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Title:
HUMAN MILK FAT REPLACERS FROM INTERESTERIFIED BLENDS OF TRIGLYCERIDES
Document Type and Number:
WIPO Patent Application WO/1994/026855
Kind Code:
A1
Abstract:
The invention concerns triglyceride compositions as obtainable by 1,3-specific enzymic interesterification of: 1) a triglyceride mix, comprising > 30 % P and/or St, from which > 35 % is bonded at 2, while the remaining fatty acid residues are mainly unsaturated; 2) a triglyceride mix, wherein > 10 % of 1,3-positions are accompanied by C8-C14 fatty acids.

Inventors:
CAIN FREDERICK WILLIAM (NL)
QUINLAN PAUL THOMAS (GB)
Application Number:
PCT/EP1994/001306
Publication Date:
November 24, 1994
Filing Date:
April 22, 1994
Export Citation:
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Assignee:
LODERS CROKLAAN BV (NL)
CAIN FREDERICK WILLIAM (NL)
QUINLAN PAUL THOMAS (GB)
International Classes:
A23C11/04; A23D9/00; A23D9/007; C11C3/10; C12P7/64; (IPC1-7): C11C3/10; A23D9/00; A23C11/04
Domestic Patent References:
WO1992019237A11992-11-12
Foreign References:
EP0209327A21987-01-21
EP0305901A21989-03-08
US5089177A1992-02-18
EP0496456A11992-07-29
Other References:
PATENT ABSTRACTS OF JAPAN vol. 16, no. 289 (C - 956) 26 June 1992 (1992-06-26)
J. M. MUDERHWA ET AL.: "Interestérification enzymatique régiosélective 1-3 en milieu fondu et en réacteur continu : valorisation de l'huile de palme", OLEAGINEUX, vol. 44, no. 1, 1989, FR, pages 35 - 43
DATABASE WPI Week 9215, Derwent World Patents Index; AN 92-120578
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Claims:
CLAIMS
1. Triglyceride composition, as obtainable by 1,3 specific, enzymic interesterification of: a triglyceride mixture, comprising at least 30 wt% of palmitic and/or stearic acid residues, from which at least 35 wt%, preferably at least 40 wt% of the total palmitate and/or stearic present are bonded at the 2position, while the remaining fatty acid residues are mainly unsaturated, in particular oleic and linoleic, and a triglyceride mixture, in which at least 10 wt% of the 1,3positions are occupied by medium chain fatty acids (C8C14) .
2. Triglyceride composition, according to claim 1, as obtainable by the enzymic conversion of: a triglyceride mixture high in SSU and/or USU type triglycerides (U= unsaturated fatty acid C18+; S= saturated fatty acid C16 and/or C18) . and 2) a triglyceride that can act as a source for saturated medium chain fatty acid moieties in 1, 3specific, enzymic conversions.
3. Triglyceride composition, according to claims 1 or 2, wherein the mixture high in SSU and/or USUtype triglycerides is a mixture, comprising more than 40 wt%, preferably more than 60 wt% triglycerides of the SSU and/or USU type, while SSU/USU is preferably PPU/UPU (U= oleic or linoleic; P= palmitic) .
4. Triglyceride composition according to claim 1, wherein the triglyceride mixture, comprising at least 30 wt% of palmitic acid/or stearic residues mentioned under 1) in claim 1 is lard or butterfat.
5. Triglyceride composition, according to claims 1 or 2, wherein the triglyceride mixture, providing the saturated medium chain fatty acid moieties, comprises more than 20 wt%, preferably more than 40 wt% of these medium chain fatty acid moieties.
6. Triglyceride composition, according to claim 1, wherein the interesterification is performed on a mixture that also contains other fats, such as sunflower oil and/or high oleic sunflower oil and/or canola oil and/or soybean oil and/or butterfat.
7. Triglyceride composition, according to claim 6, wherein the composition is obtained by 1,3specific, enzymic interesterification of a mixture, comprising () 3080 wt% of a triglyceride mixture with an (USU + SSU) content of 4070 wt% () 1050 wt% of a fat, providing the saturated medium chain fatty acid moieties, which fat contains 1590 wt% saturated medium chain fatty acid residues, () 025 wt% of a liquid, vegetable oil high in unsaturated fatty acid residues, such as sunflower oil, high oleic sunflower or soybean oil () 035 wt% of butterfat.
8. Triglyceride composition according to claims 1 or 2, wherein the triglycerides are obtainable from enzymic, 1,3specific interesterification of the triglycerides 1) and 2) of claims 1 or 2, wherein the weight ratio of the triglycerides 1) and 2) before the interesterification ranges from 80:20 20:80.
9. Interesterified triglyceride mixture, comprising at least 10 wt%, preferably at least 15 wt% palmitic acid residues, wherein the palmitic acid residues are distributed in the triglycerides in such a way that at least 35 wt%, preferably at least 40 wt% of the palmitic residues are bonded at the 2position, and comprising at least 10 wt% of saturated medium chain fatty acid residues (C8C12) , such that the sum of the triglycerides with carbon number (42+44+46) is at least 10 wt%, preferably at least 15 wt%.
10. Interesterified triglyceride mixture, according to claim 9, wherein the following fatty acid residues are present in the amounts mentioned: (C 8:0 + C10:0 + C 12 0> 540 wt% 16:0 1040 wt% 18:0 215 wt% 18:1 2050 wt% 18:2 3020 wt% while more than 35 wt%, preferably more than 40% of the C16:0 is bonded at the 2position.
11. Interesterified triglyceride mixture, according to claims 9 or 10, wherein the following carbon number distribution occurs: 42 28 wt% 44 2.510 wt=i 46 615 wt% 48 1118 wt% 50 1020 wt% 52 1940 wt% 54 720 wt% .
12. Blend of triglycerides, wherein the blend comprises at least 20 wt% of the triglyceride compositions of claims 111 in addition to another fat.
13. Blends of triglycerides according to claim 12, wherein the blend has a carbon number distribution according to: 42 510 wt% 44 615 wt% 46 1016 wt% 48 815 wt% 50 715 wt% 52 922 wt% 54 1830 wt% .
14. Infant food composition, comprising 0.52 parts by weight of a protein, 37 parts by weight of a carbohydrate and 23 parts by weight of a fat composition, wherein the fat composition comprises 20100 wt% of the triglyceride composition as claimed in claims 113.
15. Process for the production of a human milk fat replacer composition, wherein a triglyceride mixture (I) , comprising at least 30 wt% of palmitic and/or stearic acid residues, from which at least 35 wt% are bonded at the 2position, while the remaining fatty acid residues are mainly unsaturated is converted in the presence of a 1.3specific enzyme with a triglyceride mixture (II) , in which at least 10 wt% of the 1, 3positions are occupied by medium chain fatty acids (C8C14) , while the weight ratio of mixtures (I) and (II) ranges from 20:8080:20.
Description:
Human milk fat replacers from interesterified blends of triglycerides

From our European patent EP 209 327 it is known that triglycerides, wherein more than 50% of the fatty acid residues in the 2-position are saturated, preferably palmitic, while simultaneously more than 43 wt% of the saturated C 12 to C 18 fatty acids present are bonded to the 2- position, are excellent human milk fat replacers that display a better absorption than triglycerides with a lower content of 2-palmitic. A similar finding is the subject of our European patent application EP 496 456, wherein, however, the advantage of the presence of linolenic acid mainly bonded in the 1, 3-positions is disclosed. In both above references also human milk fat compositions are mentioned, comprising blends of the human milk fat replacers and oils, high in lauric (C 12 ) fatty acid residues.

Although the blends according to above references are suitable human milk compositions with a reasonable resemblence to human milk, its deviation from human milk fat was still such that we studied ways to come to triglyceride compositions that are even closer to human milk than the known compositions. In these triglyceride compositions the content of palmitic bonded to the 2-position should remain relatively high, while the content of medium chain fatty acids (i.e. C 8 -C 14 ) mainly bonded at the 1, 3-positions should exceed a minimum amount, so that the triglyceride composition in total displays a composition, in terms of fatty acid content, distribution of the fatty acids over the three positions of the triglycerides and carbon number distribution that is closer to that of human milk than any synthetic prior art triglyceride composition.

It should be noted here that blends of randomized palm oil, lauric oil, an oil high in oleic acid and an oil, containing linoleic acid are known from EP 376 628 and GB 2 142 340.

Although the total fatty acid composition of these blends resembles human milk fat closely the distribution of the fatty acid residues over the three positions of the triglycerides is quite different from human milk fat. As a consequence thereof the carbon number distribution in the triglyceride composition is also not in line with that of human milk fat.

In order to achieve an improvement in above compositions it was proposed in EP 488 800 to subject the above blends to a co-randomization. Although such a co-randomization might inherently result in a triglyceride composition closer to that of the human milk fat per se, it also results in a composition, wherein palmitic, originally present in the 2- position is spread over the whole molecule, while laurics, originally bonded in the 1,3-positions, will also be bonded in the 2-position in the randomized mixture. Therefore, the digestibility and absorbability of the triglyceride mixture is adversely affected by the randomization treatment.

It is further pointed out that directed triglycerides with improved absorption and digestibility are known from EP 265 699. However, in this reference the directed triglycerides are mainly of the type 1, 3-dipolyunsaturated-2-(C 8 -C 14 ) saturated. These triglycerides therefore are quite different from human milk fat.

In WO 92/19237 it is disclosed that the hydrolysis rate of fats can be increased by incorporation of medium chain fatty acids in the 1, 3-positions of triglycerides. However, nothing is disclosed about the application of this principle in the production of human milk fat replacers.

We have found new fat compositions that have a triglyceride structure that is closer to human milk fat than known hithertho, and that combine the advantages of an improved absorption rate (because of its 2-palmitic content) with an

increased hydrolysis rate for the residues in the Im¬ positions (because of presence of medium chain fatty acids in 1,3), resulting in a further improved absorption rate of the triglycerides.

Although triglyceride compositions in general can be described using compound parameters, we found that it is very difficult to come to a description for our compositions that is both generic and sufficient, this being due to the fact that different fatty acid residues with different chain length can be present in our mixtures.

However, our new triglyceride compositions can fully be described as "products by process". So, our invention concerns a triglyceride composition, as obtainable by 1,3- specific, enzymic interesterification of:

1) a triglyceride mixture, comprising at least 30 wt% of palmitic and/or stearic acid residues, from which at least 35 wt%, preferably at least 40 wt% of the total palmitate and/or stearic present are bonded at the 2-position, while the remaining fatty acid residues are mainly unsaturated, in particular oleic and linoleic, and

2) a triglyceride mixture, in which at least 10 wt% of the 1,3-positions are occupied by medium chain fatty acids (C 8 -C 14 ) .

In a more strict sense our inventions concerns a triglyceride composition, as obtainable by the enzymic conversion of:

1) a triglyceride mixture high in SSU and/or USU- type triglycerides (U= unsaturated fatty acid C 18+ ; S= saturated fatty acid C 16 and/or C 18 ) . and 2) a triglyceride that can act as a source for saturated medium chain fatty acid moieties in

1, 3-specific, enzymic conversions.

Preferred compositions are obtainable from mixtures high in in SSU and/or USU-type triglycerides, comprising more than 40 wt%, preferably more than 60 wt% triglycerides of the SSU and/or USU type, while SSU/USU is preferably PPU/UPU (U= oleic or linoleic; P= palmitic) .

Other suitable fats that can be used as such fat compositions are lard or butterfat.

The triglyceride mixture, providing the saturated medium chain fatty acid moieties preferably comprises more than 20 wt%, preferably more than 40 wt% of these medium chain fatty acid moieties. Examples of those fats are palm kernel fat, coconut oil, high lauric rapeseed oil and fractions thereof.

Although the triglycerides according to the invention can be obtained from the conversion of above two triglycerides components, it is preferred that the interesterification is performed on a mixture that also contains other fats, such as sunflower oil and/or high oleic sunflower oil and/or canola oil and/or soybean oil and/or butterfat.

Therefore, in the most preferred embodiment according to the invention the triglyceride compositions are obtained by 1,3- specific, enzymic interesterification of a mixture, comprising: (-) 30-80 wt% of a triglyceride mixture with an (USU + SSU) -content of 40-70 wt%

(-) 10-50 wt% of a fat, providing the saturated medium chain fatty acid moieties, which fat contains 15-90 wt% saturated medium chain fatty acid residues, (-) 0-25 wt% of a liquid, vegetable oil high in unsaturated fatty acid residues, such as sunflower oil, high oleic sunflower or soybean oil (-) 0-35 wt% of butterfat.

The weight ratio of the basic triglycerides that can be applied, ranges from 80:20-20:80.

In the case the fatty acid moiety bonded at the 2-position is palmitic and the medium chain fatty acid residues that are introduced are chosen from C 8 to C 12 saturated fatty acids the resulting interesterified triglyceride mixture can be defined as comprising at least 10 wt%, preferably at least 15 wt% palmitic acid residues, wherein the palmitic acid residues are distributed in the triglycerides in such a way that at least 35 wt%, preferably at least 40 wt% of the palmitic residues are bonded at the 2-position, and comprising at least 10 wt% of saturated medium chain fatty acid residues (C 8 -C 12 ) > such that the sum of the triglycerides with carbon number (42+44+46) is at least 10 wtt preferably at least 15 wti

These triglyceride mixtures display the following fatty acid composition

(C 8:0 + C10:0 + C 12:0 ) 5-40 wt%

C 16 : θ 10-40 Wt% C 18 : 0 2-15 wt% C 18 : l 20-50 wt%

'18:2 3-20 wt%

while the following carbon number distribution occurs in these compositions:

-42 2-8 Wt%

-46 6-15 wt%

-48 11-18 wt%

-50 10-20 wt%

-52 19-40 wt%

-54 7-20 wt%

Therefore, our new triglyceride compositions have a carbon number distribution that is closer to that of human milk fat than a physical blend of the components from which the interesterified mixture is made. This is demonstrated in tables I and II, wherein the carbon number distribution is

given for human milk fat: for a physical blend of BP/CN/SF/HOSF in a ratio 75/15/7/3; for a physical blend of BP/BF/CN/SB in a ratio 50/25/15/10 and for the products obtained after a 1,3-specific enyzmic interesterification of these blends.

- BP meaning a triglyceride high in 2-palmitate according to EP 209 327

- CN meaning coconut oil - SF meaning sunflower oil

- HOSF meaning high oleic sunflower oil

- BF meaning butter fat

- SB meaning soybean oil

TABLE I

Carbon no. human milk 75/15/7/3 BP/CN/SF/HOSF physical mix Inter, data

32 0 - 0.2 0.95

34 0 - 0.4 1.60

36 0 - 0.9 2.20 0.2

38 0 - 2.0 2.10 0.4

40 0.2 - 3.2 1.50 1.2

42 0.9 - 5.6 1.20 3.1

44 2.7 - 9.2 0.80 4.4

46 5.5 - 13.5 0.40 9.6

48 11.4- 17.6 1.10 13.0

50 16.8- 22.8 10.5 16.8

52 23.9- 38.0 58.5 34.3

54 7.4 - 16.7 17.5 15.6

56 0.9 - 3.6 0.70 0.7

58 0.0 - 1.4 0.30 0.2

60 0.0 - 0.3

TABLE I I

Carbon no. human milk 50/25/15/10 BP/BF/CN/SB physical mix Inter, data

32 0 - 0.2 0.80 0.2

34 0 - 0.4 1.70 0.4

36 0 - 0.9 3.20 0.8

38 0 - 2.0 3.70 2.9

40 0.2 - 3.2 3.20 3.8

42 0.9 - 5.6 2.40 5.1

44 2.7 - 9.2 1.80 6.7

46 5.5 - 13.5 1.80 10.7

48 11.4- 17.6 3.40 14.3

50 16.8- 22.8 10.0 15.4

52 23.9- 38.0 48.8 22.6

54 7.4 - 16.7 16.1 12.2

56 0.9 - 3.6 0.50

58 0.0 - 1.4

Blends of triglycerides that comprise at least 20 wt% of the triglyceride compositions according to the invention in addition to at least one other fat are also part of the invention. These blends can be applied in addition to or instead of the triglyceride composition per se.

Although the carbon number distribution in these blends is further away from that of human milk fat than the carbon number distribution of our interesterified blends, the product performance of these blends is still acceptable. In fact, the carbon number distribution in these blends is typically as follows:

-42 5-10 Wt%

-44 6-15 Wt%

-46 10-16 wt%

-48 8-15 wt%

-50 7-15 Wt%

-52 9-22 Wt%

-54 18-30 wt%

The blends can be applied per se, however, it is also possible to fractionate the blends in order to remove at least part of the trisaturated triglycerides, in particular when these are present in too large amounts.

The other fat can be any fat that suitably can be applied in infant food compositions and are in fact known from the references cited above. However, we prefer to use liquid oils, such as sunflower oil, soybean oil, etc.

Also infant food compositions, comprising 0.5-2 parts by weight of a protein, 3-7 parts by weight of a carbohydrate and 2-3 parts by weight of a fat composition, wherein the fat composition comprises 20-100 wt% of the triglyceride composition according to the invention are part of the invention.

The invention further concerns a process for the production of a human milk fat replacer composition, wherein a triglyceride mixture (I) , comprising at least 30 wt% of palmitic and/or stearic acid residues, from which at least 35 wt% are bonded at the 2-position, while the remaining fatty acid residues are mainly unsaturated is converted in the presence of a 1.3-specific enzyme with a triglyceride mixture (II) , in which at least 10 wt% of the 1, 3-positions are occupied by saturated medium chain fatty acids (C 8 -C 14 ) , while the weight ratio of mixtures (I) and (II) ranges from 20:80-80:20.

EXAMPLES

EXAMPLE I

Fats I and II, described in table III were mixed in a weight ratio of 57:43 parts by weight and interestified using Rhizomucor miehei immobilised on duolite (SP-392, Novo Industries) . Reaction conditions were: 1 part catalyst to 20 parts oil; incubated at 70°C for 24h. Fat I was a palm stearine previously reacted with a source of unsaturated fatty acids using the above lipase and containing -53% of total 16:0 in the sn-2 position. Fat II was palm kernel oil, containing ~ 71% C 8 -C 14 saturates in sn 1,3 position. After enzymic interesterificatin of fats I and II, the product, fat III comprised « 48% of 16:0 in the sn-2 position. The carbon number distribution of the physical blend (fats I and II) and the enzymically interesterified blend (fat III) are shown in table IV. In the physical blend the sum of carbon numbers 42-46 was 9.2% after enzymic interesterification this increased to 42.25 o •

EXAMPLE II

Lard (6 parts) and palm kernel oil (2.5 parts) were blended together and enzymically interesterified according to the method described in example 1. The carbon number distribution of the physical (Fat IV) and interesterified blends (fat V) are given table V. The interesterified product was mixed with 1.5 parts soyabean oil to produce a fat blend for use in infant formula.

The sum of carbon numbers 42-46 in fat IV and V was 6.95 and 30.1 wt%, respectively. The distribution of 16:0 in the triglyceride mixture before and after interesterification was similar, and close to that found in breast milk.

EXAMPLE III

Butterfat (3 parts) and palm kernel oil (1 part) were physically blended and 1,3 interesterified according to example I. The carbon number distribution of the physical (fat VI) and interesterified (fat VII) blends are given in table VI.

The sum of carbon numbers 42-46 before and after interesterification was 19.4% and 32.8 wt% respectively.

EXAMPLE IV

3 parts by weight high oleic sunflower oil (HOSF) , 7 parts sunflower, 15 parts coconut and 75 parts Betapol (comprising 30% 16:0 of which 75% was esterified to the sn-2 position) were mixed together and enzymically interesterified as described in Example I. The fatty acid composition of the blend is given in table VII and the carbon number distribution of the blend before (fat IX) and after interesterification (fat X) is given in table VIII. The carbon number distribution after 1,3 interesterification was substantially within the range reported for breast milk (table I) , whereas the physical blend lies substantially outside the range. The 1,3 interesterified blend also contained approx 70% of the total 16:0 esterified at the sn- 2 position. The sum of carbon numbers 42-46 before and after interesterification was 2.4 and 17.1 respectively.

EXAMPLE V

15 parts (by weight) coconut oil, 10 parts soyabean oil, 25 parts butter fat and 50 parts Betapol were physically mixed and subjected to 1,3 interesterification as described in Example I. The fatty acid composition of the blend is given in Table IX and the carbon number distribution of the blend

before (fat XI) and after interesterification (fat XII) is given in table X.

Comparison with table I illustrates that 1,3 interesterification produces a carbon number distribution sifnificantly closer to that of breast milk. The interesterified blend contained 24% 16:0 of which 65% was esterified to the sn-2 position. The sum of carbon numbers 42-46 before and after 1,3 interesterification was 6.0 and 22.5, respectively.

TABLE III

Overall and 2-position fatty acid composition of Fats I-III

Fat I Fat II Fat III

Overall 2-position Overall 2-position Overall 2-position

8:0 3.9 0.4 1.7 0.3

10:0 3.4 1.5 1.4 0.8

OJ

10 12:0 0.2 48.7 48.1 20.9 21.1

14:0 1.2 1.3 15.0 14.8 6.1 7.0

16:0 53 88.1 7.5 4.1 37.4 47.6

18:0 3.6 3.1 3.0 1.7 3.3 2.9

18:1 33.8 5.6 15.6 25.0 26.0 16.3

15 18:2 6.6 1.9 2.9 4.1 5.1 3.5

18:3 0.3

TABLE IV

Carbon Number distribution of fats (I & II) and III

Fats (I&II) Fat III

30 0.2 0.1

32 1.1 0.5

34 1.8 0.8

36 5.0 2.7

38 4.3 3.5

40 2.9 7.9

42 3.1 10.7

44 2.7 13.4

46 3.4 18.1

48 13.7 15.3

50 29.8 13.2

52 24.4 9.7

54 5.0 2.6

TABLE V

Lard/PK 6 parts/2.5 parts

Physical blend Fat IV After Fat V + 1.5 interesterification parts Fat V soybean oil

28 0.38 - -

30 0.38 0.12 0.1

32 1.9 0.43 0.4

34 2.6 0.5 0.42

36 6.9 1.6 1.4

38 5.3 2.8 2.4

40 3.0 3.7 3.1

42 2.8 7.5 6.4

44 2.15 8.0 6.8

46 2.0 14.6 12.4

48 3.4 17.4 14.8

50 10.0 12.6 11.0

52 42.0 19.2 20.5

54 15.9 10.9 19.2

56 1.35 0.6 0.8

TABLE VI

Physical blend Fat VI After interesterification

Fat VII

26 0.3 1.4

28 1.1 1.4

30 1.1 2.0

32 3.3 3.4

34 6.5 4.9

36 13.7 6.3

38 14.3 7.8

40 10.3 8.6

42 7.3 9.5

44 6.0 10.8

46 6.1 12.5

48 7.7 12.4

50 8.9 9.4

52 8.4 6.7

54 4.8 2.8

TABLE VII

Fatty acid composition of Fat blend (Fats IX & X)

FAME wt%

8:0 1.3

10:0 1.1

12:0 7.6

14:0 3.0

16:0 25.7

18:0 2.2

18:1 38.7

18:2w6 16.2

18:3w3 2.9

TABLE VIII

Carbon Number distribution of fats XI and XII

wt%

Carbon Physical blend After 1,3 Number Fat IX interesterification

Fat X

32 0.95 -

34 1.6 -

36 2.2 0.2

38 2.1 0.4

40 1.5 1.2

42 1.2 3.1

44 0.8 4.4

46 0.4 9.6

48 1.1 13.0

50 10.5 16.8

52 58.5 34.3

54 17.5 15.6

56 0.7 0.7

58 0.3 0.2

TABLE IX

Fatty Acid composition of Fat blend (Fats XI & XII)

FAME wt%

6:0 0.6

8:0 1.5

10:0 1.6 12:0 8.1

14:0 5.1

16:0 24.1

18:0 5.1

18:1 36.9 18:2 12

18:3 0.9

TABLE X

Carbon Number distribution of Fats XI and XII

Carbon wt% Number

Physical blend After 1,3 Fat XI interesteri ication

Fat XII

32 0.8 0.2

34 1.7 0.4

36 3.2 0.8

38 3.7 2.9

40 3.2 3.8

42 2.4 5.1

44 1.8 6.7

46 1.8 10.7

48 3.4 14.3

50 10.0 15.4

52 48.8 22.6

54 16.1 12.2

56 0.5