Stanol comprising compositions

The invention regards a process for the preparation of a mixture of stanol and stanol fatty acid esters by esterification of phytosterols with a source for fatty acid moieties, in such a way that the degree of esterification of the phytosterols is in the range of 40-85%, and subsequent hardening of the so obtained sterol/sterol fatty acid mixture, the process can be carried out without the use of any solvent, and wherein preferably the fatty acid groups of the stanol fatty acid esters are substantially saturated fatty acid esters. Also claimed are food products comprising mixtures of stanol and stanol fatty acid esters, in particular fat based food products such as yellow fat spreads.

BACKGROUND OF THE INVENTION
 The present invention concerns a method for the production of stanol fatty
 acid esters, a stanol fatty acid ester composition, and the use thereof in
 food products, in particular in fat based food products in amounts
 sufficient to obtain a blood cholesterol lowering effect if the food
 product is used according to the common needs of the consumer.
 Fatty acid esters of phytosterols and/or phytostanols are hydrolysed in the
 gut and the subsequent free phytosterols and/or phytostanols will inhibit
 the absorption of cholesterol thereby lowering the blood cholesterol. Free
 phytosterols and/or phytostanols themselves are hardly absorbed.
 Indications in literature are that phytostanols are absorbed even in a
 lesser extend than phytosterols. The use of phytostanols in fat based food
 products to lower blood cholesterol could therefore be preferred over the
 use of phytosterols.
 In U.S. Pat. No. 5,502,045 (Raision Tehtaat Oy AB) a substance of
 beta-sitostanol fatty acid ester is described produced by 1. solvent
 hardening of beta-sitosterol followed by 2. esterification of the formed
 beta-sitostanol with fatty acids. The so formed mixture of beta-sitostanol
 fatty acid esters can be used as such or added to a food.
 There are several disadvantages to this production method, of which the
 most severe is that the beta-sitosterol should first be solubilized in a
 solvent (e.g. ethylacetate, butanol, ethanol) before the hardening of the
 sterol can be performed. Because the solubility of beta-sitosterol, or
 phytosterols in general, in solvents is rather limited, the hardening step
 is a relatively expensive operation because of high solvent costs and high
 costs of hardening equipment of relatively large volume. Moreover, the
 solvents need to be recovered after the hardening process is completed,
 and suitable locations for above hardening process will be limited because
 of environmental regulations. Furthermore, in a process aiming at the
 production of a food ingredient, removal of all solvents is essential,
 this making the process even more expensive.
 It has been observed that the stability of fat based food products
 diminishes by the addition of sterols and stanols thereto, in particular
 when the sterols/stanols are used at higher levels. As sterols and stanols
 are not very soluble in fat large crystals thereof are found in the
 products prepared with these sterols or stanols. For example, very serious
 crystal formation is observed at 3-4% sterol levels On the other hand,
 however, the use of these higher levels is often required to obtain the
 significant cholesterol reduction level that is desired.
 It is well known that by esterification of sterols/stanols with fatty
 acids, the solubility can be increased. However, a disadvantage of
 esterification is that this decreases the efficacy of the sterol/stanol
 compounds to lower the blood cholesterol level. Another disadvantage found
 in the use of sterol/stanol fatty acid esters is that the absorption of
 lipophilic micronutrients (like beta-carotene) decreases (Gyling HK et al
 (1996) Circulation 6: I-578).
 Another disadvantage found with the esterification of sterols/stanols is
 found in the production thereof, requiring long processing times and/or
 high processing costs.
 SUMMARY OF THE INVENTION
 The disadvantages indicated above were found to be reduced with the present
 invention, which concerns a process for the production of a stanol and
 stanol fatty acid ester mixture, by esterification of phytosterols with a
 source for fatty acid moieties in such a way that the degree of
 esterification of the sterols is in the range of 40%-85%, and subsequent
 hardening of the so obtained sterol/sterol fatty acid ester mixture.
 Preferably, the degree of esterification is in the range of 50-85%, more
 preferably in the range of 55-80%, and most preferably in the range of
 60-70%. This process allows a preparation of mixtures of stanols and
 stanol fatty acid esters without the presence of a solvent needed in any
 of the process steps. Sources for fatty acid moieties, are the known
 compounds, normally applied in esterification reactions. Preferred sources
 are free fatty acids and triglycerides.
 This invention allows that a significant cost reduction can be achieved, as
 the amount of the relatively expensive sterols used as the starting
 material can be reduced without a decrease of comparable blood cholesterol
 lowering efficacy of the end product, whereas a further reduction of costs
 is obtained in the time and processing reduction of the esterification
 process of the sterols. By partial esterification of the sterols and
 subsequent hardening of the sterol/sterol ester mixture so obtained no
 solvents in the hardening step are needed since the sterolester mixture is
 in a liquid state. Using such a solvent free production method, which is
 more environmental friendly, and does not require specific legal
 admissions, is also more cost effective due to the fact that less raw
 materials, equipment and labour is required.
 Hence, advantages are found in minimization of possible negative side
 effects and optimization of efficacy, quality (solubility) and production
 costs.
 Where in this application sterols are mentioned, phytosterols
 (4-desmethylsterols, 4-monomethylsterols and 4,4'-dimethylsterols, and/or
 mixtures thereof) are meant. When stanols are mentioned the stanol
 analogous of above molecules and mixtures thereof are meant.
 For obtaining the sterolester mixture before hardening is carried out, the
 sterols are esterified with a source for one or more C2-24 fatty acids
 moieties to an esterification degree in the range of 40-85%, more
 preferably in the range of 50-80% and most preferably in the range of
 60-70%. For the purpose of the invention the source for fatty acid
 moieties can be indicated with the term C2-24 fatty acid and this refers
 to any molecule comprising a C2-24 main chain and at least one acid group.
 Although not preferred within the present context the C2-24 main chain may
 be partially substituted or side chains may be present. Preferably,
 however the C2-24 fatty acids are linear molecules comprising one or two
 acid group(s) as endgroup(s). Most preferred are linear C8-22 fatty acids
 as occur in natural oils. Suitable esterification conditions are for
 example described in WO 92/19640.
 Suitable examples of any such fatty acids are acetic acid, propionic acid,
 butyric acid, caproic acid, caprylic acid, capric acid. Other suitable
 acids are for example citric acid, lactic acid, oxalic acid and maleic
 acid. Preferred are lauric acid, palmitic acid, stearic acid, arachidic
 acid, behenic acid, oleic acid, cetoleic acid, erucic acid, elaidic acid,
 linoleic acid and linolenic acid.
 Most preferred are the C18 polyunsaturated, monounsaturated or saturated
 fatty acids like stearic acid, oleic acid, elaidic, linoleic acid,
 alpha-linolenic acid and gamma-linolenic acid, since after fully hardening
 of sterolesters comprising these fatty acids, the fatty acid part will be
 the saturated stearic acid, which has a neutral effect on blood
 cholesterol.
 When desired a mixture of fatty acids may be used. It is also possible to
 use a natural occurring fat or oil as a source of the fatty acid moieties
 and to carry out the esterification via an interesterification reaction
 herewith. Most preferred are fatty acid mixtures containing high amounts
 (&gt;70%) of C18 polyunsaturated, monounsaturated or saturated fatty acids
 such as fatty acid mixtures of sunflower, safflower, rapeseed, linseed,
 linola and/or soybean.
 The invention further concerns the stanol and stanol fatty acid ester
 mixture so produced. Also claimed are stanol and stanol fatty acid esters
 mixtures wherein the fatty acid groups of the stanol fatty acid esters are
 substantially saturated fatty acid groups, and preferably, &gt;85% are
 saturated, more preferably &gt;90%, and most preferably &gt;95% are saturated.
 The invention further describes food products comprising such a mixture.
 The food products of the invention comprise at least 1% of stanol
 equivalents (present as free stanols and stanol fatty acid esters) whereby
 the degree of esterification is in the range of 40-85%. It has been
 observed that such products do not show instability and/or crystal
 formation, whereas the maximum blood cholesterol lowering efficacy of the
 stanols is obtained, while negative effects on absorption of lipophilic
 micro-nutrients are avoided. This beneficial effect is in particular
 suitable for products comprising at least 5% of a mixture comprising
 15-50% stanols and 50-85% stanol fatty acid esters.
 The invention was found to be in particular beneficial at stanol levels
 above 3 wt. % (total of stanol and stanol ester mixture), and more
 preferably at levels of at least 5 wt. %. Normally, a total stanol
 (equivalents) level range of 7-15 wt % provides sufficient to good results
 when applied in daily consumed food products.
 As mentioned, it has been found that the majority of the stanols does not
 have to be esterified to produce a decent and effective blood cholesterol
 lowering fat based food product. Moreover, it has been found that
 esterification of all or nearly all of the stanols decreases the efficacy
 of these compounds to lower blood cholesterol. Furthermore it is
 anticipated that the decrease of absorption of lipophilic micronutrients
 (like beta-carotene) will be less than earlier reported (Gyling HK et al
 (1996) Circulation 6: I-578) when less of the sterols in the food product
 are esterified.
 DETAILED DESCRIPTION OF THE INVENTION
 A specific embodiment of this invention regards the use of a stanol and
 stanol fatty acid mixture in fat based food products. Fat based food
 products are food products (partially) based on fat and regarded by the
 consumer, as `fatty type of products`. Examples are yellow fat spreads
 (containing vegetable fat and/or animal fat such as butterfat), dressings,
 coffee-creamer, shortenings, cooking and frying oils, fillings and
 toppings, ice-cream and the like. These products in most cases comprise a
 particular amount of fat. In some cases, however, products are still
 regarded as `fatty type of products`, despite a replacement of part or
 even all of the fat by fat replacers. Fat based food products in which the
 fat is partially or completely replaced by fat replacers are also covered
 by the term fat based food products of this invention.
 The food products as such are common products in the western world, and are
 used by consumers on a daily basis in amounts different for each
 individual. The invention is in particular very suitable for yellow fat
 spreads, dressings, cheese, shortenings, cooking and frying oils and ice
 cream, with a preference for yellow fat spreads, mayonnaise, dressings,
 shortenings, cooking and frying oils. On the basis of habits of the
 consumer in the western world, the invention is preferred to concern in
 particular for yellow fat spreads (including margarines, butter and low
 fat spreads) and dressings. Yellow fat spreads, for this invention, can
 comprise 0 (zero) to 90% fat (usually 5-80%). Dressings can comprise 0 to
 85% fat (usually 5-80%), shortenings, cooking and frying oil more than 95%
 fat.
 The most advantageous level of sterols to be esterified within the teaching
 of the present invention depends on the fat level in the food product and
 the total level of stanols (including the stanol fatty acid esters)
 therein. At a given total stanol amount in the product, the most
 advantageous degree of esterification will be lower for high fat levels
 than for low fat levels (based on total food product). For example, at
 total stanol equivalent levels of about 10% and at fat levels in the range
 of 50-90%, the degree of esterification is suitably optimized in the range
 of 40-75%, whereas at a total stanol equivalent level of about 10% and a
 fat level in the range of 0-50%, the degree of esterification optimum will
 be found in the range of 60-90%.
 Also, higher stanol equivalent levels at given fat level will lead to
 optimization at higher degrees of esterification.
 The preparation of the fat based food products comprising the stanol fatty
 acid esters of the invention can be carried out in any suitable manner
 commonly known. Suitably, the stanol fatty acid ester mixture can be added
 and dissolved to the fat prior to combining with the aqueous phase of the
 product to be prepared.
 In a preferred embodiment, the food product is a yellow fat spread
 comprising 0 to 80% fat, and at least 1 wt. % and preferably at least 2
 wt. % and more preferably at least 5 wt % stanol equivalents (present as
 free stanols and stanol ester mixture prepared according to the
 invention). In its most preferred embodiment, the amount of stanol
 equivalents is at least 5%, with optimal results found when the amount of
 stanol equivalents is in the range of 7-15%.
 The invention is in particular suitable for low fat spreads having a fat
 level in the range of 0-40%, where the amount of cholesterol level
 reducing fat is low. However, another preference exists for higher fat
 level spreads (60-80% fat), as a very significant reduction of cholesterol
 level in the blood serum can be obtained when high PUFA fat level fats are
 used, and where the fat in the spread is not optimised on PUFA, to add the
 cholesterol lowering effect upon use to such spreads.
 The fat that is applied in these fat based food products can be any fat,
 such as dairy fat and/or vegetable fat. However, if fat is present, for
 health reasons the use of one or more vegetable fat sources is preferred.
 In particular, the use of liquid fats is preferred.
 The fat can be one single fat or a blend. The use of fat compositions
 comprising a considerable amount of PUFA rich triglycerides in addition to
 the use of the stanol/stanol fatty acid ester mixture is in particular
 considered highly beneficial. For example, oils of sunflower, safflower,
 rapeseed, linseed, linola and/or soybean can be used in a preferred
 embodiment. Also the fat compositions mentioned in Netherlands patent
 documents no. NL 143115, NL 178559, NL 155436, NL 149687, NL 155177,
 European patent documents EP 41303, EP 209176, EP 249282, and EP 470658
 are highly suitable.
 If a fat blend is used, it is preferred that it comprises at least 30%, and
 more preferred at least 45% of poly-unsaturated fatty acids, based on the
 total weight amount of the fat in the fat based food product. So, a strong
 effect on the cholesterol lowering effect is obtained if use is made of an
 optimal ratio of stanol and stanol-esters as set forth in this application
 in a food product in which a fat blend comprising at least 30 wt. % of
 PUFA rich triglycerides is used.
 As fat spreads are a commonly and daily used product in western food eating
 habits, a preference exists for the use of a mixture of stanol and stanol
 fatty acid esters, in all the preferred embodiments as set forth above, in
 fat spreads.
 Where butterfat is used for preparing spreads of the invention, or where
 the spreads are butter, it is preferred that the amount of stanol
 equivalents is in the range of 5-15%, preferably 10-15%. As the
 consumption of butter is considered less beneficial for consumers health,
 the present invention is in particular suitable for making spreads
 containing butter or butter-melanges, as the negative effect associated
 with the butter consumption can be minimized or even reversed.
 Another advantage of the present invention is that stanol ester produced by
 esterification to a degree of 40-85% and subsequent hardening (i.e. stanol
 esters with saturated fatty acids) have a stronger structuring properties
 than stanolesters mixtures comprising mainly mono- or poly-unsaturated
 fatty acids, due to their higher melting points. By using the so produced
 stanol and stanol esters with saturated fatty acids, the amount of
 hardstock required to make a spreadable product out of above mentioned
 liquid oils can be more reduced than with stanolesters mixtures comprising
 mainly mono- or poly-unsaturated fatty acids, thereby potentially
 optimizing the amount of PUFA rich glycerides in the product further, and
 thereby compensating the saturated fatty acid part of the stanol ester
 mixture applied in the product.

EXAMPLES
 Example 0a
 Partial Esterification of Sterols to Sterolesters with an Optimal
 Esterification Degree by Stopping Reaction
 A mixture of sterols derived from soybean oil distillates was partially
 esterified with sunflowerseed oil fatty acid methylesters in such a way
 that an optimal ratio between free sterols and sterolesters was obtained.
 A mixture of 60.8 kg sterols and 43.8 kg sunflowerseed oil methylesters was
 dried for 2 hours at 120 degree C. under a reduced pressure of 5-40 mbar.
 Then the interesterification was started by adding 120 g of sodium
 methylate catalyst under a reduced pressure of 30-40 mbar and at 125
 degree C. After 1 h and 15-30 minutes the mixture was cooled to 90 degree
 C. and the reaction was stopped by adding 10% of a diluted citric acid
 aqueous solution. An esterification or conversion degree of about 60% was
 obtained. After washing, the water was separated and the mixture was dried
 and bleached. The residual methylesters were removed by
 stripping/deodorisation.
 Example 0b
 Esterification of Sterols to Sterolesters with a Maximal Esterification
 Degree and Optimizing the Free Sterol to Sterolester Ratio Afterwards
 Firstly, a mixture of sterols derived from soybean oil distillates was
 fully esterified with sunflowerseed oil fatty acid methylesters.
 A mixture of 60.8 kg sterols and 43.8 kg sunflowerseed oil methylesters was
 dried for 2 hours at 120 degree C. under a reduced pressure of 5-40 mbar.
 Then the interesterification was started by adding 120 g of sodium
 methylate catalyst under a reduced pressure of 15-30 mbar and at 125
 degree C. After 2 h and 30 minutes the mixture was cooled to 90 degree C.
 and the reaction was stopped by adding 10% of a diluted citric acid
 aqueous solution. An esterification or conversion degree of about 91% was
 obtained. After washing, the water was separated and the mixture was
 dried.
 Secondly, 23.4 kg of unesterified sterols were added and dissolved to
 obtain an optimal esterification degree of about 60%. Next this mixture
 was bleached and the residual methylesters were removed by
 stripping/deodorisation.
 Example 1a
 Hydrogenation of Free Sterol and Steryl Esters from Ex.0a
 A mixture of free sterols and sterols esters as obtained from Example 0a
 was hydrogenated on laboratory scale. As catalyst 5 wt % Pd on activated
 carbon was used. To 0.5 kg of the sterylesters 2 g of catalyst was added
 and the mixture was heated to 90 degree C. under a reduced pressure of
 5-30 mbar.
 The hydrogenation was carried out at 90 degree C. and at 3 bar hydrogen
 pressure. After 90 minutes approximately 40% of the theoretical amount of
 hydrogen was absorbed and again 2 g of catalyst was added. After 7.5 hours
 approx. 80% of the theoretical amount of hydrogen was absorbed and 2 g of
 catalyst was added and the temperature was increased to 95-115 degree C.
 Finally, after 11 hours of reaction approx. 100% of the theoretical amount
 of hydrogen was absorbed. At that moment no extra hydrogen was absorbed
 anymore and the hydrogenation was ended.
 The major part of the catalyst was removed by filtration over a paper
 filter. The remaining part of the catalyst was removed by applying 2%
 Hyflow and filtration over a paper filter.
 Analysis indicated that a hardening conversion of about 95% was achieved.
 Example 1b
 Hydrogenation of Free Sterol and Steryl Esters from Ex.0b
 A mixture of free sterols and sterols esters as obtained from Example 0b
 was hydrogenated on laboratory scale. As catalyst 5 wt % Pd on activated
 carbon was used. To 0.5 kg of the sterylesters 2 g of catalyst was added
 and the mixture was heated to 90 degree C. under a reduced pressure of
 5-30 mbar.
 The hydrogenation was carried out at 90 degree C. and at 3 bar hydrogen
 pressure. After 90 minutes approximately 40% of the theoretical amount of
 hydrogen was absorbed and again 2 g of catalyst was added. After 7.5 hours
 approx. 80% of the theoretical amount of hydrogen was absorbed and 2 g of
 catalyst was added and the temperature was increased to 95-115 degree C.
 Finally, after 11 hours of reaction approx. 100% of the theoretical amount
 of hydrogen was absorbed. At that moment no extra hydrogen was absorbed
 anymore and the hydrogenation was ended.
 The major part of the catalyst was removed by filtration over a paper
 filter. The remaining part of the catalyst was removed by applying 2%
 Hyflow and filtration over a paper filter.
 Analysis indicated that a hardening conversion of about 95% was achieved.
 Example 2a
 Preparation of a Spread 70% Fat (Stanol esters Ex.1a)
 Refined sunflower oil (65% PUFA as linoleic acid) was enriched with
 esterified stanols as obtained from Example 1a (to a total stanol
 equivalent concentration of 45%). Of this stanol-ester concentrate, 22
 parts were mixed with 35 parts of normal refined sunflower oil, 15 parts
 of refined rapeseed oil and 8 parts of a refined interesterified mixture
 of 65 parts fully hardened palm oil and 35 parts fully hardened palm
 kernel oil. To this fatblend, small amounts of soybean lecithin,
 monoglyceride, flavours and beta-carotene solution were added.
 To 18 parts water, small amounts of whey protein powder, flavour, and
 citric acid were added to obtain a pH of 4.8.
 80 parts of the fat phase composition (containing 70% of fat) and 20 parts
 of the aqueous phase composition were mixed and kept at 60 degree C. The
 mixture was then passed through a Votator line with 2 scraped surface heat
 exchangers (A-units) and 1 stirred crystallizer (C-unit) in AAC-sequence
 operating at 800, 800 and 100 rpm respectively. The product leaving the
 C-unit had a temperature of 11 degree C. It was filled into tubs and
 stored at 5 degree C. A good and stable, high PUFA, high fat-continuous
 spread enriched with 10% stanol equivalents (mainly present as C18:0
 stanol esters) was obtained.
 Example 3a
 Preparation of a Spread 40% (Stanol Esters Ex.1a)
 Refined sunflower oil (65% PUFA as linoleic acid) was enriched with
 esterified stanols as obtained from Example 1a (to a total stanol
 equivalent concentration of 45%). Of this stanol-ester concentrate, 22
 parts were mixed with 23 parts of normal refined sunflower oil and with 5
 parts of a refined interesterified mixture of 50 parts fully hardened palm
 oil and 50 parts fully hardened palm kernel oil. To this fatblend small
 amounts of soybean lecithin, monoglyceride and beta-carotene solution were
 added.
 To 44 parts water, gelatine and small amounts of whey protein powder,
 flavours, preservative and citric acid were added to obtain a pH of 4.7.
 50 parts of the fat phase composition (containing 40% of fat) and 48 parts
 of the aqueous phase composition were mixed and kept at 60 degree C. The
 mixture was then passed through a Votator line with 2 scraped surface heat
 exchangers (A-units) and 2 stirred crystallizers (C-unit), in
 ACAC-sequence operating at 500, 1000, 600 and 100 rpm respectively. The
 product leaving the last C-unit had a temperature of 10 degree C. It was
 filled into tubs and stored at 5 degree C. A good and stable, high PUFA,
 low fat-continuous spread enriched with 10% stanol equivalents (mainly
 present as C18:0 stanol esters) was obtained.
 Example 3b
 Preparation of a Spread 40% (Opt. Ratio Ex.1b)
 Refined sunflower oil was enriched with free and esterified stanols as
 obtained from Example 1b (to a total stanol equivalent concentration of
 45%). Of this stanol and stanol-ester concentrate, 22 parts were mixed
 with 23 parts of normal refined sunflower oil and with 5 parts of a
 refined interesterified mixture of 50 parts fully hardened palm oil and 50
 parts fully hardened palm kernel oil. To this fat blend small amounts of
 soybean lecithin, monoglyceride and beta-carotene solution were added.
 To 44 parts water, gelatine and small amounts of whey protein powder,
 flavours, preservative and citric acid were added to obtain a pH of 4.7.
 50 parts of the fat phase composition (containing 40% of fat) and 48 parts
 of the aqueous phase composition were mixed and kept at 60 degree C. The
 mixture was then passed through a Votator line with 2 scraped surface heat
 exchangers (A-units) and 2 stirred crystallizers (C-unit), in
 ACAC-sequence operating at 500, 1000, 600 and 100 rpm respectively. The
 product leaving the last C-unit had a temperature of 10 degree C. It was
 filled into tubs and stored at 5 degree C. A good and stable, high PUFA,
 low fat-continuous spread enriched with 10% stanol equivalents (present as
 free and as C18:0 stanol esters) was obtained.
 Example 4a
 Preparation of a Dressing (Stanol Esters Ex.1a)
 49 parts of water is mixed with 11 parts of various flavour components,
 preservatives, thickeners and emulsifiers. The mixture is thoroughly mixed
 in a stainless steel stirred vessel. To this aqueous mixture 20 parts of
 sunflower oil (65% PUFA as linoleic acid) enriched with 40% stanol
 equivalents present as stanol esters as obtained from Example 1a is added.
 To above oil in water mixture, 20 parts of normal refined sunflower oil is
 added, thoroughly mixed for an additional 15 min, to obtain a
 pre-emulsion. The pre-emulsion is brought into a colloid mill (Prestomill
 PM30) and processed at a split-size between level 15 and 20 and a
 throughput between level 4 and 6. A good and stable water continuous
 dressing enriched with 8% stanol equivalents (mainly present as C18:0
 stanol esters) is obtained.