Low-fat frozen confectionery composition

Field of the invention

The present invention relates to frozen confectionery coatings which have a low amount of fat. In particular, it relates to the use of water-in-oil emulsion as low-fat coating for frozen confections.

Background of the invention

Edible coatings are commonly used in frozen confectionery products, as they provide a texture or taste contrast and improve the organoleptic properties of the product. The most common coatings used in the frozen dessert industry are chocolate-based coatings. These usually consist of milk, sugar, and cocoa in fat.

As a viable alternative to fat-based compositions, water- in-oil emulsions have been developed. Water-in-oil emulsions are known to be used in filling compositions, such as disclosed in EP 0 547 658 Bl, EP 0 397 247 Bl, EP 0 440 203 Al or as spreads or fat substitutes such as described in EP 0 430 329 Bl and EP 0 441 495 A2 for instance .

Water-in-oil emulsions which may serve as a coating in frozen confectionery products have also been described, for instance, in EP 0 986 959 Al. Therein, a coating composition having soft texture, good adhesion on ice cream, reduced fat content, good flavour release and good storage and heat-shock resistance is provided by a water- in-oil emulsion.

US 5,556,659 also discloses a water-in-oil emulsion which has the same texture and flavour properties as required

for conventional fat-based coatings, but which contains less fat.

Fat continuous emulsions are also mentioned in WO 97/02754 for use as a coating layer for frozen or chilled confectionery products.

US 3,223,532 describes emulsions for food use which may be used for enrobing ice cream bars. The viscosity of the emulsion should be between 18 and 35 degrees MacMichael for enrobing ice creams, while a viscosity of 35-150 degrees MacMichael is useful as icings, candy coatings, sauces and the like.

A method for manufacturing water-containing chocolates and chocolate compositions by using a water-in-oil emulsion is described in US 6,159,526. The choice of emulsifiers is the critical factor in achieving the desired products.

EP 0 958 747 Bl relates to a process for preparing chocolate formulations which is cost effective and results in reduced calorie formulations. This is provided by a water-in-oil emulsion in which sugar syrup is dispersed in the fat phase.

Object of the invention

There thus remains a need to develop an improved frozen dessert coating which has similar mechanical properties to a regular ice-cream coating, with a reduced calorie content .

Summary of the invention

Accordingly, this is achieved by the features of the independent claims . The dependent claims further develop the central idea of the invention.

Thus, in a first aspect, the invention provides for a water-in-oil emulsion composition comprising at least 45% of an aqueous phase, less than 35% of an oil phase, wherein the aqueous phase comprises solids dissolved therein in an amount up to 15% and wherein food-grade particles are suspended in the oil phase in an amount up to 20%.

In a second aspect of the invention, a water-in-oil emulsion composition comprising at least 55% of an aqueous phase, less than 35% of an oil phase and wherein the aqueous phase comprises solids dissolved therein in an amount less than 10%, is provided.

A third aspect of the invention relates to the use of a water-in-oil emulsion composition according to any of claims 1 to 13 for the production of a brittle coating for frozen confectionery.

The invention further provides for a brittle coating for frozen confectionery comprising at least 45% of an aqueous phase, less than 35% of an oil phase, wherein the aqueous phase comprises solids dissolved therein in an amount up to 15%, and wherein food-grade particles are suspended in the oil phase in an amount up to 20%.

Similarly, a brittle coating for frozen confectionery comprising at least 55% of an aqueous phase, less than 35% of an oil phase and wherein the aqueous phase comprises solids dissolved therein in an amount less than 10%, falls under another aspect of the invention.

Thus, the invention also relates to a coated frozen dessert comprising a coating according to any of claims 15 to 17.

Finally, a method for producing a water-in-oil emulsion for preparing a brittle frozen confectionery coating comprising the steps of: a. Preparing an aqueous phase by mixing water with up to 15% of water-soluble solids and heating the mixture b. Preparing a fat phase by mixing fat and emulsifiers and heating the mixture c. Emulsifying the mixture of said aqueous phase and said fat phase under heat d. coating a frozen confectionery with the emulsion obtained in step c, and a composition for use as a brittle frozen confectionery coating obtainable by said method constitute further aspects of the invention.

Figures

The present invention is further described hereinafter with reference to some of its embodiments shown in the accompanying drawings in which:

Figure 1 is a flow chart illustrating the process resulting in the coating composition of the invention,

Figure 2 shows the influence of sucrose on the brittleness of the coating and compares the brittleness of known references and the brittleness of coatings of the present invention.

Detailed description of the invention

In the present disclosure, the terms "fat" and "oil" are used interchangeably and are taken to have the same meaning .

Referring to fig. 1, the water-in-oil emulsion compositions of the present invention are obtained by mixing an aqueous phase into a fat phase, and emulsifying the mixture such that the fat phase is continuous.

According to an aspect of the present invention, the water-in-oil emulsion comprises at least 45% of an aqueous phase, less than 35% of an oil phase, wherein the aqueous phase comprises solids dissolved therein in an amount up to 15% and wherein food-grade particles are suspended in the oil phase in an amount up to 20%. In further embodiments, the amount of solids present in the aqueous phase may be less than 12%, less than 10%, less than 6%, even less than 3%.

According to another aspect of the present invention, the water-in-oil emulsion composition comprises at least 55% of an aqueous phase, less than 35% of an oil phase and wherein the aqueous phase comprises solids dissolved therein in an amount less than 10%. In further embodiments, the amount of solids present in the aqueous phase may be less than 6%, even less than 3%.

The solids dissolved in the aqueous phase are selected from any food-grade, water-soluble agents, such as sugars, milk powders, gelling agents etc. and mixtures thereof.

Typical sugars used in the aqueous phase are sucrose, fructose, sugar replacers such as polyols (e.g. maltitol, lactitol, isomalt, erythritol, sorbitol, mannitol, xylitol) , bulking agents like polydextrose or other

sweeteners like tagatose, high-intensity sweeteners like saccharin, aspartame, acesulfame-K, cyclamate, neohesperidin, rhaumathin, sucralose, alitame, neotame or any possible combinations thereof. Preferably, the sugar used is sucralose.

Gelling agents present in the aqueous phase may be selected from carrageenans, pectins, gellan, gelatines, guar gum, acacia gum, sodium alginate, xanthan gum, proteins or mixtures thereof. Preferably, the gelling agent used is carrageenan.

In the emulsions of the invention, the fat phase comprises a mixture of fat and emulsifier. The fat may be any fat with a melting point below 45°C, preferably below 35°C. Preferably, the fat is selected from cocoa butter, cocoa butter equivalent, cocoa butter substitute or cocoa butter replacer .

The emulsifiers present in the fat phase are selected from sugar esters, polyglycerol fatty acid esters, polyglycerol polyricinoleate (PGPR) , polysorbates (polyoxyethylene sorbitan esters) , monoglycerides and any possible combination thereof.

The amount of emulsifiers present in the fat phase is between 0.5 and 3%. Preferably it is between 1.5 and 2%.

As shown in Figure 1, the food-grade particles may be added to the emulsion after formation of said emulsion. The food-grade particles may be added directly as such or may be dispersed in fat prior to addition.

According to an embodiment, the water-in-oil emulsion composition may comprise food-grade particles suspended in the oil phase in an amount of up to 20%.

The food-grade particles may be any edible particle selected from cocoa, milk powder, starch, calcium carbonate, fruit powder, silicon dioxide etc. or mixtures thereof .

Preferably, the food-grade particles are cocoa particles added in the form of cocoa powder or cocoa liquor. This will give the coating a chocolate aspect and taste. The cocoa powder or the cocoa liquor used may be natural or alkalinised.

Suspending the food-grade particles in the fat phase, rather than in the aqueous phase, presents the advantage that the aqueous phase maintains a low solid content which, upon freezing, confers the desired mechanical properties to the emulsion composition, as disclosed further herein.

The water-in-oil emulsions of the present invention may comprise at least 45%, preferably at least 50%, more preferably from 55-95% of a water phase and from 5-35% of a fat phase. In an even more preferred embodiment, they comprise from 55-85% of a water phase and from 15-35% of a fat phase. Even more preferably, the water-in-oil emulsions comprise from 55-75% of a water phase and from 15-30% of a fat phase. Most preferably, they comprise from 55-70% of a water phase and from 20-30% of a fat phase.

Typically, the emulsion compositions are used directly as coating for frozen confectionery. The coating may be achieved by dipping or other methods known in the art.

Alternatively, the emulsion may be stored at freezing temperatures (-20 ⁰ C) and reheated for the coating process when need be .

In any case, the water phase of the emulsions comprises solids dissolved therein in an amount up to 15%, or, according to another embodiment, less than 10%. This presents the advantage that, when frozen, the emulsions are hard and brittle, with firmness and brittleness comparable to traditional fat-based ice cream coatings.

Without wishing to be bound by theory, it is thought that the low concentration of dissolved solids in the aqueous phase allows the water droplets of the water phase to become solid at freezing temperatures (e.g. -20 ⁰ C). The higher the solids concentration in the aqueous phase, the less crystallised the water droplets are at freezing temperatures (e.g. -20 ⁰ C).

Thus, the water-in-oil emulsions of the present invention may be used in the production of brittle coatings for frozen confectionery. The coating of frozen confectionery with the emulsion compositions of the present invention may be carried out by any techniques known to the skilled person.

By frozen confectionery is meant any of ice cream, sorbet, mellorine, frozen yogurt, frozen mousse, frozen custard, sherbet etc.

The invention therefore provides a brittle coating for frozen confectionery comprising at least 45% of an aqueous phase, less than 35% of an oil phase, wherein the aqueous phase comprises solids dissolved therein in an amount up to 15% and wherein food-grade particles are suspended in

the oil phase of said emulsion in an amount up to 20%. In further embodiments, the amount of solids present in the aqueous phase may be less than 12%, less than 10%, less than 6%, even less than 3%.

Further, a brittle coating for frozen confectionery comprising at least 55% of an aqueous phase, less than 35% of an oil phase and wherein the aqueous phase comprises solids dissolved therein in an amount less than 10% falls under a further aspect of the invention. In further embodiments, the amount of solids present in the aqueous phase may be less than 6%, even less than 3%.

The influence of solids content of the water phase on the brittleness of the coatings are illustrated in Figure 2. As can be seen in Figure 2, the more sucrose is present in the aqueous phase, the less brittle it is.

Brittleness can be measured by how much mass can be applied to a solid before it breaks with very little deformation. Brittleness is therefore proportional to the breaking force. The higher the force required to break the sample, the higher the brittleness.

The coatings of the invention are brittle since they will suffer very little deformation before breaking. By "very little deformation" is meant that, on average, a distance of 0.5-3mm is covered before a sample of 4 mm thickness breaks .

The brittleness of the coatings of the present invention is between 2500 g and 6000 g. Preferably, the coatings have a brittleness between 4000 and 6000 g.

A high brittleness, as exhibited by the coatings of the present invention, is advantageous. Indeed, this provides texture characteristics which render the product more appealing, by having a high snap. The coatings of the present invention offer the advantage that they contain less fat than traditional fat-based coatings. Indeed a reduction of between 40-70% fat, and a caloric reduction of more than 50% compared to regular chocolate coating is achievable. The coatings of the invention are also characterised in that they demonstrate similar mechanical properties (snap, melting behaviour etc.) compared to regular chocolate coating, as well as improved brittleness.

A coated frozen confectionery comprising a coating according to the invention may be any type of frozen dessert such as ice-cream, sorbet, mellorine, frozen yogurt, frozen mousse, frozen custard, sherbet etc.

The method for producing a water-in-oil emulsion for preparing a brittle frozen confectionery coating according to the present invention comprises in a first step preparing an aqueous phase by mixing water with water- soluble solids up to 15% and heating the mixture. Preferably, the solids are present in an amount less than 12%. In another embodiment, the solids are present in an amount less than 10%. The water-soluble solids are selected from sugars, milk powders, gelling agents etc. or mixtures thereof. These are selected from the groups described above.

Typically, the aqueous phase ingredients are mixed with water and stirred at 25°C for 10 minutes at a shear rate of 200 rpm. The mixture is then heated to between 80 ⁰ C and 95°C, preferably to 86°C over 20 minutes at a shear rate

of 200 rpm, and stirred at that temperature and at that shear rate for 30 minutes. The mixture is then stored in an oven at 90 ⁰ C during the preparation of the fat phase.

In a second step, the fat phase is prepared by mixing the fat in a pre-heated crystalliser (e.g. 80 ⁰ C) with the emulsifiers. The fat may be any fat with a melting point below 45°C, preferably less than 35°C. The emulsifiers or combination of emulsifiers may be selected from the group described above.

Emulsification of the mixture of the aqueous phase and of the fat phase is then carried out under heat. Preferably the emulsification is carried out at a temperature between 70 ⁰ C and 80°C, more preferably 75°C for up to 10 minutes at 250 rpm.

The emulsion is then cooled, with a gradual decrease of the shear rate.

If food-grade particles are added, these are gently stirred into the emulsion, preferably by using a spatula, at between 35 and 45°C, preferably at a temperature of about 40 ⁰ C. The emulsion may then be used directly as a coating for or as inclusions in frozen confectionery.

The compositions obtainable by the method described above fall under another aspect of the invention. These may be used as a brittle frozen confectionery coating and present the advantage of being low in fat, while retaining the desirable characteristics of traditional high-fat coatings. These even exhibit increased brittleness for an optimum snap.

The present invention is further illustrated by means of non-limiting examples.

Examples

Example 1: Water-in-oil emulsion recipe 1

The coating was made according to the process described previously.

The present coating recipe has 30% less fat and a reduction of up to 50% in the calories compared to traditional fat-based coatings.

Example 2: Water-in-oil emulsion recipe 2

Preparation of the emulsion: Fat with emulsifier are mixed together at 40 ⁰ C. Sugar is dissolved into water and heated at 40 ⁰ C. Emulsification is then done at 40°C with the

blade turning at 250 rpm. Emulsion is kept under these conditions for 20 min. Then food-grade particles are added at 40°C under gentle mixing (60 rpm) . The resulting mass is ready to be coated around an ice-cream at a temperature between 35 to 40 ⁰ C.

Example 3: Water-in-oil emulsion recipe 3

This emulsion is not inside the frame of this patent for the composition. It was made with the same process as the one described in the main part of the specification.

Example 4: Brittleness measurements Materials

Texture Analyzer Stable Micro System TA-HD, equipped with a 50 kg load cell,

Geometry Stable Micro System Three Point Bend Rig (HDP/3 PB) composed of a rig base plate with two supporting blades and a compression unit, - A refrigerated box Heraus Vδtsch HT 4004, regulated at -15°C.

Plastic weighting tray, external dimensions 9*9 cm,

Dry ice (CO2) in pellets.

Method

Samples preparation

Directly after the fabrication, while the sample is still liquid, 20 grams exactly are poured in a plastic weighting tray such that the sample covers entirely the bottom of the tray in a homogenous way.

The sample is put in the freezer at -25°C ensuring that it is kept absolutely horizontal in order to keep the same thickness over the whole surface and kept there for minimum 3 days.

One hour before carrying out the measurements, the samples are put in a refrigerated box regulated at -15°C.

Parameters of the apparatus

Program : Texture Expert Exceed (Version 2.61) Settings : Measure force in compression

Return to start

Parameters: Pre-test speed 2.00 mm/s Test speed 3.00 mm/s

Post-test speed 10.00 mm/s

Distance 5.0 mm

Load cell 50 kg Trigger: Type: Auto Force: 15 g

Acquisition Rate: 400 pps Units: Force: grams

Distance: millimeters Break detect: Off

Installation of the geometry

Screw the rig base plate on the heavy duty platform of the texture analyzer and install on it the part with the two supporting blades. Hold tight the two screws ahead and on

the right side in order that it is fixed onto the base plate .

Screw the upper blade on the load cell. Lower the upper blade between the two supporting blades and adjust the upper blade so they are parallels and their front and bottom face are at the same level. Jam the rig base plate on the heavy duty platform in this position. Go back up the upper blade and move apart the two supporting blades of 3 cm each to obtain a total space between this two blades of 6 cm.

Install around the base plate a sagex lid with a hole cut in its centre in order to be able to cool down the lower part with dry ice. Finally the upper and lower blades should be distant from around 1 to 1.5 cm to let enough place to put the sample on. If this distance is too big, the analysis will take too many time and the sample will reheat too much.

Measurement The sample is taken out of the refrigerated box and turned out of its plastic tray and put on the texture analyzer in the middle of the two supporting blades cooled with dry ice. The measurement is started immediately.

The following parameters for assessing the brittleness are measured:

Maximal strength at which the sample breaks. Distance covered by the upper blade between the first contact with the sample (beginning of the measurement) and the moment of the break.

Measurements carried out on standard commercial coating samples (shown in Fig. 2) show a range of brittleness between 2300 and 400Og. The brittleness of the coatings

according to the invention is between 2300 and 610Og (Fig.

2) .

Example 5: Brittleness measurements Sample of example 1 was compared to sample of example 3, using measurement of brittleness described in example 4.

Sample at 25% sugar had a low brittleness. Example 1 sample has a maximal strength of 480Og while sample of example 3 has a maximal strength of 60Og. The first one is brittle while the second one is not.