Hydrated lamellar phases or liposomes which contain a fatty monoamine or a cationic polymer which promotes intracellular penetration, and a cosmetic or pharmaceutical composition containing same, as well as a method of screening such a substance

Abstract

The invention relates to novel hydrated lamellar phases or liposomes which contain either polyethylenimine, or a substance which stimulates intracellular penetration selected from the group consisting of: i) a fatty monoamine of carbon-containing chain length of between C10 and C18; ii) a cationic polymer,
optionally at least one fluorescent compound which is essentially inert with respect to the intracellular penetration, which enables this penetration to be visualised. These liposomes are very useful in cosmetics or in pharmacy for stimulating the intracellular penetration of a substance or active principle.

Claims

1. Hydrated lamellar phases or liposomes, comprising at least in part in their structure a substance or a mixture of substances which is (are) capable of stimulating the intracellular penetration of at least one active principle present or carried in said hydrated lamellar phases or liposomes and is (are) selected from the group consisting of: a) a primary, secondary, tertiary, or quaternary fatty monoamine of carbon-containing chain length of between C10 and C13; and b) a quaternised soya protein of formula RN(R.sub.1R.sub.2R.sub.3), in which R symbolizes the plant protein molecule, which is hydrolysed or not, hydroxypropylated; R.sub.1 and R.sub.2 independently being a C1-C6 hydrocarbon group, and R.sub.3 being an alkyl radical having 10 to 18 carbon atoms, and wherein the lamellar phases or liposomes comprise at least one polar lipid or a polar sphingolipid.

2. The lamellar phases or liposomes of claim 1, wherein the lamellar phases or liposomes further comprise at least one agent which modifies the membrane of liposomes in the lipid phase.

3. The lamellar phases or liposomes of claim 2, wherein said membrane modifying agent comprises a polar lipid selected from the group consisting of a triglyceride, a polar phospholipid, a polar sphingolipid, and any mixture thereof.

4. The lamellar phases or liposomes of claim 3, wherein the polar phospholipid is selected from phosphatidylcholine or lecithin, phosphatidylethanolamine or cephaline, phosphatidylserine, phospharidylglycerol, diphosphatidylglycerol, or cardiolipin, phosphatidylinositol, and any mixture thereof.

5. The lamellar phases or liposomes of claim 3, wherein the polar sphingolipid is selected from a ceramide, a sphingophospholipid, a glycosphyngolipid, and any mixture thereof.

6. The lamellar phases or liposomes of claim 1, wherein the lamellar phases or liposomes comprise at least one lecithin extracted from a natural source selected from the group consisting of soya, rape, sunflower, lupin, groundnut, sesame, marrow, bran oil, bigseed falseflax, calendula, flax, hemp, and any mixture thereof.

7. The lamellar phases or liposomes of claim 1, wherein the lamellar phases or liposomes comprise cholesterol or cholesterylhemisuccinate as an agent which rigidifies the membranes.

8. The lamellar phases or liposomes according to claim 1, wherein the concentration of the substance or the mixture of substances which stimulate(s) the intracellular penetration ranges between 0.05% and 25% by weight of a composition which contains the hydrated lamellar phases or liposomes.

9. The lamellar phases or liposomes of claim 1, wherein the concentration of the substance or the mixture of substances which stimulate(s) the intracellular penetration ranges between 0.5% and 2.5% by weight of a composition which contains the hydrated lamellar phases or liposomes.

10. The lamellar phases or liposomes of claim 1, wherein the substance or the mixture of substances is a quaternised soya protein of formula RN(R.sub.1R.sub.2R.sub.3), in which R symbolizes the plant protein molecule, which is hydrolysed or not, hydroxypropylated; R.sub.1 and R.sub.2 independently being a C1-C6 hydrocarbon group, and R.sub.3 being an alkyl radical having 10 to 18 carbon atoms.

11. The lamellar phases or liposomes of claim 1, wherein R.sub.3 is lauryl.

12. The lamellar phases or liposomes of claim 1, wherein R.sub.3 is an alkyl radical having 10 to 13 carbon atoms.

13. The lamellar phases or liposomes of claim 1, wherein the at least one active principle is selected from the group consisting of an anti-radical agent, a depigmenting agent, a slimming agent, a skin or hair pigmenting agent, and any mixture thereof.

14. The lamellar phases or liposomes of claim 13, wherein the anti-radical agent is selected from the group consisting of vitamin E, a flavonoid, a carotenoid, vitamin C, and any mixture thereof.

15. A cosmetic, dermocosmetic, pharmaceutical or dermopharmaceutical composition, comprising lamellar phases or liposomes which comprise at least one substance which stimulates intracellular penetration as defined in claim 1, in admixture with a cosmetically or pharmaceutically acceptable excipient.

16. The composition of claim 15, wherein the concentration of the substance which stimulates intracellular penetration ranges between 0.05% and 25% by weight of the final composition.

17. The composition of claim 16, wherein the concentration of the substance which stimulates intracellular penetration ranges between 0.5 and 2.5% by weight of the final composition.

18. A cosmetic or dermocosmetic composition having an anti-wrinkle effect, an antioxidant effect, a slimming effect, a skin paling effect, or a skin or hair pigmenting effect, comprising the hydrated lamellar phases or liposomes as defined in claim 1, wherein the lamellar phases or liposomes comprise the substance or the mixture of substances at a concentration of from 0.05% to 25% by weight of a final composition, in admixture with a cosmetically acceptable excipient.

19. A method of cosmetic care, comprising applying onto zones of skin or hair in need thereof the cosmetic or dermocosmetic composition as defined in claim 15.

20. The method of claim 19, wherein the cosmetic care is selected from the group consisting of an anti-wrinkles care, an antioxidant care, a slimming care, a skin paling care, and a skin or hair pigmenting care.

21. Liposomes, comprising: a) at least one active principle present or carried in said liposomes; b) polar phospholipid; and c) at least in part in their structure, a substance or a mixture of substances stimulating the intracellular penetration of the at least one active principle, wherein the substance or the mixture of substances comprises a cationic natural polymer or a natural polymer rendered cationic, selected from the group consisting of quaternised soya proteins of formula RN(R.sub.1R.sub.2R.sub.3), in which R symbolizes the plant protein molecule, which is hydrolysed or not, hydroxypropylated; R.sub.1 and R.sub.2 independently being a C1-C6 hydrocarbon group, and R.sub.3 being an alkyl radical having 10 to 18 carbon atoms.

22. The liposomes of claim 21, wherein the substance or the mixture of substances comprises a quaternised soya protein of formula RN(R.sub.1R.sub.2R.sub.3), in which R symbolizes the plant protein molecule, which is hydrolysed or not, hydroxypropylated; R.sub.1 and R.sub.2 independently being a C1-C6 hydrocarbon group, and R.sub.3 being an alkyl radical having 10 to 13 carbon atoms.

23. The liposomes of claim 21, wherein the substance or the mixture of substances is lauryldimonium hydroxypropyl hydrolysed soya protein.

24. The liposomes of claim 21, wherein the substance or the mixture of substances is cocodimonium hydroxypropyl hydrolyzed soya protein.

25. Hydrated lamellar phases or liposomes, comprising at least in part in their structure a substance or a mixture of substances which is (are) capable of stimulating the intracellular penetration of at least one active principle present or carried in said hydrated lamellar phases or liposomes and is (are) selected from the group consisting of: a) a primary, secondary, tertiary, or quaternary fatty monoamine of carbon-containing chain length of between C10 and C13; and b) a quaternised plant protein of formula RN(R1R2R3), in which R symbolizes the plant protein molecule, which is hydrolysed or not, hydroxypropylated; R1 and R2 independently being a C1-C6 hydrocarbon group, and R3 being an alkyl radical having 10 to 18 carbon atoms, wherein the hydrated lamellar phases or liposomes are prepared by: i) preparing a hydro-lipidic mixture comprising at least one polar lipid or a polar sphingolipid, wherein the hydro-lipidic mixture is capable of forming said hydrated lamellar phases or liposomes in a dispersion process; and ii) incorporating, before or during the dispersion process of the hydro-lipidic mixture, the substance or the mixture of substances to the hydro-lipidic mixture.

26. The hydrated lamellar phases or liposomes of claim 25, wherein the substance or the mixture of substances is a quaternised soya protein of formula RN(R1R2R3), in which R symbolizes the plant protein molecule, which is hydrolysed or not, hydroxypropylated; R1 and R2 independently being a C1-C6 hydrocarbon group, and R3 being an alkyl radical having 10 to 18 carbon atoms.

27. The hydrated lamellar phases or liposomes of claim 25, wherein the substance or the mixture of substances is lauryldimonium hydroxypropyl hydrolysed soya protein.

28. The hydrated lamellar phases or liposomes of claim 25, wherein the substance or the mixture of substances is cocodimonium hydroxypropyl hydrolyzed soya protein.

29. The method of cosmetic care of claim 19, wherein it is a method of skin care and wherein the composition is applied onto zones of the skin.

Description

DESCRIPTION OF THE FIGURES

(1) Annexed FIGS. 1 to 4 show the visualisation of the intracellular penetration of two pre-selected tracers according to the invention, PBF-F and TRITC, respectively:

(2) FIG. 1 represents fibroblasts which are incubated for 24 hours with liposomes having 0.01% of PBF-F with an enlargement of the objective multiplied by 10.

(3) FIG. 2 represents fibroblasts which are incubated for 24 hours with liposomes having 0.01% of PBF-F with an enlargement of the objective multiplied by 40.

(4) FIG. 3 represents fibroblasts which are incubated for 24 hours with liposomes having 0.01% of TRITC with an enlargement of the objective multiplied by 100.

(5) FIG. 4 represents fibroblasts which are incubated for 24 hours with liposomes having 0.01% of TRITC and 3% of PEI, with an enlargement of the objective multiplied by 100.

EXAMPLE 1

Preparation and Purification of Liposome Encapsulating a Fluorescent Tracer

(6) Fluorescent tracers not only have the advantage of being securing with regard to radioactivity for example, but are furthermore very simple to use when it is a question of making a quantification and of demonstrating a visual aspect of the intracellular penetration on cell culture models.

(7) The selection of the tracer necessitated the preparation of liposomes which contain 0.01% of various hydrosoluble or liposoluble tracers, and their purification so as to remove the non-incorporated tracer before their application onto normal human fibroblasts. A liposome control is made in parallel without fluorescent tracer.

(8) a) Selection of the Liposome Preparation Protocol

(9) Liposomes are prepared with a concentration of 20% of soya lecithin dissolved in Trizma dilution buffer (Sigma, France) 55 mM-27 mM NaCl adjusted to pH 5. After magnetic agitation for 30 minutes at ambient temperature, the mixture is very vigorously homogenised for 10 minutes.

(10) The liposomes are then diluted in DF medium [DMEM (Dulbecco's Modified Eagle's Medium)/Ham F12 glutamax 50/50 volume/volume, supplemented with 10% of calf serum, with penicillin at a final concentration of 100 UI/millilitre, with gentamicin at a final concentration of 1 microgram/millilitre, with amphotericin B at a final concentration of 1 microgram/millilitre] so as to obtain varying soya lecithin concentrations (0.5-1-2-3-4-5-7.5-10%).

(11) 250 l of liposomal suspension is added onto cultures of normal human fibroblasts extracted from abdominal plasy and cultivated in a 96-well plate. Each concentration is tested on 6 different wells. The cell viability is evaluated by a test with paranitrophenylphosphate which determines the intracellular alkaline phosphatase activity after three rinses with pH 7.4 phosphate buffer. The percentage of living cells is calculated with respect to a control made without the addition of liposome in the culture well (n=6).

(12) The results obtained show that a cell viability of more than 85% is obtained up to 7.5% of lecithin. At 10% of lecithin, the viability passes below the acceptable threshold of 75% viability.

(13) The concentration of 5% which enables a cell viability of greater than 90% to be obtained is selected.

(14) b) Preparation of 5% Soya Lecithin Liposome Incorporating a Fluorescent Tracer

(15) 0.5 g of soya lecithin, 0.01% of fluorescent tracer which is pre-solubilised according to the recommendations of the provider, are introduced into a dish and is diluted in 10 ml of Trizma buffer. After magnetic agitation for 30 minutes at ambient temperature, the mixture is vigorously homogenised for 10 minutes, in thus obtaining a liposomal solution in which the liposomes have an average size which can vary between 100 and 800 nanometres according to the exact conditions of homogenisation.

(16) The aim of the purification step is to separate the non-encapsulated tracer fraction from the fraction of tracer which is encapsulated in the liposomes. For this, the liposomal solution is centrifuged in a conical tube for 10 minutes at 1,790 g at ambient temperature. The plugs are then recovered and then solubilised in 10 ml of culture medium.

(17) The liposome negative control is made according to the protocol described above, without fluorescent tracer.

(18) The samples are preserved for 24 hours at 4 C. in the absence of light. 26 series of liposomes are made with various types of fluorescent tracers, pH sensitive ones, calcium-sensitive ones, or others.

EXAMPLE 2

Selection of a Fluorescent Tracer which can be Encapsulated in a Liposome, which does not Penetrate Spontaneously in Normal Human Fibroblasts in Culture

(19) The selection of the tracer necessitated the preparation and the purification of liposomes, according to the protocol described in Example 1, these liposomes containing varying concentrations of the various hydrosoluble or liposoluble tracers (Table 1, Annex 1). The controlsa free fluorescent tracerare made by dissolution at the same concentration of fluorescent tracer in the dilution buffer, so as to quantify its cytotoxicty and its spontaneous penetration in the fibroblasts.

(20) The comparison with a liposome which does not contain any fluorescent tracer as negative control is made in parallel.

(21) Practically, after extraction from a biopsy originating from abdominal plastic surgery, the fibroblasts are amplified in DF medium, i.e.: DMEM (Dulbecco's Modified Eagle's Medium)/Ham F12 glutamax 50/50 volume/volume, supplemented with 10% of calf serum, with penicillin at a final concentration of 100 UI/millilitre, with gentamicin at a final concentration of 1 microgram/millilitre, with amphotericin B at a final concentration of 1 microgram/millilitre.

(22) Firstly, after centrifugation, the purified liposomes are taken up into DF culture medium, homogenised in a vortex, and are deposited at the rate of 1 ml per well on the fibroblasts cultivated in 24-well plates (Costar MW24). The controls are made under the same conditions. A non-treated control is also made.

(23) The fibroblasts are incubated for 24 hours at 37 C. in the presence of the liposomes, and are then rinsed 3 times in pH 7.4 phosphate buffer. First of all, the fluorescence is evaluated dry by spectrofluorimetry with a Cytofluor 4000 (Millipore). Secondly, the intracellular fluorescence is observed for the molecules of interest on an Olympus reverse microscope (IX70) by using the corresponding excitation filter (objective 10, 40 and 100). Finally, the cytotoxicity of the fluorescent tracers is evaluated in a 96-well plate by incubation for 24 hours as described in Example 1.

(24) The results obtained show that from the 25 molecules tested, only pentafluorobenzoylaminofluorescein PFB-F (P12925 Molecular Probes) and tetramethylrhodamine isothiocyanate TRITC (T-490 Molecular Probes) give interesting positive results after incorporation in a liposome, application on the fibroblasts for 24 hours and quantification of the penetration of the liposomal content.

(25) Annexed FIGS. 1 to 4 are photographs which visualise the intracellular penetration of the two pre-selected tracers PFB-F and TRITC at the concentration of 0.01% in liposomes after incubation with the fibroblasts for 24 hours.

(26) TABLE-US-00001 TABLE 2 Results of the tracer screening Cytotoxicity (% Penetration of the non- Penetration (fluorescence treated control) free probe after washing) PFB-F (485530) 110.7% 8 (gain 45) 65 (gain 45) TRITC (530620) 74.8 295 (gain 50) 1,119 (gain 50)
However, although the TRITC gives a more intense marking, (Table 1 and Annexed FIGS. 1 to 4), it is nevertheless slightly cyctotoxic, it penetrates slightly when it is added free in the culture medium. PFB-F thus seems to be a better tracer.

EXAMPLE 3

Study of the Intracellular Penetration in the Presence of PFB-F (Pentafluorobenzoylaminofluorescein) or TRITC (Tetramethylrhodamine Isothiocyanate) in the Presence or not of Polyethylenimine

(27) The intracellular penetration of liposomes which contain 5% of soya lecithin, 0.01% of PFB-F or TRITC in the presence or not of 0.5% 25 kDa polyethylenimine (PEI), which are prepared according to the protocol described in Example 1, is analysed after incubation for 24 hours on human fibroblasts cultivated in a 24-well plate, as described in Example 2.

(28) The results obtained show that the addition of PEI stimulates the penetration of the PFB-F liposomes 13.7 times, whereas the addition of PEI decreases the penetration of the TRITC liposomes 16 times (cf. photographs of Annexed FIGS. 1 to 4).

(29) The tracer retained is therefore PFB-F or pentafluorobenzoylaminofluorescein at 0.01% in the liposome.

EXAMPLE 4

Study of the Stability of the Liposomes Containing Pentafluorobenzoylaminofluorescein (PFB-F)

(30) The stability of the liposomes is analysed by study of the release of the fluorescent tracer into the DF culture medium by spectrofluorimetry; this study is made as a function of the pH, of the ionic strength and of the presence of detergent.

(31) Practically, liposomes which contain 5% of soya lecithin, 0.01% of PFB-F and 50 M of 25 kDa PEI are prepared. The liposomal solutions are adjusted to pH 6-7-8-9; the concentration of sodium chloride (NaCl) is adjusted to 50-100-150-200 mM and the concentration of sodium dodecyl sulphate (SDS) or Triton X-100 is adjusted to 0.1-0.5-1-3%. The results obtained are presented in Table 3.

(32) TABLE-US-00002 TABLE 3 Study of the release as a function of the presence of detergents, of the ionic strength and of the pH. Release: Molecules Concentrations Release: average Standard deviation Triton X-100 3% 44027 177 1% 45800 2888 0.5% 40834 39 0.1% 19829 103 SDS 3% 62481 180 1% 71809 1558 0.5% 76676 200 0.1% 22990 108 NaCl 200 mM 68527 2040 150 mM 7622 36 100 mM 6314 113 50 mM 5680 62 pH 9 25265 411 8 18816 226 7 8781 70 6 7640 55

(33) The results seem to indicate that the liposomes containing 50 M of 25 kDa PEI start to destabilise from 200 mM NaCl, 0.5% of Triton X-100 or SDS and above pH 7.

EXAMPLE 5

Yield of Encapsulation of the Fluorescent Tracer PFB-B as a Function of the Concentration of Polyethylenimine

(34) Liposomes are prepared according to the method described in Example 5 with increasing concentrations of 25 kDa PEI from 0 to 100 M. After centrifugation at 1,790 g for 10 minutes, the supernatants are quantified by spectrofluorimetry. The yields of encapsulation are calculated with respect to the initial concentration. The results are given in Table 4.

(35) TABLE-US-00003 TABLE 4 Yield of encapsulation of PFB-F as a function of the concentration of PEI Concentration of PEI (M) 0 1 10 50 100 Yield (%) 89.0 92.3 91.0 87.5 86.3

(36) It is noted that the yield of encapsulation is not affected by the increase in concentration of PEI.

EXAMPLE 6

Development of the Screening Conditions with Fluorescent Liposomes Containing Varying Concentrations of Polyethylenimine

(37) Liposomes are prepared according to the protocol described in Example 1 with varying concentrations of polyethylenimine (25 kDa PEIneutralised by 6N hydrochloric acid), i.e. 0-5-10-50 M and 0.01% of PFB-F.

(38) The quantification is carried out by spectrofluorometry after incubation on fibroblasts cultivated in a monolayer in a 24-well plate for 2-4-6-24 and 48 hours after 3 washings in pH 7.4 phosphate buffer, against a non-treated fibroblasts blank and after normalisation against free PFB-F at the same concentration. The results are given in Table 5.

(39) TABLE-US-00004 TABLE 5 Study of the intracellular penetration of the PFB-F as a function of time and the concentration of PEI (n = 4 for each condition), expressed in arbitrary units of fluorescence. Concentration of PEI 0 5 M 10 M 50 M Standard Standard Standard Standard Time Average deviation Average deviation Average deviation Average deviation 2 h 6 0 49 4 67 7 116 6 4 h 7 3 63 5 89 9 159 10 6 h 6 0 65 10 94 13 203 12 24 h 9 3 120 5 129 3 291 17 48 h 6 1 160 18 171 13 306 6
The best results are obtained for a concentration of 50 M of PEI and a minimum time of incubation on the fibroblasts of 24 hours. These conditions will be retained for the screening of the molecules which stimulate the intracellular penetration. The results are statistically significant of the free probe control (p<0.05) for all times as from the concentration of 5 M.

EXAMPLE 7

Analysis of the Intracellular Penetration and of the Cytotoxicity of Fluorescent Liposomes Containing 50 M Polyethylenimine as a Function of Time

(40) The experimentation is made according to Example 6 for PEI concentrations of 0 to 100 M. The quantification of the fluorescence is made according to Example 6. The stimulation of the intracellular penetration is expressed as a stimulation factor with respect to liposome without PEI.

(41) The cell viability is carried out in a 96-well plate (250 l of liposomal solution per well) by a test which evaluates the alkaline phosphatase activity on cell mats (test with paranitrophenylphosphate, n=6). The results of cell viabilities are expressed as a percentage of living cells with respect to a PEI-free fluorescent liposome control. The determination of IL1 alpha (Kit Quantikine R&D System) is done on the culture media sampled after 24 hours of incubation in parallel to a determination of total proteins (Bradford, Sigma). The results are given in Tables 6 and 7.

(42) TABLE-US-00005 TABLE 6 Factor of intracellular penetration of the PFB-F and cytotoxicity as a function of time and of the concentration of PEI (n = 4 for each condition). Time 0 5 M 10 M 50 M Viability PEI 50 2 h 0.7 5.4 7.4 12.9 93.8% 4 h 0.8 7.0 9.9 17.7 92.4% 6 h 0.7 7.2 10.4 22.6 83.9% 24 h 1.0 13.3 14.3 32.3 72.6% 48 h 0.7 17.8 19.0 34.0 48.4%

(43) TABLE-US-00006 TABLE 7 Determination of IL1 alpha in pg/mg of total proteins 25 kDa PEI 0 10 M 50 M 100 M Total proteins in g/ml 132.8 136.2 119.5 79.2 IL1 in pg/ml 9.2 12.7 13.1 14.4 IL1 in pg/mg of proteins 69.3 93.2 109.6 181.8 Stimulation factor 1 1.3 1.6 2.6

(44) The results show that it is possible to increase up to 34 times the penetration factor of the fluorescent tracer in the presence of PEI in this experiment. However, it is observed that at the concentration of 50 M of 25 kDa PEI, as from 24 hours, a non-negligible phenomenon of cytotoxicity is observed, at 48 hours, more than half of the cells are dead. As regards the synthesis of IL1 alpha at the concentration of 50 M, the stimulation is of 1.6 times, and at 100 M it is 2.6 times. This molecule therefore generates a stress of significant inflammatory nature.

EXAMPLE 8

Screening of Molecules which Stimulate the Intracellular Penetration of a Fluorescent Tracer Incorporated in a Liposome

(45) Liposomes are prepared with 5% of soya lecithin, 0.01% of PFB-F and 1-0.1-0.01% of molecule to be tested which is neutralised to pH 7 by hydrochloric acid if necessary in Trizma dilution buffer as described in Example 5.

(46) 55 molecules are firstly tested in triplicate, in comparison with the 50 M 25 kDa PEI. The intracellular penetration is quantified after 24 hours of incubation on normal human fibroblasts cultivated in 24-well plates as described in Example 2. The cell viability is estimated in a 96-well plate with 200 l of liposomal suspension. The results obtained for the concentration of 1% are given in Table 8 (Annex 2). Over the screening carried out, 15 molecules were selected since they are capable of stimulating the intracellular penetration of the fluorescent tracer by more than 10%. The cell viabilities are varied (from 37 to 99%) at a concentration of 1%. The visualisation of the fluorescent tracer confirmed the penetration for the molecules which stimulate the penetration by more than 32%. These molecules are retained in priority.

EXAMPLE 9

Influence of the Structure of the Molecules on the Stimulation of Intracellular Penetration

(47) The preparation of the liposomes with primary fatty monoamines of alkyl chain length of between 3 and 18 carbons and the quantification of the intracellular penetration of the fluorescent label are carried out as described in the preceding Example. The results are given in Table 9.

(48) TABLE-US-00007 TABLE 9 Stimulation of the intracellular penetration as a function of the carbon- containing chain length Number of carbons Primary monoamine with a single alkyl fatty chain STIMULATION FACTOR 25 kDa PEI control 34.7 C3 0.9 C4 1.4 C6 0.2 C7 3.7 C10 39.6 C11 95.3 C12 47.1 C13 44.5 C14 11.6 C15 14.9 C18 19.6

(49) The incorporation, in the membranes of the liposomes, of fatty amines having aliphatic chains of various sizes, shows clearly the impact of the length of the carbon-containing chains on the stimulating activity of the intracellular penetration of the PFB-F encapsulated in liposomes having 5% of lecithin. A rough classification of the fatty acids exists as a function of the length of chains. Short chains (less than 108 carbons), medium chains (from 10 to 18 carbons) and long chains (more than 18 carbons) are thus distinguished. In transposing this classification to the primary fatty amines tested within the context of this study, it appears that the medium chains are those which confer to the liposomes their property of stimulation of the intracellular penetration to the liposomes.

EXAMPLE 10

Influence of the Steric Hindrance on the Intracellular Penetration

(50) With the view to best defining the features of the molecules having a stimulating effect on the intracellular penetration of a fluorescent tracer encapsulated in liposomes having 5% of lecithin, we have observed the impact of the steric hindrance on the potential stimulating activity of these molecules. We have thus studied the intracellular penetration of the PFB-F encapsulated in liposomes in the presence of primary fatty monoamines on the one hand, and with secondary fatty monoamines on the other hand. The preparation of the liposomes with primary or secondary fatty amines and the quantification of the intracellular penetration of the fluorescent markers are carried out as described in Example 8. The results are given in Table 10. The diamines do not enable a better intracellular penetration of the marker.

(51) TABLE-US-00008 TABLE 10 Stimulation of the intracellular penetration as a function of the carbon- containing chain number Number of alkyl chains of the amine (chain length) Stimulation factor 25 KDa PEI 34.7 1(C4) 1.7 2(C4) 0.7 1(C10) 39.6 2(C10) 1.2

EXAMPLE 11

Influence of the Steric Hindrance on the Intracellular Penetration

(52) In proceeding as described notably in Example 9 or 10, it was shown that the length of the carbon-containing chain is however not the sole factor which intervenes in the stimulation of the intracellular penetration of the liposomal content.

(53) In fact, in making the comparison of the chemical structures given in the following Figure encapsulated in liposomes, a specificity of the R group is shown which interferes with the C.sub.12 carbon-containing chain.

(54) ##STR00001##

(55) The quaternised molecules Y and A are products which are very common to the person skilled in the art. The steric hindrance of the quaternised molecule (commercial molecules) incorporated plays a role in the stimulation of the intracellular penetration of the liposomes having lecithin.

(56) The molecules of the following classes (Table 11) can be, for example, used at 1% for stimulating the intracellular penetration at varying degrees up to +39%. Other quaternised hydrolysates of molecules extracted from almonds, peas, potato, or alga can also be used.

(57) TABLE-US-00009 Examples of commercially Examples of available quaternised potential molecules Chemical name providers wheat Cocodimonium, steardimonium, Croda hydroxypropyltrimonium or Lauryldimonium hydrolyzed wheat protein Wheat germ-amidopropalkonium chloride Soya Lauryldimonium hydroxypropyl hydrolyzed soya Croda protein, Cocodimonium hydroxypropyl hydrolyzed RITA soya protein, hydroxypropyl trimethyl corporation ammonium chloride hydrolyzed soya protein Soy dihydroxypropyldimonium glucoside Keratin Hydroxypropyltrimonium hydrolyzed RITA keratin corporation Casein Hydroxypropyltrimonium hydrolyzed RITA casein corporation Collagen Hydroxypropyltrimonium hydrolysed collagen, RITA corporation Lauryldimonium hydroxypropyl hydrolyzed Cognis collagen Silk Hydroxypropyltrimonium hydrolyzed silk RITA corporation Rice Cocodimonium hydroxypropyl hydrolyzed rice Sochibo protein Guar Hydroxypropyl guar Meyhall hydroxypropyltrimonium chloride, Hydroxypropyl guar Rhodia hydroxypropyltrimonium chloride, Guar hydroxypropyltrimonium, honey Hydroxypropyltrimonium honey ARCH Cellulose Polyquaternium 4 and 10 Quimasso Polyquaternium 39

EXAMPLE 12

Optimisation of the Concentration of Functionalising Molecule (which Stimulates the Intracellular Penetration)

(58) The stimulation of the intracellular penetration of the fluorescent tracer is optimised in testing various concentrations of functionalising molecule.

(59) Practically, liposomes are formed with 5% of soya lecithin, 0.01% of PFB-F, and 0.5 to 2.5% of the quaternised soya solution in Trizma dilution buffer. The intracellular penetration and the cytotoxicity are evaluated as described in Example 2. The results obtained are given in Table 12.

(60) TABLE-US-00010 TABLE 12 Study of the concentration of molecule which stimulates the intracellular penetration and the stimulation factor, as well as cell viability Quaternised soya in % 0.5 1 1.5 2 2.5 Stimulation factor 0.6 1.6 38.9 97.2 99.9 Cell viability (%) 92.4 97.9 87.9 75.4 77.3

(61) The intracellular penetration sought after can therefore be adjusted as a function of the concentration of functionalising agent and of the maximum cytotoxicity tolerated.

EXAMPLE 13

Inflammatory Effect Compared Between the Polyethylenimine and the Quaternised Soya Selected

(62) The stimulation of the synthesis of interleukin 1 alpha is compared between liposomes which are functionalised by 50 M PEI and various concentrations in solution of quaternised soya.

(63) Practically, liposomes are formed with 5% of soya lecithin, 0.01% of PFB-F, and 0.5 to 2.5% of the solution of quaternised soya or 50 M of PEI, in Trizma dilution buffer. The IL1 alpha content is evaluated with a kit (Quantikine R&D System) as described in Example 7. A test with paranitrophenylphosphate (PNPP) is carried out in parallel in order to evaluate the number of cells per well. The results of IL1 alpha content are compared to the optical density of PNPP obtained.

(64) The results obtained are given in Table 13.

(65) TABLE-US-00011 TABLE 13 Effect of the functionalising molecules (PEI and quaternised soya) on the synthesis of interleukin 1 alpha Concentration of functionalising molecule 50 M 0.5% 1.5% PEI soya 1% soya soya 2% soya PNPP 72.3 91.8 91.6 87.5 88.4 IL1 alpha 350 137.5 137.5 212.5 187.5 IL1 alpha/PNPP 484.1 149.8 150.1 242.9 212.1

(66) The results obtained show that the solution of quaternised soya selected previously induces a cytotoxicity and an inflammatory stress which is very limited with respect to the reference molecule PEI.

EXAMPLE 14

Apoptotic Effect Compared Between the Polyethylenimine and the Quaternised Soya Selected

(67) The stimulation of the synthesis of interleukin 1 alpha is compared between liposomes which are functionalised by 50 M PEI and various concentrations in solution of quaternised soya.

(68) Practically, liposomes are formed with 5% of soya lecithin, 0.01% of PFB-F, and 0.5 to 2.5% of the solution of quaternised soya or 50 M of PEI, in Trizma dilution buffer. The content of caspase 1 is evaluated with a kit (Caspase-1 Colorimetric Assay R&D System). A test with paranitrophenylphosphate (PNPP) is carried out in parallel in order to evaluate the number of cells per well. The results of caspase-1 content are compared to the optical density of PNPP obtained. The results obtained are given in Table 14.

(69) TABLE-US-00012 TABLE 14 Effect of the functionalising molecules on the content of caspase-1 Concentration of functionalising molecule 50 M 0.5% 1.5% PEI soya 1% soya soya 2% soya PNPP 59.8 91.8 91.6 87.5 88.5 Caspase-1 642.8 76 87.7 78.3 117.5 Caspase-1/PNPP 1074.9 82.8 95.7 89.5 132.8

(70) The results obtained show that the solution of quaternised soya selected previously induces a cytotoxicity and an apoptotic stress which is excessively limited with respect to the reference molecule PEI.

EXAMPLE 15

Observation of the Structure of the Liposomal Composition of Example 14 by Transmission Electronic Microscopy

(71) The liposomes prepared with 2% of quaternised soya solution, without addition of active principle and of fluorescent tracer, were observed by transmission electronic microscopy. A negative coloration of the liposomes is made by using heavy metal salts which burst between the bilayers of the multilamellar vesicles. The observation is made with a Philips CM120 transmission electronic microscope and an enlargement of 30 to 60,000.

(72) The observation reveals the presence of concentric lipid layers which are characteristic of multilamellar structures. The average size of the liposomes observed varies from 150 to 250 nm.

EXAMPLE 16

Stimulation of the Anti-radical Protection by the Use of a Solution of Quaternised Soya of Example 11

(73) Liposomes are prepared with 5% of soya lecithin, 0.2% of natural vitamin E and 2% of quaternised soya solution of Example 11 (molecule Y).

(74) Practically, 0.4 g of natural vitamin E is added to 10 g of soya lecithin and 10 ml of 96% ethanol. The solution is evaporated for one night under magnetic agitation at ambient temperature and in the absence of light. After evaporation of the ethanol, 100 ml of deionised water are added. The mixture is agitated up to complete dissolution.

(75) The liposomes are then prepared by adding 5 ml of the lecithin-vitamin E solution, 190 l (i.e. 2%) of quaternised soya solution and 4.80 ml of 55 mM Trizma dilution buffer27 mM NaCl adjusted to pH 5 are mixed under magnetic stirring in the absence of light for 30 minutes. The solution is then homogenised at maximum speed for 10 minutes in order to form the modified liposomes. The same solution is prepared without passing to the homogenisation and will serve a free vitamin E control.

(76) The natural vitamin E-based liposomes are prepared in the presence of 10 M 25 kDa PEI, so as to prevent the cytotoxicity and also without functionalising agent.

(77) Normal human fibroblasts are sown in 24-well plates and are cultivated up to confluence. After three rinses with pH 7.4 phosphate buffer with calcium and magnesium (In vitrogen), the various solutions are incubated diluted to the half (i.e. final vitamin E concentration of 0.1%) in culture medium for at least two hours. Wells are incubated with culture medium alone and will serve as probe control in the following. After three rinses in pH 7.4 phosphate buffer with calcium and magnesium so as to remove the liposomes and the free vitamin E, the cell mats are incubated in the presence of Dihydrorhodamine 123 (Molecular Probes) at the rate of 200 l/well of a solution prepared as follows: 150 l of a 1 mM solution dissolved in 15 ml of HBSS buffer. The plate is read for fluorescence at 490-530 nm, and then irradiated at 0.8 J/cm.sup.2 with UVB at 912 nm, and is then read again for fluorescence at the same wavelengths. The results are expressed as ratios: A=irradiated/non-irradiated (I/NI) B=(I/NI liposome)/(I/NI probe control) C=liposomed Vitamin E/free vitamin E.

(78) The fluorescent probe used enables the presence of intracellular reactive oxygen intermediates to be evaluated since it diffuses passively through the cell membranes wherein it can then be oxidised to cationic rhodamine. The fluorescent probe reacts positively for example with hydrogen peroxide and peroxynitrites. The results obtained are given in Table 15.

(79) TABLE-US-00013 TABLE 15 Anti-radical protection by the thus-modified liposomes B = A = liposome/ C = I NI I/NI control liposome/free Product of the 118990 58786 2.01 79.3% +23% invention Non- 114907 52306 2.31 91.1% +11% functionalised liposome Liposome PEI 105257 40148 2.82 111.4% 9%

(80) These results indicate that the liposomes functionalised by the quaternised soya protein enable obtaining more than 20% of protective effect against radical stress with respect to non-functionalised liposomes, whereas the liposomes functionalised with the reference molecule PEI do not enable a protective effect to be observed on the one hand, they even generate an additional stress.

EXAMPLE 17

Stimulation of Depigmentation by the Products of the Invention

(81) Liposomes were prepared according to the following protocol: 5% of soya lecithin to which 2% of quaternised soya solution or 10 M PEI is added or not. Actives are also co-encapsulated: Phytolight (Coletica, Lyons, France) without 0.05% preservative (cocktail of plant actives), 0.05% arbutine and 1 mM catechin (Sigma). The molecules were applied free, in 5% lecithin liposome, in 10 M PEI functionalised liposomes or 2% quaternised soya, on normal human melanocytes cultivated in 24-well plates and pre-confluent. The actives which are liposomed or not are incubated for 66 hours at 37 C. under 5% CO.sub.2 in MMK2 medium (Sigma). After 3 rinses with phosphate buffer with calcium and magnesium (Invitrogen), extraction into phosphate buffer containing 0.5% triton X-100, the tyrosinase activity is quantified by a determination in the presence of L-DOPA and MBTH (3-methyl-2-benzothiazolinone hydrazone). The formation of a MBTH-o-quinone compound is characterised by an absorbance value at 490 nm quantified kinetically. The tyrosinase activity is expressed by the slope (rate) of the enzymatic reaction. The results are given in Table 16.

(82) TABLE-US-00014 TABLE 16 Depigmenting effect of liposomed or non-liposomed actives (expressed in rate of enzymatic reaction) Free Lipsosome PEI Liposome Soya liposome Arbutin 0.004 0.001 0 0 Phytolight 0.01 0.008 0.003 0.0016 Catechin 0.007 0.007 0 0.003

(83) These results show that as a function of the actives co-encapsulated, the functionalisation enables an increase in the inhibition of the tyrosinase activity in vitro on normal human melanocytes. The functionalisation by the quaternised soya is more effective than that obtained by addition of PEI for the complex of plant extracts, equivalent for arbutin and slightly less for catechin. In every case, the activity is at least 2.3 times greater than with a non-functionalised liposome.

EXAMPLE 18

Method of Decreasing the Size of the Products of the Invention

(84) The size of the liposomes can be decreased by use of a high pressure homogeniser (working pressure of greater than 1,000 bars, preferably greater than 2,000 bars, more preferably greater than 3,000 bars). At 3,000 bars, this instrument enables liposomes of about 50 nm to be obtained.

(85) The size of the liposomes was analysed with the aid of a laser particle size analyser (Beckman Coulter, N4 plus, Submicron Particle Size Analyser) and by transmission electronic microscopy, as described in Example 15.

EXAMPLE 19

Demonstration of the Penetration of Material which is Carried by the Products of the Invention after Transcutaneous Permeation: Examples with a Fluorescent Tracer, Vitamin E or Genetic Material

(86) The penetration of fluorescent molecule (0.01% PFP-F), free or incorporated in a liposome as described in Example 12, comprising or not comprising 2% quaternised soya solution selected in Example 11, was quantified by transcutaneous permeation on human skin. The diffusion kinetics were quantified by spectrofluorimetry from 3 to 24 hours. The release was quantified after 24 additional hours. The storage was also evaluated last. The number of samples tested is 5 per condition. The results obtained given in Table 17 show that the use of liposomes prepared in the presence of quaternised soya significantly stimulate the diffusion, the release and the storage of the fluorescent tracer with respect to the non-vectorised form or form vectorised without quaternised agent.

(87) TABLE-US-00015 TABLE 17 Quaternised Free Liposome liposome Diffusion 0.57 0.03 1.17 0.05 1.76 0.13 Release 24 h 0.691 0.06 1.398 0.07 1.77 0.21 Storage 0.81 0.1 1.27 0.17 2.61 0.33

(88) The penetration of vitamin E molecule (0.5%), free or incorporated in a liposome as described in Example 12, comprising or not 2% quaternised soya solution selected in Example 11, was quantified by transcutaneous permeation on human skin. The diffusion kinetics were quantified by high performance liquid chromatography from 5 to 24 hours. The release was quantified after 24 additional hours. The storage was also evaluate last. The results obtained also show that the use of liposomes prepared in the presence of quaternised soya significantly stimulates the diffusion, the release and the storage of the vitamin E with respect to the non-vectorised form or form vectorised without quaternised agent.

(89) The same experiment of transcutaneous penetration was carried out with the incorporation or not of fluorescent genetic material (200 mM) in a liposome as described in Example 12 in the presence of a 2% soya solution. The results obtained by observation by epifluorescence optical microscopy of transverse sections of the skin show that the use of liposomes prepared in the presence of quaternised soya enable the diffusion of the genetic material to the deep dermis.

(90) Sequence of the fluorescent probe of duplexed elastin 19-20:

(91) TABLE-US-00016 Sense: 5-(FITC) AGCUGCUAAGGCUGGCGCUTT-3 anti-sense: 5-AGCGCCAGCCUUAGCAGCUTT-3

EXAMPLE 20

Use of the Products of the Invention in Oil-in-water Emulsion Type Cosmetic or Pharmaceutical Formulations

(92) Formulation 20a

(93) TABLE-US-00017 A Water qsp 100 Butylene Glycol 2 Glycerine 3 Sodium Dihydroxycetyl 2 Phosphate, Isopropyl Hydroxycetyl Ether B Glycol Stearate SE 14 Triisononaoin 5 Octyl Cocoate 6 C Butylene Glycol, 2 Methylparaben, Ethylparaben, Propylparaben, pH adjusted to 5.5 D Products of the invention 0.0110%
Formulation 20b:

(94) TABLE-US-00018 A Water qsp 100 Butylene Glycol 2 Glycerine 3 Polyacrylamide, Isoparaffin, 2.8 Laureth-7 B Butylene Glycol, 2 Methylparaben, Ethylparaben, Propylparaben; Butylparaben, Phenoxyethanol, C Products of the invention 0.0110%
Formulation 20c:

(95) TABLE-US-00019 A Carbomer 0.50 Propylene Glycol 3 Glycerol 5 Water qsp 100 B Octyl Cocoate 5 Bisabolol 0.30 Dimethicone 0.30 C Sodium Hydroxide 1.60 D Phenoxyethanol, 0.50 Methylparaben, Propylparaben, Butylparaben, Ethylparaben E Perfume 0.30 F Products of the invention 0.0110%

(96) These formulations 20a, 20b and 20c are manufactured as usual, namely, each group of components A, B, etc. is homogenized separately and then the following group of components is admixed therewith. Thus, group of components B is admixed with component A, afterwards, group of components C is added to the mixture of components A plus B, and so on, as is well understood by those skilled in the art to which the invention pertains.

(97) This procedure is also applied for any other similar invention's examples like those set forth here below.

EXAMPLE 21

Use of the Products of the Invention in a Water-in-oil Type Formulation

(98) TABLE-US-00020 A PEG 30 - 3 dipolyhydroxystearate Capric Triglycerides 3 Cetearyl Octanoate 4 Dibutyl Adipate 3 Grape Seed Oil 1.5 Jojoba Oil 1.5 Phenoxyethanol, 0.5 Methylparaben, Propylparaben, Butylparaben, Ethylparaben B Glycerine 3 Butylene Glycol 3 Magnesium Sulfate 0.5 EDTA 0.05 Water qsp 100 C Cyclomethicone 1 Dimethicone 1 D Perfume 0.3 E Products of the invention 0.0110%

EXAMPLE 22

Use of the Products of the Invention in a Triple Emulsion Type Formulation

(99) TABLE-US-00021 Primary emulsion W1/O A PEG 30 - 4 dipolyhydroxystearate Capric Triglycerides 7.5 Isohexadecane 15 PPG-15 Stearyl ether 7.5 B Water 65.3 C Phenoxyethanol, 0.7 Methylparaben, Propylparaben, Butylparaben, Ethylparaben Secondary emulsion W1/O/W2 A Primary emulsion 60 B Poloxamer 407 2 Phenoxyethanol, 0.3 Methylparaben, Propylparaben, 2-bromo- 2nitropropane-1,3 diol Water qsp 100 C Carbomer 15 D Triethanolamine PH 6.06.5 E Products of the invention 0.0110%

EXAMPLE 23

Use of the Products of the Invention in a Formulation of Lipstick Type and Other Anhydrous Products

(100) TABLE-US-00022 A Mineral Wax 17.0 Isostearyl Isostearate 31.5 Propylene Glycol Dipelargonate 2.6 Propylene Glycol Isostearate 1.7 PEG 8 Beeswax 3.0 Hydrogenated Palm Kernel Oil 3.4 Glycerides, Hydrogenated Palm Glycerides Lanolin Oil 3.4 Sesame Oil 1.7 Cetyl Lactate 1.7 Mineral Oil, Lanolin Alcohol 3.0 B Castor Oil qsp 100 Titanium Dioxide 3.9 CI 15850: 1 0.616 CI 45410: 1 0.256 CI 19140: 1 0.048 CI 77491 2.048 C Products of the invention 0.015%

EXAMPLE 24

Use of the Products of the Invention in a Formulation of Aqueous Gels (Eyeliners, Slimmers, etc.)

(101) TABLE-US-00023 A Water qsp 100 Carbomer 0.5 Butylene Glycol 15 Phenoxyethanol, Methylparaben, 0.5 Propylparaben, Butylparaben, Ethylparaben B Products of the invention 0.0110%

EXAMPLE 25

Preparation of Pharmaceutical Formulations Containing the Product of the Invention

(102) Formulation 25a: Preparation of Tablets

(103) TABLE-US-00024 A Excipients in g per tablet Lactose 0.359 Sucrose 0.240 B Product of the invention 0.0010.1
Formulation 25b: Preparation of an Ointment

(104) TABLE-US-00025 A Excipients Low density polyethylene 5.5 Liquid paraffin qsp 100 B Product of the invention 0.0010.1
Formulation 25c: Preparation of an Injectable Formula

(105) TABLE-US-00026 A Excipient Saline isotonic solution 5 ml B Product of the invention 0.0010.1 g

(106) Phase A and phase B are packaged in separate ampoules and are mixed prior to use.

EXAMPLE 26

Evaluation of the Cosmetic Acceptation of the Products of the Invention

(107) Toxicology tests were carried out on the compounds obtained according to Example 15 (without incorporation of active principle), by a skin and ocular evaluation in the rabbit, by the study of the absence of abnormal toxicity by single oral administration in the rat and by the study of the sensitising power in the guinea pig.

(108) Evaluation of the Primary Irritation of the Skin in the Rabbit:

(109) The preparations described above were applied without dilution at the dose of 0.5 ml on the skin of 3 rabbits according to the method recommended by the OECD in relation to the study of the acute irritant/corrosive effect on the skin.

(110) The products are classed according to the criteria defined in the Decision of Jan. 2, 1982 published in the Official Journal of the French Republic (the JORF) of Feb. 21, 1982.

(111) The results of these tests have enabled concluding that the preparation containing the compound obtained according to Example 12 was non-irritant for the skin.

(112) Evaluation of the Ocular Irritation in the Rabbit:

(113) The preparations described above were instilled pure and in one batch at the rate of 0.1 ml in the eye of three rabbits according to the method recommended by the directive of the OECD NO. 405 of Feb. 24, 1987, in relation to the study of the acute irritant/corrosive effect on the eyes.

(114) The results of this test enable concluding that the preparations can be considered as non-irritant for the eyes.

(115) Test on the Absence of Abnormal Toxicity by Single Oral Administration in the Rat:

(116) The preparations described were administered in one batch orally at the dose of 5 g/Kg of body weight, to 5 male rats and 5 female rats according to a protocol inspired from the Directive of the OECD No. 401 of Feb. 24, 1987 and adapted to cosmetic products.

(117) The LD0 and LD50 are found to be greater than 5,000 mg/Kg. The preparations tested are therefore not classed amongst the preparations which are dangerous by ingestion.

(118) Evaluation of the Skin Sensitisation Potential in the Guinea Pig:

(119) The preparations described are subjected to the maximization test described by Magnusson and Kligmann, a protocol which is in agreement with the directive line No. 406 of the OECD. The preparations are classed as non-sensitising by contact with the skin.

(120) Evaluation of the Mutagenicity Potential:

(121) The protocol is in accordance with the directive line of the OECD No. 471 (Directive 92/69/EEC).

(122) The mutagenesis tests were carried out on <<Salmonella typhimurium>> and on <<Escherichia coli>> according to the method of Ames et al. (Mutation Research, 1975, 31, 347-364). Five strains were exposed to the product of the invention in minimum medium, with or without exogenous systems of metabolism activation (so as to distinguish pro-mutagens and mutagens directly). After incubation, the mutated colonies were counted and were compared to the number of colonies spontaneously mutated amongst the controls.

(123) The product of the invention does not possess any mutagenic activity in the sense of Directive 92/69 EEC.

(124) Evaluation of the Sensitisation Potential on Healthy Volunteers:

(125) Evaluation on a panel of volunteers of the allergising potential of the product of the invention. The protocol is in accordance with the method of Marzulli and Maibach (Contact Dermatitis, 1976, 2, 1-17) which comprises an induction phase and a triggering test. This test is made on a panel of 100 healthy volunteers of feminine and/or masculine sex, aged between 18 and 65 and having any skin type.

(126) An occlusive patch containing the product of the invention diluted to 20% was applied on the scapular zone of each one of the volunteers. The patches were left in direct contact with the skin for 24 hours and were reapplied every two days for 3 weeks for a total of 9 applications. After the removal of each patch, the clinical signs of irritation and of the skin sensitisation were evaluated=Induction Phase.

(127) After a period of 2 weeks, other patches containing the product of the invention diluted to 20% were applied on the skin of the volunteers and were left in direct contact with the skin surface for 24 hours. The clinical signs of the irritation and of the skin sensitisation were evaluated 24, 48 and 72 hours after the removal of the patch=Challenge Phase.

(128) None of the 100 volunteers involved in the study presented clinical signs of irritation or of skin sensitisation, whether it be during the induction phase or the challenge phase.

(129) Under the experimental conditions retained, the product of the invention diluted to 20% is devoid of allergising potential.

(130) TABLE-US-00027 TABLE 1 Selection of fluorescent probes as tracers Penetration Probe name Chracteristics Exc/Em Concentration Encapsulated leak cell-permeating Toxicity in liposome Retained #L7545L Lysosensor pH sensitive 329/440 10 M Yes Yes Yes No No No yellow/blue DND 160 #H-348 hydroxypyrene 403/511 1 mM No NT No NT No No trisulfonic acid, trisodium salt #P-12925 492/516 200 M Yes No No Yes Yes pentafluorobenzoylamino fluorescein #F-1200 Fura-2. Sensitive to Ca.sup.2+ 335/505 10 M No No No No Yes pentapotassium salt #C-369 carboxy Fluoresces if 85 M Yes Yes Yes NT NT No dichlorofluorescein esterases #B-1151 carboxyethyl 482/520 50 M No NT ? NT NT No carboxyffluorescein #T-490 555/580 Yes ? ? No Yes No Interferes tetramethylrhodamine with PEI isothiocyanate TRITC #C-687 cascade blue 399/421 200 M Yes NT No No Very low No hydrazine trisodium salt #S-1129 sulfo fluorescein 200 M NT NT no No Very low No diacetate #D-3329 dextran texas red 592/609 NT NT No Yes No No

(131) TABLE-US-00028 Annex 2: Results of screening of molecules which stimulate the penetration (Table 8) Stimulation INCI name factor Viability Visualisation Polyethylenimine 25 kDa 34.7 74.1 + Cocodimonium hydroxypropyl 4.3 86 hydrolyzed wheat protein Cocodimonium hydroxypropyl 18 85 hydrolyzed rice protein Steardimonium hydroxypropyl 4.6 86.4 hydrolyzed wheat protein Lauryldimonium hydroxypropyl 6.2 87.5 hydrolyzed wheat protein Hydroxypropyltrimonium 1.3 91.7 hydrolyzed wheat protein Hydroxypropyltrimonium honey 15 92 Sodium lauroyl Oat amino acids 0.8 76.6 Sodium lauroyl wheat amino 1.1 46.1 acids Cocoamine 32.7 79.7 + Lauryldimonium hydroxypropyl 38.8 87.9 + hydrolyzed soya protein Chitosan 10.3 99 Hydroxypropyl guar 1.1 74.8 hydroxypropyltrimonium chloride Hydroxypropyl guar 0.2 91.1 Hydroxypropyl guar 0.4 97.5 Hydroxypropyl guar 1.4 71.2 hydroxypropyltrimonium chloride Guar hydroxypropyltrimonium 0.6 53.3 Meypro 1 91.6 Polyquaternium 7 0.3 80.1 Polyvinylpyrrolidone (1) 1.4 85.1 polyvinylcaprolactam 4.1 0 Polyvinylpyrrolidone (2) 0.7 26.6 Polyvinylpyrrolidone (3) 0.7 71 Polyquaternium 16 (1) 4.6 83.5 Polyquaternium 11 (1) 1.5 49.7 Cocotrimonium methosulfate 0.1 55 Polyquaternium 16 (2) 8.4 33.8 Polyquaternium 16 (3) 1 38.8 Polyquaternium 16 (4) 12.5 67.1 Polyquaternium 16 (5) 0.2 85.3 Polyquaternium 44 0.8 59.7 Cocoalkonium chloride 5.6 36.3 Cocotrimonium chloride 0.2 65.6 Tetrahydroxypropyl 1.9 95.3 ethylenediamine Stearamidopropyl cetearyl 13.1 93.2 dimonium tosylate and PG Quaternium 70 and PG 0.2 63.9 Quaternium 26 30.9 59.2 Quaternium 22 2 98.9 Polyquaternium 28 0.6 79.3 Polyquaternium 11 (2) 2.9 50.7 Polyquaternium 11 (3) 2.9 77.1 Polyquaternium 2 4.2 23.6 Stearalkonium chloride 17.6 37.4 Propylamine C3 0.9 103.3 n-Butylamine C4 1.4 106.2 Dibutylamine 2 C4 0.7 75.7 Hexylamine C6 0.2 82.1 Heptylamine C7 3.7 39.4 Dioctylamine 2 C8 1 34.7 Decylamine C10 39.6 68.5 + Didecylamine 2 C10 1.2 28.3 Undecylamine C11 95.3 84 + Dodecylamine C12 47.1 57 + Tridecylamine C13 44.5 62.6 + Tetradecylamine C14 11.6 54.8 Pentadecylamine C15 14.9 73 Octadecylamine C18 19.6 61.2 Oleylamine C18:1 1.9 87.1