EP1978818A2

EP1978818A2 - Method for obtaining a vegetable plant protein fraction, in particular for producing vegetable ice cream

Info

Publication number: EP1978818A2
Application number: EP07702345A
Authority: EP
Inventors: Peter Eisner; Klaus Müller; Claudia Pickardt; Andreas Malberg
Original assignee: Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Current assignee: Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Priority date: 2006-01-17
Filing date: 2007-01-17
Publication date: 2008-10-15
Also published as: NO336729B1; DE102006002249B4; WO2007082507A3; KR20080083318A; US20090011107A1; DE102006002249A1; CN101374418A; NO20082738L; WO2007082507A2; US8257772B2; CA2634350A1

Abstract

The invention relates to a method for obtaining a vegetable protein fraction, in particular for producing vegetable ice cream, wherein vegetable parts are added to water or to an aqueous solution in order to detach and/or disperse vegetable proteins from the vegetable parts. According to the invention, one or several vegetable protein fractions are separated from the obtained aqueous mixture according to a separation method. According to said method, one or several substances having lipophilic or amphiphilic bordering surfaces are added to the mixture in order to separate one or several vegetable protein fractions. The detached and/or dispersed proteins having lipophilic or amphiphilic groups in the mixture are attached to said substances. Said substances comprising the attached proteins are separated from the mixture. Due to said invention, a vegetable protein fraction having particularly good emulsifying characteristics is obtained, said protein fraction being advantageous as an emulsifier in the production of vegetable ice cream.

Description

Process for obtaining a vegetable

Protein fraction, in particular for the production of vegetable ice cream

Technical application

The present invention relates to a process for obtaining a vegetable protein fraction, in particular for producing vegetable ice cream, in which plant parts are mixed with water or a water-containing solvent in order to dissolve and / or disperse vegetable proteins from the plant parts, and in which one or more vegetable protein fractions are separated from the water-containing mixture thus obtained by a separation process.

State of the art

Ice cream and other creamy ice cream variants contain animal or vegetable fats and

Milk protein and / or milk sugar as well as partially egg protein. Milk and egg proteins fulfill in the ice cream in addition to a possibly desirable taste in particular functions of texturing.

The manufacture of ice cream is essentially performed by weighing the ingredients, pre-mixing, homogenizing, pasteurizing, cooling (+4 ⁰ C), ripening, freezing in the ice freezing Let anläge (Freezen), packaging and storage.

Ice cream such as mousse is known (at least 50% milk content and one liter Milk at least 270 g whole egg or 90 g egg yolks), cream ice cream (at least 18% milk fat from whipped cream), ice cream (at least 10% milk fat), simple ice cream (at least 3% milk fat), milk ice (milk content at least 70%) and ice cream with vegetable fat (at least 3% vegetable fat). Common to all these ice creams is that they contain milk protein and lactose in addition to animal or vegetable fats.

Many people have an intolerance to dairy or other animal ingredients, so they should avoid consuming milk and cream ice cream. For this group of consumers there is so far no alternative to milk-containing ice cream with comparable indulgence value.

For the enjoyment of eating ice cream, the creaminess is of particular importance. The creaminess is determined by the fat content and its integration into the total matrix. In addition, the viscosity of the melt determines the creaminess of the ice. A higher viscosity melt is perceived as creamier in the mouth than a low viscosity melt. In addition, the melting behavior determines the organoleptic sensation during the consumption of ice. An ice cream with a slow, uniform melting behavior is perceived as more pleasant than an ice cream with a heterogeneous and z.T. very fast absorption behavior. The breakdown behavior is influenced inter alia by the impact, i. the volume-related

Gas content (air or nitrogen) determined in the ice. Most creamy types of ice cream have a gas content of over 40 to 50 vol .-%. Such a service So far, it can only be achieved with conventional ingredients.

Other important quality parameters are the mouthfeel and the sensation of cold when consumed. With insufficient emulsion action and water binding of the matrix, larger ice crystals form, giving rise to a rough mouthfeel and an aqueous impression. The sensation of cold is determined by the availability of the fat.

Creamy types of ice cream are obtainable in the prior art only by larger amounts of fat, to achieve the Kremigkeitsgefühls the fat content should be greater than 15 wt .-%, better than 20% by weight.

In hitherto known ice cream preparations with vegetable protein content, especially based on soya, attempts have been made to replace the animal emulsifiers with vegetable proteins. Dried plant proteins were used here, which were obtained in conventional aqueous or aqueous-alcoholic extraction processes and after drying as a powder.

Plants used to obtain proteins for use in ice cream contain between 10% and 50% by weight protein in the dry matter, depending on the feedstock. The protein content in plants does not consist of a defined substance.

Rather, the total protein includes a variety of different protein fractions. Each protein fraction is from several hundred to more than - A -

1000 amino acids constructed with different amino acid sequences. The secondary, tertiary and quaternary structure of the proteins gives each molecule specific properties.

Thus, individual protein fractions have particularly good properties as emulsifier or gelling agent, as water binders, foaming agents or texture improvers for foods. Depending on the production process, all these different protein fractions are included

Protein mix, e.g. is obtained by drying a protein solution.

The extraction of vegetable protein products is so far almost exclusively from soybeans. The beans are peeled, further comminuted by flocculation or grinding and the protein extracted by adding water from the soy flakes or the flour. The aqueous extract can be removed by mechanical separation techniques from the undissolved solids, e.g. Fibers are separated and routed out of the extraction process. The soy protein product can then be precipitated from the extract, enriched with membrane processes and / or dried.

With the aid of the described technology, the proteins are obtained as a protein product although they consist of different protein fractions with different properties. A separation of the protein fractions according to emulsifier specific, functional properties is not carried out according to the prior art. Rather, fractionation is after material sum parameters such as precipitability, solubility or molecular size.

So it is possible to fold protein molecules from extracts by lowering the pH, by adding certain salts or by heating and to convert it into a water-insoluble state. The protein molecules accumulate in the form of flakes. These can be separated mechanically from the proteins still in solution.

Another method for the separation of protein-containing suspensions and solutions are filtration or membrane processes. So can be separated by simple filtration suspended from dissolved proteins. It is also possible to use molecules of different sizes, e.g. by ultrafiltration into a fraction of larger and to separate into a fraction of smaller molecules. The specific properties of the fractions obtained can only be adapted to a limited extent to the requirements of the food industry. In many cases, the larger and precipitable molecular fractions have better properties than emulsifiers, while the smaller or non-precipitable fraction has better properties than foaming agents.

In WO 2006/076889 A2 a process for the preparation of a vegetable protein ingredient for an ice cream is described. Lupine seeds are prepared and first crushed. Thereafter, in one or more protein extraction steps, a portion of one in the comminuted lupine seeds - S -

contained lupine protein dissolved or at least dispersed in an aqueous phase. To obtain the protein ingredient, the lupine protein is separated by precipitation from the aqueous phase.

The object of the present invention is to provide a method for obtaining a vegetable protein fraction with particularly good emulsifying properties, which can be used particularly advantageous as an emulsifier in the production of vegetable ice cream.

Presentation of the invention

The object is achieved by the method according to claim 1. Advantageous embodiments of the method can be taken from the subclaims and the following description.

In the proposed method, plant parts, in particular peeled or unshelled plant seeds, are mixed with water or a water-containing solvent in order to dissolve and / or disperse vegetable proteins from the plant parts.

Subsequently, one or more substances with lipophilic or amphiphilic interfaces are introduced into the mixture obtained in this way or brought into contact with the mixture, in which in the mixture dissolved and / or dispersed proteins with lipophilic or amphiphilic groups, hereinafter also as target proteins designated, attach. The one or more substances with the attached proteins are separated from the mixture by a separation process to obtain the desired vegetable protein fraction (s).

In the method according to the invention, the fractionation of the mixture of different dissolved and / or dispersed protein fractions present in water or a water-containing solution thus takes place by introducing a lipophilic or amphiphilic phase boundary into the water or into the mixture. Proteins with a high affinity for lipophilic substances attach themselves to the lipophilic interfaces and can thus be separated from other dissolved or dispersed substances.

The process thus enables a selective recovery of surface-active emulsifier protein, which attaches to the lipophilic or amphiphilic interfaces due to its lipophilic or amphiphilic properties. This protein fraction obtained by the process is of great advantage in enriched form, above all for the production of vegetable ice cream, to which it is preferably added in a proportion of between 0.5 and 6% by weight. The selective fractionation of the proteins into a particularly efficient emulsifier protein fraction made possible by the present process makes it possible to produce ice cream with particularly positive properties and appealing organoleptic properties.

In the method, a substance is used, due to the lipophilic structure of the interface advantageous to attach lipophilic groups of proteins. For example, it is possible to use lipophilic surfaces of polymers or other adsorber materials which, for example, are brought into contact with the protein mixture as a fixed bed or as dispersed particles.

Surprisingly, through this

Fractionation protein fractions are obtained whose emulsifying capacity (binding capacity of oil in water) per gram of protein by a factor of 5 compared to the original protein mixture is increased. The amount of additional emulsifier required for different applications can thus be reduced to a minimum.

In a particularly advantageous embodiment of the method, oil droplets or fat particles are used as substance with lipophilic interface or surface. The proteins with pronounced lipophilic properties attach to this surface, whereas proteins with less pronounced lipophilic properties do not or only to a small extent attach to the phase interface. Other substances with low lipophilic intrinsic properties which are present in the mixture, e.g. Saccharides, salts or fibers do not or only to a small extent attach to the lipophilic surfaces.

The proposed method very efficiently succeeds in separating proteins with a defined ratio of lipophilic and hydrophilic properties from other dissolved or dispersed proteins. By adapting the surface properties Shafts, for example by the selection of different polymers with different polar and non-polar groups on the surface, succeeds in selecting the proteins. Since proteins also always have hydrophilic regions in addition to the lipophilic group, the process according to the invention allows fractionation of the proteins according to their ratio of lipophilic groups to hydrophilic groups, depending on the lipophilic characteristics of the interface. Thus, the properties of the respective protein obtained can be specifically optimized for use in different applications, for example for the production of vegetable ice cream.

When the target proteins from the mixture have attached to the surface, the remaining aqueous mixture is separated from the lipophilic substances with the attached proteins. In the case of dispersed lipophilic particles or drops, the aqueous phase can be mechanically separated. Besides filtration, centrifugal processes are suitable for this purpose. A prerequisite for a good separation is that the lipophilic particles or droplets have a different density than the surrounding aqueous mixture.

Since lipophilic adsorbents often have a comparable or somewhat lower density than water, floating of the lipophilic substances together with the attached proteins can be achieved. To increase the density difference, the aqueous phase can be enriched for this with soluble salts or with sugar, which increases the specific gravity of the liquid phase. result. In a centrifugal field then the lighter lipophilic substances can be separated together with the attached proteins as a floating fraction of the liquid and discharged, for example by means of decanters.

In a particularly advantageous embodiment of the method according to the invention, a vegetable oil or fat is added to the aqueous protein mixture as the lipophilic substance or phase. Depending on the particle size of the oil / fat phase, which can be set defined by technical means, a more or less large phase interface is available. At this phase boundary, the lipophilic target proteins are deposited and can be separated from the aqueous phase by centrifugation. Thus, it is possible to selectively separate particularly good emulsifier proteins from an aqueous protein mixture. It does not matter at which point in the plant the proteins were originally located. Proteins with a defined ratio of lipophilic and hydrophilic groups attach to the oil phase boundary.

The vegetable oil used is preferably the oil which is to be used in the food later as an oil phase in the emulsion. For example, if it is desired to prepare an ice cream with rapeseed oil as an ingredient, rapeseed oil droplets, if appropriate also together with further constituents of the rapeseed, can be used as lipophilic phase boundary surface in the aqueous protein mixture for the fractionation. The by fractionation obtained Rapsδl protein mixture can then be used directly as an ingredient for the vegetable ice cream.

The same applies to ice cream, in which other vegetable oils are used. Possibly. may be added to the oil before use as a lipophilic substance certain substances that are desirable in the subsequent preparation. Thus, flavors, colors, vitamins, phytochemicals or other bioactive substances may be added. In ice cream, these substances are then present in a defined concentration.

In a further advantageous embodiment of the method according to the invention, the phase boundary is produced directly with the oil from the protein-containing plant. For example, soybean oil from soybean can be used to fractionate soya proteins. For this purpose, it is necessary to produce by means of agitators, high-speed mixing units, such as Turrax ^® , or by means of ultrasound oil droplets, on whose surface the proteins can attach. With smaller droplet size, more surface is available for attaching the proteins. Preferably, oil droplets with a droplet size <100 .mu.m, preferably <10 .mu.m, are produced here with the mixing or comminution device.

However, the greater amount of intermingling fluid between the smaller oil droplets also removes more dissolved proteins that do not have the specific properties of interfacially attached proteins. In this case it is it is helpful to separate the graft fluid in one or more washing stages from the emulsifier proteins adhering to the oil droplets. A person skilled in the art is able, depending on the desired protein purity, to set the required droplet size by selecting the stirring or ultrasound conditions and to use the required number of washing steps, which gives the best results for the desired protein purity.

Particularly good emulsifier proteins are obtained when using oil-containing plants such as rapeseed, palm kernels, flax or sunflower. However, it is also possible to use other oily plants such as e.g. Soy or Lupine to use for the said application. The

Selection will be made primarily because of the desired organoleptic properties of the ice cream.

In an advantageous embodiment of the method according to the invention, the oil serves as an absorber surface and is not separated from the protein after protein fractionation. The moist oil-protein mixture is then incorporated particularly advantageously directly into the ice cream. Thus, the ice is enriched with vegetable oil and there is a particularly stable ice cream emulsion in which even after prolonged storage in the frozen state no organoleptically perceptible oxidative changes occur. In addition, the proteins remain in their dissolved, native structure.

The complete separation of the water, eg by means of drying, would change the proteins and thus impair the ice quality. If the phase interface is not produced with vegetable oil but with other adsorbers, such as polymers, the proteins must subsequently be separated from the adsorbers. For this purpose, water, emulsions or lipophilic liquids such as hexane, acetone, alcohols or other solvents are suitable. From these liquids, the protein may optionally be recovered in pure form by the liquid is separated from the protein again. In the case of solvents, evaporation can take place.

A pure protein can also be obtained when the protein is separated from the aqueous mixture along with oil droplets. After drying the water, the resulting oil-protein mixture can be mixed with a lipophilic solvent, e.g. Hexane or acetone or others, whereby the oil phase is removed and the protein is recovered in pure form. This pure emulsifier protein can be used in addition to in

Ice cream is also used in other foods.

This also applies to the mixture of protein and vegetable oil obtained by fractionation, which apart from the planned use in ice cream can also be used for other applications as an emulsifier protein. Possible applications for such proteins or protein-oil mixtures are e.g. Creams, mayonnaises, soups, sauces, drinks, bread, bakery products,

Delicatessen products, salads and spreads.

After removal of the lipophilic protein fraction hydrophilic protein fractions remain in solution in the aqueous mixture. These may be concentrated by isoelectric precipitation or filtration techniques and recovered as a protein isolate characterized in particular by high water solubility, foam-forming properties, gelation and viscosity-forming properties. This hydrophilic protein product can be advantageously used in the production of beverages, foamed foods such as chocolate kiss, water and milk-based desserts or baked goods.

Depending on the requirements of the hydrophilic protein fraction, it is also possible to carry out various pretreatment steps with more or less lipophilic adsorbers in the aqueous protein mixture. In this case, further fractions can be separated off and the properties of the proteins discharged with the adsorbers and the proteins remaining in the mixture can be further specialized. By combining different adsorbers, it is possible to obtain distinctively hydrophilic proteins in a highly pure form as the end product.

embodiment

Example 1: Creamy vegetable ice with reduced fat content

100 g of ground, peeled sunflower seeds are mixed with 400 g of a sugar solution and the pH of the solution is adjusted to 7.5 with sodium hydroxide solution. The mixture is stirred for 4 minutes with a dispersing tool. As a result, the proteins contained in the sunflower seeds are dissolved in the water. The oil contained in the cores is exposed in this process in addition to the aqueous phase as a lipophilic further phase and is thus available as Adsorberoberflache available. The oil droplets are mainly deposited on the proteins with particularly good emulsifier properties.

Thereafter, the insoluble constituents, predominantly fibers and shell residues, are separated from the protein-oil-water dispersion through a 63 μm sieve. The emulsion phase is obtained after centrifuging the filtrate by ablating the upper layer. The heavier liquid phase after centrifugation contains, in contrast to the emulsion phase, the less well-emulsifying, but particularly readily water-soluble proteins and can be further worked up to obtain them. So these proteins z. B. be obtained by ultrafiltration.

The solid filter residue is washed once more with 200 g of sugar solution and so won a further share of emulsifier proteins together with the remaining oil and other soluble constituents. The combined emulsion phase (82 g) containing the emulsifier proteins together with the sunflower oil is mixed with 400 g of water to separate impurities such as soluble non-emulsifier proteins. The mixture is then centrifuged. The emulsifier proteins remain bound to the oil and can thus be separated as a floating phase. This emulsion phase is again washed with water in the same manner to separate unwanted soluble constituents. There are obtained 82 g of an emulsion containing about 1.5% emulsifier proteins and 33% fat. Finally, the desired water or oil content of the emulsion is adjusted by the addition of water.

The emulsion prepared is used according to the recipe given in Table 1 for the production of ice cream. In addition to the stabilizer protein, the emulsion already has a fat content, so that an additional addition of vegetable fat is eliminated. It is a particularly creamy pure vegetable ice cream is achieved, but has a very low fat content of only 8%. The fat is emulsified so well that even with a long storage time of 6 months, no large ice crystals are formed in the ice. Thus, the ice is also very stable and stays creamy for a long time. Table 1: Formulation for the production of vegetable ice cream

Example 2: Vegetable ice cream with ice-cream character

The emulsion of Example 1 is incorporated in exchange for cream in a cream-ice cream recipe. Due to the good emulsifier effect of the protein can be dispensed with the addition of artificial emulsifiers. The stability of the emulsion is also very good in this "ice cream", good storage stability is given.

Claims

claims

A process for obtaining a vegetable protein fraction, in particular for the production of vegetable ice cream, in which plant parts are mixed with water or a water-containing solvent in order to dissolve and / or disperse vegetable proteins from the plant parts, and in which one or more vegetable protein fractions are separated from the water-containing mixture obtained in this way by a separation process, wherein one or more substances with lipophilic or amphiphilic to separate the one or more vegetable protein fractions

Interfaces are introduced into the mixture, in which dissolved in the mixture and / or dispersed proteins with lipophilic or amphiphilic groups attach, and wherein the one or more substances are separated with the attached proteins of the mixture.

2. The method according to claim 1, characterized in that the one or more substances are dispersed in the mixture.

3. The method according to claim 2, characterized that the one or more substances are polymers.

4. The method according to claim 1 or 2, characterized in that the one or more substances are fat particles.

5. The method according to claim 1 or 2, characterized in that the one or more substances are oil droplets, which are introduced into the mixture.

6. The method according to claim 1 or 2, characterized in that as one or more substances vegetable oil and / or vegetable fat is introduced into the mixture.

7. The method according to claim 1 or 2, characterized in that as one or more substances vegetable oil and / or vegetable fat is introduced into the mixture, which is needed for a later ice cream preparation using the one or more separated vegetable protein fractions.

8. The method according to claim 7, characterized in that the vegetable oil and / or vegetable fat

Add additives that are needed for the subsequent ice cream preparation.

9. The method according to any one of claims 6 to 8, characterized in that the vegetable oil is extracted together with the vegetable protein from the plant parts and distributed with a mixing or crushing device as small oil droplets in the mixture.

10. The method according to claim 9, characterized in that oil droplets are generated with a droplet size <100 microns with the mixing or crushing device.

11. The method according to claim 9, characterized in that oil droplets are generated with a droplet size <10 microns with the mixing or crushing device.

12. The method according to any one of claims 5, 9 to 11, characterized in that the oil droplets are subjected to the deposited proteins after separation from the mixture one or more washing steps to wash off gusset liquid.

13. The method according to any one of claims 1 to 12, characterized in that the plant parts are subjected to a flocculation prior to the addition of water or aqueous solvent.

14. The method according to any one of claims 1 to 13, characterized in that parts of plants are mixed from a full-fat seed with the water or water-containing solvent.

15. The method according to any one of claims 1 to 14, characterized in that the one or more vegetable protein fractions are used in a proportion of 0.5 to 6 wt.% For the production of ice cream.

16. The method according to any one of claims 1 to 15, characterized in that the one or more substances are separated with the attached proteins by a mechanical separation process of the mixture.

17. The method according to claim 16, characterized in that the one or more substances are separated with the attached proteins as floating fraction.

18. The method according to claim 16 or 17, characterized in that the mixture is a specific gravity of the

Mixture-enhancing substance is added to the density difference between the mixture and the one or more substances with the attached

Increase proteins.

19. The method according to any one of claims 16 to 18, characterized in that the one or more substances are separated with the attached proteins by centrifugation.

20. The method according to any one of claims 1 to 19, characterized in that the one or more substances are used with the attached proteins after the separation without further separation step directly to the ice cream preparation.

21. The method according to any one of claims 1 to 19, characterized in that the one or more substances are separated with the attached proteins by one or more further separation steps of the deposited proteins.

22. The method according to claim 21, characterized in that the separation of the deposited proteins by use of one or more liquids.

23. The method according to any one of claims 1 to 22, characterized in that after the separation of the one or more substances with the attached proteins of the mixture in the mixture remaining proteins by isoelectric precipitation or filtration be concentrated and as a protein isolate.

24. The method according to any one of claims 1 to 23, characterized in that protein fractions of different protein properties and / or hydrophilic proteins are obtained in highly pure form as protein isolate by several separation steps, each carried out with substances of different lipophilic or amphiphilic interface.