EP2152101A1

EP2152101A1 - Milk fat-milk protein composition (preferably esterified with palmitic acid) for improving calcium absorption

Info

Publication number: EP2152101A1
Application number: EP08750120A
Authority: EP
Inventors: Günther Sawatzki; Marco Sell
Original assignee: Humana Milchunion EG
Current assignee: Humana Milchunion EG
Priority date: 2007-05-11
Filing date: 2008-05-07
Publication date: 2010-02-17
Also published as: RU2009144036A; DE102007022694A1; UA99614C2; WO2008138821A1; RU2468610C2; CN101686726A; CN105962374A

Abstract

The invention relates to a composition comprising at least one milk fat, preferably esterified with palmitic acid at position sn-2, and optionally at least one milk protein and/or at least one hydrolysis product of a milk protein for the production of an agent for improving calcium absorption.

Description

MILK FAT MILK PROTEIN COMPOSITION (PREFERRED WITH PALMITIC ACID) FOR IMPROVING CALCIUM RECORDING

The invention relates to the use of a milk fat-milk protein composition for improving calcium uptake in the human body.

Supplying the human body with calcium is one of the most important goals of our times, as calcium deficiencies are responsible for some typical lifestyle diseases.

An adequate supply of calcium is necessary throughout life today. If calcium is not supplied to the body in sufficient quantities in early adolescence, there is a shortage of bone supply relatively early on, and so-called osteoporosis later in life. The lack of calcium intake causes a reduction in bone density. However, before it comes to the disease osteoporosis, calcium deficiency leads to numerous disorders of the metabolism. Symptoms include increased excitability of the nerves and muscles, which can lead to muscle cramps. It has long been recognized that milk is one of the most important sources of calcium in the body. Since milk contains a relatively high amount of calcium, regular diets with milk or milk products are recommended in all relevant dietary supplements for calcium intake. So far, however, the fat in the milk is considered as undesirable because, among other things, through targeted information from the industry, which has an interest in the consumption of vegetable fat, the milk fat as a source for the negative-related substances such as cholesterol and saturated fatty acids in Verbin - is brought fertilized. Now, more recent scientific evidence suggests that the role of cholesterol in food may be more sophisticated, and it is now widely accepted that moderate intake of cholesterol with food may well be considered meaningful, as a significant portion of the body's cholesterol is thought to be meaningful self-produced.

For the saturated fatty acids with a chain length of 12 to 16 carbon atoms, negative effects, in particular with regard to the development of blood vessel diseases, are not disputed. For this reason, milk fat (as the source of these fatty acids) is still regarded as a less desirable fat.

In the prior art, little attention was paid to the fact that milk fat naturally contains structures which do not occur in vegetable fats and which are selectively produced by appropriate modifications (transesterifications) only with considerable effort from the vegetable fats: the so-called "structured lipids".

"Structured lipids" are fats and oils in which the structure of the triglycerides is deliberately changed so that the three linked to the glycerol molecule fatty acids according to their position (one calls this as sn-1, sn-2 and sn-3 where sn-1 and sn-3 are virtually identical, since they are on the outside, while sn-2 always denotes the middle position), so that certain fatty acids are mainly transesterified. lent in the sn-2 position. For this there are different procedures and also appropriate products: eg. BETAPOL from Loders Croklaan B. V. Wormerveer, Netherlands. The latter product, obtained from vegetable oils by enzymatic transesterification, has been specifically developed for infant nutrition and has been shown to provide over 30% improved uptake of calcium in infants. The product is characterized by the fact that the palmitic acid (C-16), which normally occurs in vegetable fats, predominantly in the sn l / sn3 position, is present in the sn-2 position by about 45% by transesterification in this product is.

In contrast, vegetable fats and oils are so composed that palmitic acid is currently not found in the favorable sn-2 position (but predominantly in the sn-l / sn-3) (Porsgaard, T. and Hoy, CE , J. Nutr., 130: 1619-1624 (2000); Weber, N. et al., J. Nutr., 133: 435-441 (2003)).

These mechanisms now lead to an (undesired) very adverse situation for the calcium supply in the human diet: because of the "disadvantages" of milk fat described above, most health-conscious people today consume vegetable fat instead of milk fat Calcium is used to preserve the bones (eg as a salt in food supplements), but the calcium is absorbed by the body into the body by only about 60% because of lime soap formation in the intestine However, low-fat dairy products are favored, which leads to the rather unfavorable combination that especially diet-conscious people ingest calcium and vegetable fats (with palmitic acid in the sn / sn-3 position) This combination prevents a significant proportion of the recorded C alciums, can be absorbed by the body. Although the principle of avoiding lime soap formation in the gut has been known in the art of infant feeding for many years (Lucas, A. et al., Arch. Dis., Child 77: F178-F184 (1997); Nelson, CM and Innis SM J. Clin. Nutr. 70: 62-69 (1999); Ostrom KM et al., J. Am. Coli Nutr 21: 564-569 (2002)), this principle has virtually no application in the daily human diet found. It is well described in the literature that calcium prevents the absorption of fats by the formation of lime soaps in the intestine and thus leads to a lower absorption of fat from the intestine (Jacobsen, R. Lorenzen, JK, Toubro, S .; Krog-Mikkelsen L, Astrup, A., Internal J. Obesity 29: 292-301 (2005)).

Furthermore, it is always pointed out in the literature that calcium must always be given together with dairy products if a better calcium intake is to be achieved. The fact that milk fat (from cow's milk and not only from human milk!) Can make a significant contribution to this has hitherto not been specifically investigated and described in the state of the art, nor has it found its way into the practical nutrition of man.

The object of the present invention is therefore to develop a product which can be used to optimize calcium absorption in the human body.

The present invention relates to the use of a composition containing at least one milk fat for the preparation of an agent for improved uptake of calcium.

The invention is characterized in that it is possible by the administration of this composition to significantly increase the absorption of calcium in the human body. As a result, an additional calcium intake can be avoided. The milk fat consists of a physically separated portion of milk fat, such as. the butter, or a milk fat-rich milk fraction, such as the cream. Preferably, this is milk fat, which was separated from cow's milk. Alternatively, according to the invention, however, milk fat of other animal species, such as. Goat, sheep, camel and others. In addition, this milk fat component can be nutritionally improved by appropriate measures: this can be the cows are genetically selected, fed selectively and / or the milk fat of a fractionation (by targeted crystallization) are subjected.

Accordingly, for the milk fat to be used in the present invention, either milk fat already contained in a milk component (e.g., cream, etc.) or derived from the milk by means of physical separation methods (e.g., butter) may be used.

The milk fat is preferably a physically separated milk fraction.

In addition, this does not experience any chemical changes, e.g. Transesterification.

The milk fat can be modified by appropriate natural measures so that the fatty acid spectrum and / or the distribution of the fatty acids in the triglyceride structures receives a physiologically higher quality character. This is the case when there is less total palmitic acid in the triglyceride and / or when the palmitic acid present is in the sn-2 position. Thus, by choosing the cow's stock (Holstein, Jersey, Frisian, etc.), a change in these parameters can already be achieved. Much more effective, however, is a targeted feeding with plants that already contain the desired fatty acids, as in the milk practically many of the dietary fatty acids are directly incorporated. Extensive studies are available (Palmquist, D.L. et al., J. Dairy Sci., 76: 1753-1771 (1993); DePeters et al., J. Dairy Sci., 84: 929-936 (2001); Bell JA et al., J. Dairy Sci 89: 733-748 (2006); Allred S.L. et al., J. Dairy Sci. 89: 234-248 (2006); Nielsen, TS et al. Reprod. Nutr. Dev. 46: 699-712 (2006)). Conveniently, for example, the use of oilseed rape, soybean and hybrid sunflower as feeds to change the fatty acid spectrum so that the nutritionally unfavorable saturated fatty acids (C 12 to C 16) are reduced and z. B. the conjugated linoleic acids are significantly increased. The palmitic acid (C 16), which in absolute terms is present to a lesser extent in the milk fat, is incorporated in the milk fat mainly in the sn-2 position. There are also studies on this (DePeter's EJ et al., J. Dairy Sci., 84: 929-936 (2001), Porsgaard, T. and Hoy, CE, J. Nutr., 130: 1619-1624 (2000). ).

An entirely different technique is milk fat fractionation by targeted crystallization (Lai, H-C et al., J. Dairy Sci., 78: 794-803 (1995)). Through this technique, it is possible to produce a liquid milk fat fraction, which is characterized by a significantly lower palmitic acid content. Even such a fraction is nutritionally beneficial for humans.

The aforementioned changes in milk fat eliminate all the disadvantages that prevent the widespread use of milk fat in healthy foods and take advantage of the "structured lipid properties" of milk for health-promoting products with improved calcium intake.

The milk fat of the composition to be used according to the invention preferably contains 10 to 50% of esterified palmitic acid (weight percent based on the milk fat). Preferably, there are 18 to 35

Wt .-%, most preferably 22 to 28 wt .-% palmintinic acid in the triglyceride used in the invention. This palmintinic acid is found to be 20 to 75% in the sn-2 position of glycerol (based on the total amount of palminic acid present in the triglyceride). Preferably, 35 to 50%, more preferably 40 to 45% of the palmitic acid is in the sn-2 position. This ensures that in the intestine (where primarily the fatty acids are eliminated from the sn / sn-3 position) the palmitic acid on glycerol esterified (sn-2) remains and thus not set free, but as a monoglyceride is recorded. Because free palmitic acid forms with calcium in the intestine the so-called lime soaps that are not absorbed by the body and cause a significant proportion (over 30%) of calcium is not absorbed from the diet in the body. This principle of avoiding the formation of lime soaps is modeled on human breast milk, in which palmitic acid is bound up to 80% in the sn-2 position, and this fatty structure is known to significantly contribute to the calcium excretion of breast milk is well received.

This principle is also realized in the milk of other animals. For cow's milk, about 35-55% of palmitic acid is also included in the sn-2 position. Regrettably, this quality of cow's milk has until now (as opposed to human milk) been almost ignored by science. Animal milk (cow's milk is also the most important for European-dominated populations) contains significant amounts of calcium, which must be made available to the young as effectively as possible, and nature has succeeded in doing so by deliberately introducing palmitic acid into the sn-2. Position of the milk fat to produce a naturally produced structured lipid that helps to absorb the calcium from the milk well.

Surprisingly, it has also been found that the composition according to the invention results in a significantly better uptake of calcium in the body (more than 20% more) if, in addition to the milk fat, milk proteins (and / or their subfractions) are simultaneously administered compared with the case that only calcium, calcium plus only milk protein or calcium plus only fat as food source are offered. It has also proven to be much cheaper for the acceptance of In the case of milk, milk products are combined with milk proteins.

In a preferred embodiment, therefore, a composition according to the invention containing - at least one milk fat and

at least one milk protein and / or at least one hydrolysis product of a milk protein used to produce an agent for improved uptake of calcium.

The milk protein will be obtained by separating the proteins of the milk. As simple fractions (by isoelectric precipitation), for example, caseins, glycomacropetides and / or whey proteins can be used as milk proteins according to the invention.

With respect to the milk protein component, besides the isolated casein fraction and / or the isolated whey protein fraction, too

Subfractions of these milk proteins or the corresponding products can be used after hydrolysis of the proteins.

Caseins are naturally occurring proteins and are part of the milk proteins, which consist of about 20% whey protein and about 80% casein. The caseins are mainly bound to the calcium of the milk. These are able to bind large amounts of calcium. As a result, the calcium is evenly distributed in the liquid and does not settle on the ground in the form of a sediment. However, the caseins have the disadvantage that they precipitate at acidic pH, so that bound casein calcium is unsuitable for acidic products.

Several scientific research groups have investigated the binding of calcium to casein in recent years, discovering the principle of calcium-binding peptides. It turned out that certain sections of the caseins calcium especially bind well and that these sections have protein-linked phosphate groups. When hydrolyzing caseins, caseinophosphopeptides (CPP) are formed, which bind calcium particularly well. Chemically, CPP is a group of peptides derived from the caseins or fragments of the caseins and containing at least one phosphate group. By using caseinophosphopeptides, it is now possible to achieve largely clear calcium solutions. Such caseinophosphopeptides are commercially available today (eg CPP DMV).

Glycomacropeptide (GMP) is released from the caseins during the production of cheese by the action of the rennet and is present in the so-called whey fraction after cheese production. Chemically, glycomacropeptide, as the hydrophilic part of κ-casein, is a fragment of κ-casein with amino acid sequence 106 to 169. It is therefore also referred to as caseinoglycomacropeptide or caseinomacropeptide. Glycomacropeptide occurs in 1 1 different genetic variants, with A and B being the most common genetic variants. In addition, glycomacropeptides may also contain glycosidically linked carbohydrate chains. Typically, about 30-50% of GMP contains glycosylated carbohydrate chains. Glycomacropeptide does not contain an aromatic amino acid and, in addition, a phosphate group through which calcium can be bound.

The casein of milk forms stable structures with calcium (the so-called casein micelles). From the casein, the caseinophosphopeptides (CPP) and the glycomacropeptide (GMP) can be released by hydrolytic processes.

Thus, for example, the components CPP and / or GMP according to the patent application no. DE 10 2005 033 630.2, the complete disclosure of which is hereby introduced by reference to this application, can be used for the use according to the invention. For these, even in extensive investigations, a better calcium Availability as well as calcium-binding properties are demonstrated. In extensive tests, it was also checked which protein amounts are most favorable for the particular milk protein fraction. These findings then lead to the preferred amounts of protein and the corresponding ratios to the milk fat. Thereafter, the following proteins are preferred (each being the recommended daily amount for an adult): GMP (5 to 10 g) and / or CPP (2 to 10 g) and / or caseins (20 to 40 g) and / or GMP-rich ( Sweet) whey proteins (40 to 60 g)

Interestingly, it has now also been found that, alternatively or additionally, whey proteins and their hydrolysis products are also suitable for calcium binding. However, the bond is not as effective as the aforementioned caseins and their hydrolysis products. However, at a sufficiently high ratio, the whey proteins and their hydrolysis products can be used as effectively for calcium binding; only larger quantities are needed than from the caseins. For many products, however, the amount of protein is less critical and thus, depending on the desired application, alternatively the caseins (and / or their hydrolysis products) or the whey proteins (and / or their hydrolysis products) to be used in larger quantities can be used.

For example, whey proteins and their hydrolysates, as are commercially available, can be used as milk proteins. In this case, however, is usually about 2 to 4 times the amount required compared to the caseins needed to achieve a good calcium binding. Not all whey proteins and their hydrolysates are equally well suited. It has been found in practice that the so-called acidic fractions (whose isoelectric point is below pH 6.0) are best suited.

The weight ratio between the milk fat and the milk protein in the composition according to the invention should be between 0.0625 and 5, preferably between 0.5 and 4, and most preferably between 1 and 3. It depends on the type of protein and the ready-to-eat product.

The proportions of milk fat and optionally milk protein in the inventive composition for improving the

Calcium intake may well be in areas known from normal dairy products that have not been produced by recombination of individual milk components. However, the invention always relates to compositions consisting of recombined products which are produced from fractions of milk obtained in different physical quantities.

Recombinant milk is defined as a liquid milk which is obtained from the addition of water to skimmed milk powder and separate addition of milk fat to the extent that the desired fat content is set (see Handbook of Dairy and Dairy Technology, Verlag Th & Co. KG, 45894 Gelsenkirchen, 2003, p.412). Similarly, recombinant dairy products (e.g., ice cream) are also prepared from the previously separated ingredients.

In principle, it is even more advantageous to provide a combination of milk fat, milk protein and calcium together in one preparation, since this is the safest way to choose an optimal relation of the components that can ensure optimal calcium intake. However, the calcium can also be supplied in the form of appropriate dietary supplements.

In a further preferred embodiment, the composition according to the invention is therefore taken up together with calcium in the form of at least one food and / or pharmaceutically acceptable salt. In each case, for each 1000 mg of calcium (this corresponds to the recommended daily amount for an adult) about 60 to about 400 g of the milk fat according to the invention Milk protein composition are included. Preferably, about 80 to about 150 g and most preferably about 100 g of the composition according to the invention are added to 1000 mg of calcium. The at least one calcium salt may either be present in the same product, ie in the same dosage form as the composition according to the invention, or it may be taken up as soon as possible from the composition of the invention from milk fat and possibly milk protein.

In principle, the calcium source and its daily amount should be in a certain ratio for the daily intake of the milk fat-milk protein composition. The calcium source may be any of the food grade and / or pharmaceutically approved calcium-containing salts. For example, without limitation of generality, calcium carbonate, calcium chloride, calcium citrates, calcium gluconate, calcium glycerophosphate, calcium lactate, calcium orthophosphate, calcium oxide and / or calcium hydroxide may be mentioned here.

In one embodiment according to the invention, the addition of minerals and / or trace elements to the composition according to the invention is conceivable. Without restriction of generality are here as possible minerals or trace elements to call: magnesium, copper, iron, selenium, fluorine, iodine, manganese. In order to avoid problems of deposition of calcium in the blood vessels, the composition according to the invention may for example additionally be supplemented with magnesium. All magnesium salts permitted under food law can be added. As a daily amount, a maximum of 250 mg of magnesium is recommended (for an adult).

It is also preferable to add vitamins to the composition used according to the invention, particularly preferably vitamin D, which is jointly responsible for the absorption of calcium in the small intestine. When For example, the B vitamins (B l, B6, B 12), vitamin E, A or K can be used as possible further vitamins.

The addition of soluble fibers, such as, for example, oligofructose, galactooligosaccharides and / or phytosterols, is a preferred embodiment of the inventive use of the composition.

To stabilize the composition of the invention, the usual emulsifiers, e.g. Lecithins, mono- or diglycerides or other emulsifiers approved in the manufacture of food.

The composition of the invention can be used both as an additive in food or as well as food supplements or as a pharmaceutical preparation.

In principle, the composition according to the invention can be used for the production of compositions or products in liquid, solid, powdered, compacted or any other state of aggregation. The aggregate state of the product also results in the application form. The oral application is preferred. Equally possible is also the intragastric (directly into the stomach), the nasogastric (via a probe through the nose to the stomach), the parenteral (directly into the body bypassing the gastrointestinal tract) or intravenous (directly into a blood vein) application ,

So products can be made, which are used as normal food or in the dietetic food area. However, it is also possible to produce products which belong to the field of pharmaceutical products or self-medication.

The composition of the invention is versatile. Without limitation of generality, the use as milk-like products in the form of emulsions (including infant formula) is particularly suitable. yoghurt preparation, candy, powder, tablet, compacted form, bar, jelly or emulsion.

Typical application examples are the use in dairy products, baby foods, quark and yoghurt foods, whey drinks, deserts, ice cream, fruit bars, tablets, capsules, sprays or single-dose powder packaging.

The complete disclosure of all applications, patents and publications cited above and below are incorporated by reference into this application.

Even without further statements, it is assumed that a person skilled in the art can use the above description to the greatest extent. The preferred embodiments and examples are therefore to be considered as merely illustrative, in no way limiting as in any way limiting disclosure.

Example 1 :

The composition intended for use according to the invention may contain the ingredients according to the following Table 1 (for example, the recommended daily dose for the adult human is given).

Table 1: possible composition of the composition intended for use according to the invention

*) This daily amount should be taken in an amount of 1000 mg calcium.

Example 2:

From the following formulation components an adult beverage intended for use according to the invention is prepared:

208.5 g skimmed milk 81 g sweet whey powder

37 g of cream

3, 45 g CPP

This product already contains enough calcium due to its raw materials, so no additional calcium compound needs to be added. The consumption is 330ml per serving and should be a maximum of 800ml per day.

Example 3:

From the following formulation components an infant formula intended for use according to the invention is prepared (the ingredients are given per 100 ml of finished infant formula):

70.5 g water (demineralised) 21 g skimmed milk

5, 2 g whey powder (demineralised)

1, 8 g of vegetable oils

2.5 g lactose

1.7 g butter 170 mg GMP (glycomacropeptide)

90 mg CPP (Caseinophosphopeptides) Further Ingredients: Emulsifiers, minerals and vitamins in accordance with the legal requirements of the EC guidelines for infant formulas and the dietary regulation

The amount consumed depends on the age of the baby and is about 1 liter per day.

Claims

claims

1 . Use of a composition containing at least one milk fat for the preparation of an agent for improving the absorption of calcium.

2. Use of a composition according to claim 1, characterized in that the milk fat is a physically separated and chemically unaltered milk content.

3. Use of a composition according to claim 1 or 2, character- ized in that the milk fat 10 to 50 wt -.%, Preferably to 1 8 to 35 wt -.%, Particularly preferably from 22 to 28 wt -%, esterified Contains palmitic acid.

4. Use of a composition according to claim 3, characterized in that the palmitic acid to 20 to 75%, preferably 35 to 50%, particularly preferably 40 to 45%, in the sn-2

Position of glycerol is esterified.

5. Use of a composition according to any one of claims 1 to 4 containing

- at least one milk fat and

at least one milk protein and / or at least one hydrolysis product of a milk protein.

6. Use of the composition according to claim 5, characterized in that the milk protein is a physically separated milk fraction.

Use of the composition according to claim 5 or 6, characterized in that the weight ratio of milk fat to milk protein is between 0.0625 and 5, preferably between 0.5 and 4, very preferably between 1 and 3.

8. Use of the composition according to one of claims 1 to

7, characterized in that this in combination with at least one food and pharmaceutically approved

Calcium salt is used, wherein to dose 1000 mg of calcium between 60 and 400 g of the composition.

9. Use of the composition according to one of claims 1 to

8, characterized in that the at least one calcium salt is selected from the group calcium carbonate, calcium chloride,

Calcium citrate, calcium gluconate, calcium glycerophosphate, calcium lactate, calcium orthophosphate, calcium oxide and calcium hydroxide.

10. Use of the composition according to one of claims 1 to

9, characterized in that minerals, trace elements and / or vitamins and emulsifiers are added.

1 1. Use of the composition according to any one of claims 1 to 10, characterized in that soluble fiber is added.

12. Use of the composition according to claim 1 1, characterized in that oligofructose, galactooligosaccharides and / or

Phytosterols are added.

13. Use of the composition according to one of claims 1 to 12, characterized in that emulsifiers are added.

14. Use of the composition according to any one of claims 1 to 13 as an additive in foods, in nutritional supplements or in pharmaceutical preparations.