydro-alcoholic solution so as to obtain a bakery product with a controlled moisture content. Thereafter a longitudinal cut on the bakery product is made so as to obtain a lower portion and an upper portion. A layer of melted chocolate is deposited on the upper surface of the lower portion. Also described is a snack obtained by means of the process.

Abstract: Disclosed herein are compositions and methods related to preservation of plants, including trimmings and portions of leafy green plants A exemplary method for preserving fresh herbs may comprise: a. obtaining fresh trimmings from a plant; b. grinding and/or chopping th fresh trimmings to form processed trimmings; c. packaging the processed trimmings in a container; and d. freezing the processed trimmings; wherein the interior environment of the container contains substantially no oxygen.

Abstract: An improved method refines cellulose to produce a highly refined cellulosic material in combination with a hydrocolloid. The method comprises soaking raw material from primarily parenchymal cell wall structures in an aqueous solution which need not contain an agent to modify the fiber (e.g., a mild alkalizing or alkaline agent and/or solution) using reduced temperatures and pressures, and refining the material with a plate refiner so that a waste water stream is reduced in volume. The mass of fiber is combined with a hydrocolloid and the combined mass is then sheared is dried to produce the Highly Refined Cellulose in an intimately associated or bound structure with the hydrocolloid. The highly refined fiber/hydrocolloid product can also provide excellent thickening properties to a degree unexpected from simple additive effects of the materials. The unique methodology in the combining of the ingredients surprisingly affects the final properties of the combined materials.

Abstract: The present invention provides a method for manufacturing an aerated confectionery shell comprising the steps of: (i) aerating an edible liquid; (ii) depositing the aerated edible liquid into a mould cavity; and (iii) pressing the aerated edible liquid in the mould cavity using a stamp having a surface temperature below the solidification temperature of the edible liquid so as to shape and at least partially solidify the liquid, thereby forming an aerated shell layer; wherein the aerated shell layer has a total gas content of at least 5%, the gas content being calculated using the following formula (1): Gas content of aerated shell layer=(M2?M1)/M2Wherein M1 is the mass of the aerated shell layer having volume V1, and M2 is the mass of a non-aerated shell layer having volume V1 and being formed from the same edible liquid as the aerated shell layer and in the same manner as the aerated shell layer. An aerated confectionery shell obtainable by this method is also provided.

Abstract: Nutritious granular materials of fine particle sizes agglomerated within versatile micropellets are useful for inserting significant amounts of nutritious properties into snack foods. Expandable micropellet-containing formulations provide for introduction of fine particle ingredients such as proteins, minerals and other components or desirable nutrients into food processing lines not typically amenable to the fine particle sizes. Micropellet-containing formulations may consist entirely of micropellets, or may contain an expandable starch such as, for example, corn meal, sheeted doughs, and expanded collet products onto which the micropellets may be basted.

Abstract: A method for preserving and conditioning beef comprises: cleaning and chopping picked fresh beef, dipping in composite essential oil prepared from clove essential oil, cinnamon essential oil and illicium verum essential oil for 30 s and taking out and draining slightly; placing the beef dipped into a modified atmosphere packaging box and fast precooling; inflating gas of mixed proportion into the cooled modified atmosphere packaging box with beef for preservation packaging and then storing at the low temperature of 0-4° C. The shelf life of the beef packaged by the method is up to 24 d. The aerobic bacterial count is not over 6.0 lgcfu/g. A total volatile basic nitrogen TVB-N value is not over 20 mg/100 g and belongs to the range of second freshness. The beef is stable in color, is cherry-red, has the advantage of good preservation effect and is used for cooking preserved cooked beef.

Abstract: A system and a method for the production and provision of CO2 gas are disclosed. A sealable chamber is equipped with heating means and when a CO2 carrier material, such as sodium bicarbonate is placed in it and heated to its decomposition temperature CO2 gas is released. The released gas is conveyed into liquid within a container and when the pressure of the gas in the container raises more and more CO2 gas is dissolved. The heating may be done by conduction mechanism, a microwave heating mechanism or by induction mechanism. The sodium bicarbonate or any other material including carbon dioxide may be disposed in powder, solid, suspension, emulsion, solution or wet powder form. It may be disposed in thin envelope case.

Abstract: The present invention relates to a coated confection in which the wear resistance and shape retention property in high temperature of the center thereof are improved by coating a sufficient amount of shellac on a center with a complex shape. More particularly, the present invention relates to a coated confection composed of a center composed of an oil-based confection and shellac coating the center, wherein a coating rate of shellac is 0.1 to 10%.

Abstract: A frozen condiment is described, chosen among the group consisting of sauces, pastes, pates, creams and pizza toppings, having hygienic and organoleptic features comparable with those of a corresponding fresh condiment, which is in the form of granules having a porous surface, having an average weight of 6.0 g or less and essentially homogeneous in size having a diameter comprised between 1 mm and 20 mm, and apt to determine a rapid and uniform thawing of the deep-frozen condiment; a process for the deep-freezing of a substantially fluid condiment is also described, which involves dividing a substantially fluid condiment into a plurality of drops, which, in a first deep-freezing step, are dosed within a liquid bath at a temperature lower than ?150° C., obtaining a plurality of partially frozen granules having a hard and deep-frozen external surface and a soft not completely deep-frozen core, and a second deep-freezing step at a temperature comprised between ?30° C. and ?90° C.