US20040053376A1

US20040053376A1 - Procedure for the preparation of pure phosphatides and their use in the cosmetic, pharmaceutical and alimentary fields

Info

Publication number: US20040053376A1
Application number: US10/663,198
Authority: US
Inventors: Guenter Kirschner; Giampaolo Menon; Susanna Vaccaro
Original assignee: Fidia Farmaceutici SpA
Current assignee: Fidia Farmaceutici SpA
Priority date: 2001-02-09
Filing date: 2003-09-15
Publication date: 2004-03-18
Also published as: US6635456B2; US20020155558A1

Abstract

Process for preparing pure phosphatides starting from mixtures of natural phosphatides, or their single components, such as soybean or egg lecithin or animal phospholipids, or from synthetic phosphatides by reacting them both with phospholipase D derived from Streptomyces hachijoense in a completely aqueous medium in the presence of defined substates containing a primary or secondary alcoholic group, and their uses thereof.

Description

This application is a divisional of co-pending U.S. patent application Ser. No. 09/925,000 filed on Aug. 8, 2001, the entire contents of which are hereby incorporated by reference. This application also claims priority to Italian Patent Application PD2001 A 000031 filed in Italy on Feb. 9, 2001 under 35. U.S.C. §119.[0001]

SUBJECT OF THE INVENTION

The present invention concerns a process for the preparation of pure phosphatides starting from mixtures of natural phosphatides, or their single components, such as soybean or egg lecithin or animal phospholipids, or from synthetic phosphatides by reacting them with phospholipase D, with transphosphatidylation activity, in aqueous medium alone in the presence of defined substrates containing a primary or a secondary alcoholic group.

The invention also refers to the preparation, purification and characterisation of the phospholipase D used in the process.

BACKGROUND OF THE INVENTION

The synthesis of pure phospholipids, particularly on an industrial scale, is a particularly widespread problem. Indeed, there have been numerous scientific publications and patents, including some very recent ones that describe various methodologies. Generally, said methods exploit the transphosphatidylation properties of phospholipase D to obtain optically active phosphatides. One of the main problems is the fact that each of these methods is suited to the preparation of one specific phosphatide alone and cannot be adapted for the synthesis of the whole class of compounds. Generally, the most widely studied phospholipid is phosphatidylserine (PS), as it is widely used in the preparation of pharmaceutical compositions, in the preparation of liposome formulations and food supplements. Relatively little or nothing is reported concerning the synthesis of sphingophospholipids.

One limitation of all the methods reported in both the scientific and patent literature consists in the fact that the reaction of transphosphatidylation occurs in diphasic water/organic solvent systems. This presents a series of technical problems linked with the use of large quantities of solvent, especially when the industrial process is of a chemical nature, aimed at obtaining a quality product. In patent application No. DE 19917249 A1, a method is described that actually employs the aqueous phase alone, but neither the yield nor degree of purity of the PS obtained, nor the type of the utilised enzyme is reported. Moreover, there is no mention of whether it is possible to obtain other phospholipids besides PS by using the same technique and starting from the substrates used, or whether in the conditions described other phospholipids can act as reaction substrate. Japanese Patent Publication No. 5/42917 (JP 2130088) also discloses a method employing a medium comprised of water alone or a mixture of water and an organic solvent. However, this patent states that the water content is favored to be 10% by weight or less to prevent a side reaction. This reference, therefore, appears to suggest that using an aqueous environment alone is not favorable. In fact, the examples therein disclose only processes employing a biphasic mixture of water and ethyl ether.

The generic nature of the information given or absence of teaching in the aforesaid prior art concerning the applicability of the transphosphatidylation reaction of phospholipase D in aqueous phase alone could in no way have led an expert in the field to think that this was the solution to the problem. Moreover, the importance of removing impurities deriving from the use of organic solvents in processes for the manufacture of products for use in the alimentary and pharmaceutical fields has only become known in recent years, following the limitations dictated by the United States Pharmacopoeia (USP) and the European guidelines (CPMP/CH/283/95).

Another critical point that has not been investigated in-depth, either in the scientific literature or in patents, concerns the peroxidation of products caused by the use of heterogeneous phases of water/solvent in emulsion during the transphosphatidylation reaction, the reaction conditions used and the consequent need to perform numerous steps of the process (re-precipitation, washings and possibly also chromatography) to obtain products with a high degree of purity. Many of the solvents used for these reactions in the heterogeneous phase do not guarantee the absence of radicalic precursors typical of the initiation of the peroxidation reaction. Moreover, the shaking/stirring required to achieve a reaction in the heterogeneous phase increases the likelihood of there being contact with oxygen in the atmosphere and consequent triggering of oxidative phenomena. This peroxidation acts like a chain reaction, when even negligible initial primer steps can give devastating results over time, even though the triggering conditions have been eliminated or minimised. The peroxidation of a “fatty” substance such as triglycerides (oils or fats) and phospholipids too, causes the fatty acids to become “rancid”, with the consequent formation of an unpleasant smell and taste. It is particularly important that the products should have a high degree of palatability (smell and taste) when they, particularly PS, are used to prepare food supplements (nutraceuticals) with particular formulations such as granules or the so-called “functional foods”, to which the product is added to enrich their content. Consequently, it is important that the products obtained, particularly PS, should be clearly characterised in chemical terms, both with regard to the chemical composition of the fatty acids, and for the extent of their peroxidation and consequent palatability.

Lastly, it should be pointed out that the phospholipase D enzymes available on the market mainly have transphosphatidylation activity on the phosphatidylcholine fraction of the phospholipid mixture. Therefore, the other components such as phosphatidylethanolamine (PE) undergo hydrolysis to phosphatidic acid, thus reducing both the yield and the degree of purity of the finished product.

DETAILED DESCRIPTION OF THE INVENTION

Surprisingly, the Applicant has discovered that by using a purified fraction of phospholipase D from Streptoverticillium hachijoense, which is now properly referred to as Streptomyces hachijoense, it is possible to obtain a transphosphatidylation reaction with various alcoholic from a mixture of natural phosphatides or their purified fractions in a 100% aqueous environment with high yields of product, a high degree of purity and a peroxide index (degree of peroxidation) of less than 5, established according to the European Pharmacopoeia—Suppl 2000, page 41 (method A), by one single reaction step and one single precipitation.

The transphosphatidylation reaction can be conducted in various conditions of temperature and substrate concentration, adjusting the former between 20 and 60° C., preferably 45° C., and the latter between 10 and 500 mg/ml, preferably 150 mg/ml, according to the dispersibility of the substrates.

A second aspect of the present invention consists in the fact that this particular enzymatic preparation has a transphosphatidylation activity with high yields even on substrates other than phosphatidylcholine (lecithin), thus enabling the process to be used with low-cost, unpurified raw materials too.

The importance of the strain used for the preparation of the Phospholipase D and its fractionation can be deduced from the following table, where a comparison with different commercial enzymatic preparations is reported for the purified enzymatic fraction prepared according to Example 1.

Preparation of phosphaditylserine

Strain	Company	Product	PS	PA	PC

Streptomyces sp.	Sigma	P4912	50%	45%	5%
		type VI
Streptomyces sp.	Asahi Chemical	PL-DP	50%	45%	5%
	Industry Co., Ltd
Streptomyces	Sigma	P8023	40%	40%	20%
chromofuscus		type VI
Actinomadura sp.	Meito Sangyo	No code	45%	40%	15%
	Co., Ltd
Streptoverticillium	Fidia	FRS	95%	5%	—
hachijoense

Another advantage of the actual enzyme preparation and of the reaction conditions described in the instant invention is the practically complete conversion of the substrate to PS as compared to the conversion rate of not more than 70% achieved in JP 213008's diphasic water/organic solvent system.

A third aspect of the present invention concerns the preparation of pharmaceutical and cosmetic compositions and food and dietary supplements based on phospholipids, obtained according to the process described above, having a degree of peroxidation of less than 5 and a high degree of palatability, such as to make them preferable to other, similar products on the market that do not however have the above said characteristics.

The pharmaceutical compositions and the food and dietary supplements are particularly indicated in the treatment of conditions of psycho-physical stress with attention, concentration and memory deficits, often associated with advancing age, and they can be prepared, for example, in the form of capsules, tablets and granules.

The cosmetic compositions can chiefly be applied in the treatment of skin with impaired physiological functions and as aids in the therapy of dermatitis of an eczematous and/or inflammatory type, and they can be prepared, for example, in the form of creams or gels. For purely illustrative purposes, we report hereafter some preparation examples of Phospholipase D and phospholipids derived from it according to the present invention.

EXAMPLE 1

Preparation of Phospholipase D

The [0017] Streptoverticillium hachijoense ATCC 19769 strain is used.
Preparation of the inoculation to be used in the fermentation test begins with a colony on solid medium in a Petri dish. The composition of the solid medium is as follows: 21.0 g/litre Y.M., 2% agar. The bacteria taken from the Petri dishes are used to start a “scale-up” system in Ehrlenmeyer flasks as follows: [0018]
the bacteria are taken from the solid medium with a sterile platinum loop and inoculated in a 100-ml flask containing 20 ml of medium with the following composition: 21.0 g/lt of Y.M. broth; [0019]
the flask is placed in a shaker incubator set at 30° C., 150 rpm for 48 hours; [0020]
20 ml of culture is transferred to a 5.0-lt flask containing 2.5 lt of medium with the composition described above; [0021]
the flask is placed in a shaker incubator set at 30° C., 150 rpm for 72 hours. [0022]
At this point the culture is ready to be inoculated in the fermenter. This operation is made possible by the fact that the culture is in a flask fitted with a silicone tube and needle system. The fermenter used has a capacity of 50 lt (Braun Biostat U). The composition of the medium is as follows: Y.M. broth 21.0 gr/lt, pH 6.5 (the medium is sterilised directly in the fermenter by the addition of an antifoaming agent); the parameters of fermentation are: shaking at 200 rpm, temperature 30° C., air flow 0.5 vvm. [0023]
After 72 hours fermentation is interrupted. The maximum amount of enzyme reached is 5,000 U/lt and enzymatic activity is determined by the modified method of Kato et al. described in the literature (K. Shimbo et al., Agric. Biol. Chem. 54(5), 1189-93, 1990). [0024]

The culture broth is filtered to eliminate the biomass, the supernatant is concentrated using a spiral cartridge in cellulose acetate with a molecular cut-off of 10,000 D, and dialised against 50 mM Tris-HCl buffer, pH 8.0. The sample thus obtained is loaded on a chromatographic column (i.d.=10 cm, h=50 cm) packed with 500 gr of Whatman DE-52 anion-exchange resin pre-balanced with the same buffer as was used for dialysis. The enzyme is not adsorbed and elutes from the column, it is dialised against 20 mM Na-phosphate buffer, pH 5.4 and is then loaded on a chromatographic column (i.d.=10 cm, h=50 cm) packed with 50 gr of cationic exchange resin CM-Sephadex Pharmacia C-50 pre-balanced with the same buffer as the enzyme. The enzyme is eluted with a pH gradient of between 5.4 and 7.0 using an Na-phosphate buffer, 20 mM, pH 7.0. The fraction that elutes at pH 6.2 is harvested, concentrated and dialised against Tris-HCl buffer, 50 mM, pH 8.0, to a concentration of 100 U/ml and then freeze-dried.



Total	Total	Specific
activity	proteins	activity
(Unit ×	(mg ×	(Unit ×	Recovery
10³)	10³)	mg_prot)	(%)

Crude broth	250	250	1	100
Concentration and dialysis	237.5	118.8	2	95
DE-52 Whatman	212.5	2.2	97	85
CM-Sephadex C-50 Pharmacia	150	0.26	577	60
Concentration and dialysis	145	0.24	604	58
Freeze-drying	112.5	0.24	469	45

EXAMPLE 2

Preparation of PS from PC

In a jacketed reactor fitted with a shaker and reflux condenser, 272 g of sodium acetate trihydrate and 59 gr of calcium hydrochloride trihydrate are dissolved in 10 lt of water. The pH is adjusted to 5.6 (acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6) and 5.0 kg of L-serine is added and solubilised by heating to 45° C. The entire process is conducted under nitrogen. [0026]
Once solubilisation is complete, 1.5 kg of purified soybean lecithin with the following composition is added: PC 95%, PA 4%, lyso-PC 1%. Ten minutes later, 16,100 U of phopholipase D as in example 1 are added, and this is left to react for 24 hours at 45° C. [0027]
On completion of the reaction, the reactor is unloaded by adding 10 lt of a mixture of n-hexane/ispropanol/water (60/80/15); the mass is dissolved by shaking, then the shaking is stopped and the two phases are left to separate. [0028]
The lower phase is harvested and the unreacted L-serine is recovered by cooling in a crystallizer. The upper phase is washed with 6,950 ml of HCl, 1 N and 1,113 ml of isopropanol at 5° C. [0029]
The acid phase is counter-extracted with 10 lt of a mixture of hexane/isopropanol/water (60/80/15), after which the two organic phases are cascade-washed with a mixture of 7 lt of water and 6 lt of isopropanol. [0030]
The organic phases are concentrated under vacuum and precipitated by slowly adding a solution of 450 ml of sodium acetate, 4.5 M, in water in 33.2 lt of ethanol. [0031]
This is filtered and dried. [0032]
1.14 kg of phosphatidylserine with a titer of over 95%, a phosphatidic acid content of less than 5% and a peroxide index of less than 5 is obtained. [0033]
After crystallisation and drying, 3.25 kg of L-serine is harvested. [0034]

EXAMPLE 3

Preparation of PS from Egg Lecithin

180 ml of acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6, are placed n a jacketed reactor with a shaker and reflux condenser, after which 90 gr of L-serine is added and solubilised by heating to 45° C. The entire process is conducted under nitrogen. [0035]
Once solubilisation is complete, 27 gr of purified egg lecithin is added (PC content≧95%); 10 minutes later, 290 U of phospholipase D as per example 1 is added and it is left to react for 24 hours at 45° C. [0036]
Once the reaction is complete, the reactor is unloaded by adding 200 ml of a mixture of n-hexane/isopropanol/water (60/80/15) and the mass is dissolved by shaking, then the shaking is stopped and the two phases are left to separate. [0037]
The lower phase is discarded. [0038]
The upper phase is washed with 150 ml of 1 N HCl and 30 ml of isopropanol at 5° C. [0039]
The acid phase is counterextracted with 180 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the two organic phases are washed in a cascade with a mixture of 100 ml water and 130 ml of isopropanol [0040]
The organic phases are concentrated under vacuum and precipitated by the slow addition of a solution of 8 ml of 4.5 M sodium acetate in water in 600 ml of ethanol. [0041]
It is filtered and dried. [0042]
This yields 20.8 g of phosphatidylserine with a titer of over 95% with a phosphatidic acid content of less than 5% and a peroxide index of less than 5. [0043]

EXAMPLE 4

Preparation of Phosphatidylserine from Crude Soybean Lecithin

180 ml of acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6 are placed in a jacketed reactor with a shaker and reflux condenser, after which 90 g of L-serine is added and solubilised by heating to 45° C. The entire process is conducted under nitrogen. [0044]
Once solubilisation is complete, 27 g of crude soybean lecithin is added (total phospholipid content 75%, percentage composition PC 60.6/PE 29.5/PA 3.4/lyso-PC 2.5/other 3.9)); 10 minutes later, 290 U of phospholipase D as per example 1 is added and this is left to react for 24 hours at 45° C. [0045]
Once the reaction is complete, the solution is unloaded by adding 200 ml of a mixture of n-hexane/isopropanol/water (60/80/15) into the reactor and the mass is dissolved by shaking, then the shaking is stopped and the two phases are left to separate. [0046]
The lower phase is discarded. [0047]
The upper phase is washed with 150 ml of 1 N HCl and 30 ml of isopropanol at 5° C. [0048]
The acid phase is counter-extracted with 180 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the two organic phases are washed in a cascade with a mixture of 100 ml water and 130 ml of isopropanol [0049]
The organic phases are concentrated under vacuum and precipitated by the slow addition of a solution of 8 ml of 4.5 M sodium acetate in water in 600 ml of ethanol. [0050]
It is filtered and dried. [0051]
This yields 19 g of phosphatidylserine with a titer of 83.5% (PA 7.7%, lyso-PS 2.3%, PE 1.9%, other 4.5%) and a peroxide index of less than 5. [0052]

EXAMPLE 5

Preparation of Phosphatidyl-D-Serine

180 ml of acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6 are placed in a jacketed reactor with a shaker and reflux condenser, after which 90 g of D-serine is added and solubilised by heating to 45° C. The entire process is conducted under nitrogen. [0053]
Once solubilisation is complete, 27 g of purified soybean lecithin as per example 2 is added; 10 minutes later, 290 U of phospholipase D as per example 1 is added and it is left to react for 24 hours at 45° C. [0054]
Once the reaction is complete, the reactor is unloaded by adding 200 ml of a mixture of n-hexane/isopropanol/water (60/80/15). The mass is dissolved by shaking, then the shaking is stopped and the two phases are left to separate. [0055]
The lower phase is discarded. [0056]
The upper phase is washed with 150 ml of 1 N HCl and 30 ml of isopropanol at 5° C. [0057]
The acid phase is counter-extracted with 180 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the two organic phases are washed in a cascade with a mixture of 100 ml water and 130 ml of isopropanol [0058]
The organic phases are concentrated under vacuum and precipitated by the slow addition of a solution of 8 ml of 4.5 M sodium acetate in water in 600 ml of ethanol. [0059]
It is filtered and dried. [0060]
This yields 18.7 g of phosphatidyl-D-serine with a titer of over 95% with a phosphatidic acid content of less than 5% and a peroxide index of less than 5. [0061]

EXAMPLE 6

Preparation of Phosphatidylethanolamine (PE) from PC

200 ml of acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6 are placed in a jacketed reactor with a shaker and reflux condenser. The entire process is conducted under nitrogen. [0062]
58 g of ethanolamine is added and the pH is adjusted to 5.6 with glacial acetic acid at a temperature setting of 30° C. [0063]
At the end of the operation, it is heated to 45° C. and 30 g of purified soybean lecithin as per example 2 is added. After 10 minutes, 325 U of phospholipase D as per example 1 is added and this is left to react for 24 hours at 45° C. [0064]
Once the reaction is complete, the reactor is unloaded by adding 400 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the shaking is stopped and the two phases are left to separate. [0065]
The lower phase is discarded. [0066]
The upper phase is washed with 150 ml of 1 N HCl and 30 ml of isopropanol at 5° C. [0067]
The acid phase is counter-extracted with 180 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the two organic phases are washed in a cascade with a mixture of 100 ml water and 130 ml of isopropanol, then with 100 ml of sodium acetate, 1 N, and 130 ml of isopropanol. [0068]
The organic phases are concentrated under vacuum. [0069]
It is purified by silica gel chromatography using an axial pressure chromatograph with a 1 lt column equilibrated with chloroform/methanol (80/20); gradient elution is performed till chloroform/methanol/water (70/30/3). [0070]
The pure fractions are evaporated, dissolved in 250 ml of cyclohexane and freeze-dried, giving 24 g of a pale yellow, solid product, free from phosphatidic acid and lysoderivatives, and over 99% pure. [0071]

EXAMPLE 7

Preparation of Phosphatidyl-Homoserine from PC

180 ml of acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6 are placed in a jacketed reactor with a shaker and reflux condenser, after which 102 g of homoserine is added and solubilised by heating to 45° C. The entire process is conducted under nitrogen. [0072]
Once solubilisation is complete, 27 g of purified soybean lecithin as per example 2 is added; 10 minutes later, 290 U of phospholipase D as per example 1 is added and it is left to react for 24 hours at 45° C. [0073]
Once the reaction is complete, the reactor is unloaded by adding 200 ml of a mixture of n-hexane/isopropanol/water (60/80/15). The mass is dissolved by shaking, then the shaking is stopped and the two phases are left to separate. [0074]
The lower phase is discarded. [0075]
The upper phase is washed with 150 ml of 1 N HCl and 30 ml of isopropanol at 5° C. [0076]
The acid phase is counter-extracted with 180 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the two organic phases are washed in a cascade with a mixture of 100 ml water and 130 ml of isopropanol [0077]
The organic phases are concentrated under vacuum and precipitated by the slow addition of a solution of 8 ml of 4.5 M sodium acetate in water in 600 ml of ethanol. [0078]
This is filtered and dried. [0079]
22.6 g of phosphatidyl-homoserine is obtained, with a titer of over 95%, a phosphatidic acid content of less than 5% and a peroxide index of less than 5. [0080]

EXAMPLE 8

Preparation of Phosphatidyl-Hydroxyproline from PC

180 ml of acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6 are placed in a jacketed reactor with a shaker and reflux condenser, after which 112 g of hydroxyproline is added and solubilised by heating to 45° C. The entire process is conducted under nitrogen. [0081]
Once solubilisation is complete, 27 g of purified soybean lecithin as per example 2 is added; 10 minutes later, 290 U of phospholipase D as per example 1 is added and it is left to react for 24 hours at 45° C. [0082]
Once the reaction is complete, the reactor is unloaded by adding 200 ml of a mixture of n-hexane/isopropanol/water (60/80/15) and the mass is dissolved by shaking, then the shaking is stopped and the two phases are left to separate. [0083]
The lower phase is discarded. [0084]
The upper phase is washed with 150 ml of 1 N HCl and 30 ml of isopropanol at 5° C. [0085]
The acid phase is counter-extracted with 180 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the two organic phases are washed in a cascade with a mixture of 100 ml water and 130 ml of isopropanol [0086]
The organic phases are concentrated under vacuum and precipitated by the slow addition of a solution of 8 ml of 4.5 M sodium acetate in water in 600 ml of ethanol. [0087]
It is filtered and dried. [0088]
This yields 18.4 g of phosphatidyl-hydroxyproline with a titer of over 95%, a phosphatidic acid content of less than 5% and a peroxide index of less than 5. [0089]

EXAMPLE 9

Preparation of Phosphatidylglycerol from PC

200 ml of acetate buffer, 0.2 M+calcium chloride, 0.04 M, pH 5.6 are placed in a jacketed reactor with a shaker and reflux condenser. The entire process is conducted under nitrogen. [0090]
80 g of glycerol is added; it is heated to 45° C., then 30 g of purified soybean lecithin as per example 2 is added; 10 minutes later, 325 U of phospholipase D as per example 1 is added and it is left to react for 24 hours at 45° C. [0091]
Once the reaction is complete, the reactor is unloaded by adding 400 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the shaking is stopped and the two phases are left to separate. [0092]
The lower phase is discarded. [0093]
The upper phase is washed with 150 ml of 1 N HCl and 30 ml of isopropanol at 5° C. [0094]
The acid phase is counter-extracted with 180 ml of a mixture of n-hexane/isopropanol/water (60/80/15), then the two organic phases are washed in a cascade with a mixture of 100 ml water and 130 ml of isopropanol, then with 100 ml of sodium acetate, 1 N, and 130 ml of isopropanol. [0095]
The organic phases are concentrated under vacuum. [0096]
Purification is performed by silica gel chromatography using an axial pressure chromatograph with a 1-lt column equilibrated with chloroform/methanol (80/20). Gradient elution is performed till chloroform/methanol/water (70/30/3). [0097]
The pure fractions are evaporated, dissolved in 250 ml of cyclohexane and freeze-dried, giving 22.2 g of a white, solid product free from phosphatidic acid and lyso derivatives, with over 95% purity. [0098]
This is filtered and dried. [0099]

EXAMPLE 10

Harvesting and Recycling of L-Serine

The mother waters from the first partitioning of the enzymatic reaction as per example 2 are kept at a temperature of 0° C. for 24 hours, then the crystallised product is filtered. It is washed with ethanol and dried, giving white needles of pure product identical to the original. [0100]
The deficit in quantity (about 20%) is added and the product can be used as normal. [0101]

EXAMPLE 11

Examples of Pharmaceutical Compositions



(a) Each gelatinous capsule contains:
phosphatidylserine	100.0	mg
vegetal oil	270.0	mg
soy lecithin	30.0	mg
(b) Each injectable vial contains:
phosphatidylserine	50.0	mg
mannitol	100.0	mg
soy lecithin (injectable grade)	7.5	mg
phosphate buffer	2.2	mg
water	q.s.a. 2.0	ml

EXAMPLE 12

Examples of Food and Dietary Supplements



(a) Each gelatinous capsule contains:
phosphatidylserine	100.0	mg
vitamin E	5.0	mg
vegetal oil	295.0	mg
(b) Each sachet contains:
phosphatidylserine	100.0	mg
creatine	1.5	gr
beta-carotene	0.6	mg
vitamin E	5.0	mg
vitamin C	30.0	mg
vitamin B1	0.7	mg
vitamin B6	1.0	mg
vitamin B12	0.5	mcg
folic acid	0.1	mg
(c) Each chewable tablet contains:
phosphatidylserine	75.0	mg
vitamin E	5.0	mg
vitamin C	30.0	mg
vitamin B1	0.7	mg
vitamin B6	1.0	mg
vitamin B12	0.5	mcg
folic acid	0.1	mg

EXAMPLE 13

Examples of Cosmetic Compositions



(a) Each Body Cream Tube contains:
phosphatidylserine	4.0	gr
macadamia ternifolia	2.0	gr
sodium hyaluronate	10.0	mg
cetearyloctanoate	8.0	gr
caprylic/capric tryglyceride	7.0	gr
sorbitol	5.0	gr
cetearyl alcohol	4.0	gr
polysorbate 20	1.0	gr
carbomer	0.8	gr
sodium dehydroacetate	0.4	gr
disodium EDTA	0.3	gr
antioxidant (tocopherol)	50.0	mg
water	q.s.a. 100.0	ml
(b) Each Body Ointment Tube contains:
phosphatidylserine	3.0	gr
cholesterol	2.0	gr
sodium hyaluronate	10.0	mg
cetearyloctanoate	9.0	gr
caprylic/capric tryglyceride	7.0	gr
sorbitol	7.0	gr
cetearyl alcohol	3.5	gr
polysorbate 20	1.0	gr
carbomer	0.6	gr
sodium dehydroacetate	0.5	gr
disodium EDTA	0.3	gr
antioxidant (tocopherol)	50.0	mg
water	q.s.a. 100.0

The products described above in Examples 11 and 12 can be used in the treatment conditions of psycho-physical stress with attention, concentration and memory deficits, often associated with advancing age, and they can be prepared, for example in the form of capsules, tablets and granules. The tablets and capsules containing the phosphatides of the instant invention may be taken orally, typically 2-3 tablets or capsules per day. [0105]
The cosmetic compositions and body ointments described in Example 13 may be applied directly to affected areas and are used in the treatment of skin with impaired physiological functions and as an aid in the therapy of dermatitis. [0106]
Although the above pharmaceutical compositions have been described in particular physical forms with particular carriers, it will be recognized that the pharmaceutical compositions of the invention can be formulated in other standard physical forms combined with other known pharmaceutically acceptable carriers, excipients and diluents. [0107]
The invention being thus described, it is clear that these methods can be modified in various ways. Such modifications are not to be considered as divergences from the spirit and purpose of the invention and any modification that would appear evident to an expert in the field comes within the scope of the following claims. [0108]

Claims

1. A phosphatidyl-L-serine product having a fatty acid composition identical to that of soybean lecithin and a degree of peroxidation of less than 5 produced by reacting a phosphatide of formula (II):

R—O—PO(OH)—O—R₂ (II)

wherein R is diacylglycerol and R₂is CH₂—CH₂—NH₂or CH₂—CH₂—N(CH₃)₃, with a primary or secondary alcohol with a chain length of between C2 to C4, optionally substituted with one or more polar groups selected from the group consisting of amino, hydroxy and carboxy, in a single aqueous phase in the presence of an effective amount of phospholipase d with transphosphatidylation activity produced from a Streptomyces hachijoense strain to catalyze the reaction, wherein said phospholipase D is purified by eluting on an anionic cationic exchange resin at a pH of 6.2.

2. A phosphatidyl-L-serine product having a fatty acid composition identical to that of egg lecithin and a degree of peroxidation of less than 5 produced by reacting a phosphatide of formula (II):

R—O—PO(OH)—O—R₂ (II)

3. A phosphatidyl-L-serine product having a fatty acid composition identical to that of soybean lecithin and a degree of peroxidation of less than 5 produced by reacting a phosphatide of formula (II):

R—O—PO(OH)—O—R₂ (II)

wherein R is diacylglycerol and R₂is CH₂—CH₂—NH₂or CH₂—CH₂—N(CH₃)₃, with a primary or secondary alcohol with a chain length of between C2 to C4, optionally substituted with one or more polar groups selected from the group consisting of amino, hydroxy and carboxy, in a single aqueous phase in the presence of an effective amount of phospholipase D with transphosphatidylation activity produced from a Streptomyces hachijoense strain to catalyze the reaction.

4. A phosphatidyl-L-serine product having a fatty acid composition identical to that of egg lecithin and a degree of peroxidation of less than 5 produced by reacting a phosphatide of formula (II):

R—O—PO(OH)—O—R₂ (II)

5. A pharmaceutical composition comprising a pharmaceutically acceptable carrier and a phosphatide of formula (I)

R—O—PO(OH)—O—R₁ (I)

wherein R is diacylglycerol and R₁is an hydroxyl group,

made by the process of reacting a phosphatide of formula (II):

R—O—PO(OH)—O—R₂ (II)

wherein R is diacylglycerol and R₂is CH₂—CH₂—NH₂or CH₂—CH₂—N(CH₃)₃, with a primary or secondary alcohol with a chain length of between C2 to C4, optionally substituted with one or more polar groups selected from the group consisting of amino, hydroxy and carboxy, in a single aqueous phase in the presence of an effective amount of phospholipase D with transphosphatidylation activity produced from a Streptomyces hachijoense strain to catalyze the reaction to obtain said phosphatide according to formula (I).

6. A cosmetic composition comprising a pharmaceutically acceptable carrier and a phosphatide of formula (I)

R—O—PO(OH)—O—R₁ (I)

wherein R is diacylglycerol and R₁is an hydroxyl group,

made by the process of reacting a phosphatide of formula (II):

R—O—PO(OH)—O—R₂ (II)

7. A food and dietary supplement comprising a carrier and a phosphatide of formula (I)

R—O—PO(OH)—O—R₁ (I)

wherein R is diacylglycerol and R₁is an hydroxyl group,

made by the process of reacting a phosphatide of formula (II):

R—O—PO(OH)—O—R₂ (II)

8. The food and dietary supplement according to claim 7, wherein the phosphatide according to formula (I) is phospatidyl-L-serine and wherein the Streptomyces hachijoense strain used to catalyze the reaction is ATCC 19769.

9. A pharmaceutical composition capable of being administered orally comprising a pharmaceutically acceptable carrier and the phosphatidyl-L-serine product according to claim 3 or 4.

10. A cosmetic composition for topical application to the skin comprising a pharmaceutically acceptable carrier and phosphatidyl-L-serine made by the process according to claim 3 or 4.

11. A food and dietary supplement capable of being administered orally comprising a carrier and phosphatidyl-L-serine made by the process according to claim 3 or 4.

12. A method of treating psycho-physical stress, attention, concentration and memory deficits commonly associated with advancing age, comprising administering a therapeutically effective amount of a pharmaceutical composition according to claim 5.

13. A method of treating dermatitis or skin with impaired physiological functions comprising applying a cosmetic composition according to claim 6 to the skin.

14. A method of treating psycho-physical stress, attention, concentration and memory deficits commonly associated with advancing age comprising administering a food and dietary supplement according to claim 7.

15. The pharmaceutical composition according to claim 5 in the form of a capsule, tablet or granule.

16. The cosmetic composition according to claim 6 in the form of a cream or a gel.

17. A food and dietary supplement according to claim 7 in the form of a capsule, tablet or granule.

18. A food and dietary supplement according to claim 11 in the form of a capsule, tablet or granule.

19. The food and dietary supplement according to claim 8, wherein the phosphatide of formula (II) is selected from the group consisting of purified soybean lecithin and crude soybean lecithin.