Use of oligosaccharide compounds for the prevention and treatment of pathological scars

Abstract

The present invention relates to a compound selected among the synthetic polysulphated oligosaccharides having 1 to 4 ose units and the salts and complexes thereof to be used for the treatment of wounds resulting in pathological scars selected among hypertrophic, retractile or atrophic scars. Said use is preferred in particular in patients that have a predisposition to developing hypertrophic, retractile or atrophic scars. According to a second aspect, the invention also relates to said compound for the use thereof in order to inhibit the differentiation of fibroblasts into myofibroblasts during the cicatrisation of wounds resulting in pathological scars selected among hypertrophic, retractile or atrophic scars.

Claims

1. A method for treating wounds resulting in pathological scars by inhibiting the differentiation of fibroblasts into myofibroblasts, said method comprising applying to said wounds a compound chosen from synthetic polysulfated oligosaccharides having 1 to 4 monosaccharide units, the salts thereof, or the complexes thereof, wherein the pathological scars are chosen from hypertrophic or retractile scars.

2. The method as claimed in claim 1, wherein the compound is chosen from synthetic polysulfated oligosaccharides having 1 or 2 monosaccharide units, and also the salts and complexes of these compounds.

3. The method as claimed in claim 1, wherein the compound is chosen from: the potassium salt of sucrose octasulfate; the silver salt of sucrose octasulfate; and the hydroxyaluminum complex of sucrose octasulfate.

4. The method as claimed in claim 1, wherein the compound is combined with one or more other active substances chosen from antibacterials, antiseptics, painkillers, anti-inflammatories, active agents which promote healing, depigmenting agents, antipruritics, UV-screening agents, calmatives, moisturizing agents and antioxidants, and mixtures thereof.

5. The method as claimed in claim 4, characterized in that the other active substance is chosen from antioxidants.

6. The method as claimed in claim 1, wherein the compound is present in a galenic formulation selected from the group consisting of a gel, a solution, an emulsion, a cream, granules or capsules allowing application directly to the wound.

7. The method as claimed in claim 1, wherein the compound, or a galenic formulation containing it, is integrated into a component of a dressing.

8. The method as claimed in claim 7, wherein said dressing is a nonwoven dressing, combined with an additional absorbent layer.

9. The method as claimed in claim 7, wherein said dressing is a dressing comprising a nonwoven, combined with an additional absorbent layer.

10. The method as claimed in claim 7, wherein the dressing comprises a hydrocolloid adhesive and in that said polysulfated oligosaccharide is incorporated into said adhesive.

11. The method as claimed in claim 1 for treating wounds in a subject who has a predisposition to developing hypertrophic or retractile scars.

Description

DESCRIPTION OF THE FIGURES

(1) FIG. 1 illustrates the effect of the potassium salt of sucrose octasulfate KSOS on the differentiation of fibroblasts into myofibroblasts.

(2) In particular, FIG. 1 (A) shows the expression of the -SMA messenger RNA by quantitative RT-PCR under 4 conditions (nondifferentiated control without TGF-, differentiated control with TGF-, nondifferentiated control without TGF- but with KSOS, and differentiated control with TGF- and KSOS).

(3) FIG. 1 (B) shows the -SMA protein expression by the Western blot method.

(4) FIG. 1 (C) shows the -SMA protein expression visualized by immunofluorescence.

(5) FIG. 1 (D) illustrates the percentages of differentiated cells expressing -SMA.

(6) FIG. 2 illustrates, by means of photographs of the collagen lattices on D1 and D7 under the various conditions, the collagen lattice contraction-inhibiting effect of the Urgotul Start dressing containing the potassium salt of sucrose octasulfate (KSOS) after 1 and 7 days of culture.

PATHOLOGICAL SCARS

(7) The present invention is concerned with wounds which create 3 types of pathological scars: hypertrophic scars, retractile scars and atrophic scars.

(8) Hypertrophic or retractile scars have as common origin an initial hyperplastic phase of high intensity and/or lengthy duration, which phase causes an excess of dense fibrous tissue in the non-reorganized dermis. These pathological scars are large, swollen, red and hard and cause itching. They are characterized by an increased deposition of dermal collagen, which comes from the damaged deep layer of the epidermis, of proteoglycans and of fibronectin and tissue water under the epithelium.

(9) Hypertrophic or retractile scars often form after a burn, but can also develop after a deep injury (surgical incision, for example). They remain confined within the limits of the original wound. Microscopically, they exhibit thin collagen fibers and myofibroblasts expressing -smooth muscle actin in large amounts. The retractions observed in hypertrophic or retractile scars are caused by the contractile activity of myofibroblasts. Thus, myofibroblasts are responsible for the disorganization of the collagen bundles in the deep layer of the dermis. Indeed, collagen bundles are normally flat, but, under the effect of the contraction of the myofibroblasts, they take on a coiled shape which leads to the formation of collagen nodules under the epithelium.

(10) Hypertrophic scars, when they are located at the level of a joint (bending fold) or of a line of tension, can, like retractile scars, result in incapacitating retractions. They are more abundantly vascularized than normal skin, and the vessels are more dilated. After an active phase, which can last one to two years, hypertrophic scars may gradually regress, but they only rarely disappear completely.

(11) Retractile scars are nonfunctional scars in the sense that they limit the functionality of the area on which they occur. They result in a loss of mobility of the area of healing and of the adjacent areas, which can completely limit movements (for example elbow and mobility of the arm).

(12) Atrophic scars are located under the level of the surrounding skin. They form small hollows and appear when too few new connective tissue fibers are produced during the healing process. Severe-acne scars or chickenpox scars are typical examples of atrophic scars. For the purpose of the present invention, the term severe-acne scars is intended to mean acne scars which are the result of lesions which reach the layers of the dermis and not only the epidermis. Severe-acne scars are most commonly the result of forms of acne such as nodular acne, acne fulminans, or acne conglobata which cause inflammatory lesions, such as hardened furunculosis-like nodules having a diameter greater than 5 mm (nodular acne) which can progress to fistulae (acne conglobata). Severe-acne scars can take very varied forms. The first form, termed crater, corresponds to wide round scars, with a depression simulating a flat-bottomed crater. Ice pick acne scars, which are small and often deeper than the crater scars, give the impression that the skin has been pricked with a pointed instrument. They are the scars which are the most difficult to treat. These scars are the seat of a fibrosis which makes the scar rigid and hampers the usual treatments.

(13) There are a number of factors which promote the appearance of pathological scars; among the risk factors for pathological scar formation, mention may be made of: complexion: populations with a dark complexion (of North African or African origin) are much more prone to hypertrophic scars than Caucasian populations. Subjects with a very pale complexion also have, moreover, a tendency to develop hypertrophic scars; age: hypertrophic scars are frequent in children, but are rare in elderly subjects; hormones: some times of life, associated with strong bursts of hormones (puberty, pregnancy), are also more favorable to the development of abnormal scars and to acne scars; location on the body: some parts of the body are more prone to developing pathological scars, such as, for example, areas where there are folds, joint areas, areas of tension (such as the elbow, the shoulder, the thorax), the sternum, the neck, the ears or the face; infectious pathologies which create atrophic scars (chickenpox, severe acne).

(14) For the purpose of the present application, the wounds resulting in pathological scars are defined as wounds which reach the dermis, preferably wounds which reach the reticular dermis (also called deep dermis). Thus, the wounds resulting in pathological scars can be defined as wounds having a depth greater than 0.30 mm, more preferentially greater than 0.35 mm and even more preferentially greater than 0.40 mm.

(15) For the purpose of the present application, the wounds resulting in pathological scars can also be defined as being wounds located on certain parts of the body, for instance areas where there are folds, joint areas, areas of tension (such as the elbow, the shoulder, the thorax), the sternum, the neck, the ears or the face.

(16) For the purpose of the present application, the wounds resulting in pathological scars can also be defined as open wounds occurring in subjects who have a predisposition to developing hypertrophic scars, retractile scars or atrophic scars, such as, for example, subjects who have a dark or very pale complexion, children, pubescent adolescents or pregnant women.

(17) The particular oligosaccharide compound according to the invention is therefore of quite particular interest for the treatment of wounds in subjects who have a predisposition to developing hypertrophic or retractile or atrophic scars, such as subjects who have a dark or very pale complexion, children, pubescent adolescents or pregnant women.

(18) Synthetic Polysulfated Oligosaccharides Having 1 to 4 Monosaccharide Units

(19) The oligosaccharides used in the context of the present invention are synthetic oligomers made up of 1 to 4 monosaccharide units, and preferably of 1 or 2 monosaccharide units, generally linked to one another via an alpha or beta glycosidic bond. In other words, they are mono-, di-, tri- or tetrasaccharides, and preferably monosaccharides or disaccharides.

(20) There is no particular limitation regarding the nature of the monosaccharide units of these polysaccharides. They will preferably be pentoses or hexoses. By way of example of monosaccharides, mention may be made of glucose, galactose or mannose. By way of example of disaccharides, mention may be made of maltose, lactose, sucrose or trehalose. By way of example of a trisaccharide, mention may be made of melezitose. By way of example of a tetrasaccharide, mention may be made of stachyose.

(21) The oligosaccharide is preferably a disaccharide, and more preferably sucrose.

(22) For the purpose of the present application, the term polysulfated oligosaccharide is intended to mean an oligosaccharide of which at least two, and preferably all, of the hydroxyl groups of each monosaccharide have been substituted with a sulfate group.

(23) The polysulfated oligosaccharide used in the context of the present application is preferably sucrose octasulfate.

(24) The polysulfated oligosaccharides used in the context of the present invention can be in the form of salts or complexes.

(25) By way of example of salts, mention may be made of the alkali metal salts, such as the sodium, calcium or potassium salts; the silver salts; or else the amino acid salts.

(26) By way of example of complexes, mention may be made of the hydroxyaluminum complexes.

(27) In the context of the present invention, compounds which are particularly preferred are the following: the potassium salt of sucrose octasulfate; the silver salt of sucrose octasulfate; and the hydroxyaluminum complex of sucrose octasulfate, commonly called sucralfate.

(28) In particular, in the context of the present invention, the polysulfated oligosaccharides used are preferably the potassium salts rather than the aluminum salts of sucrose octasulfate.

(29) The polysulfated oligosaccharides used in the context of the present invention can be in the form of a micronized powder or in solubilized form.

(30) An example of a polysulfated oligosaccharide used in the context of the present invention is the potassium salt of sucrose octasulfate (known under the abbreviation KSOS), sold in the product Urgotul Start by Laboratoires URGO.

(31) Additional Active Substance

(32) Generally, the oligosaccharide compounds according to the invention may be used alone or as a mixture of two or more of them, or else in combination with one (or more) other active substance(s).

(33) Generally, the active agents are chosen from antibacterials, antiseptics, painkillers, anti-inflammatories, active agents promoting healing, depigmenting agents, antipruritics, UV-screening agents, calmatives, moisturizing agents and antioxidants, and mixtures thereof.

(34) Generally, the active agents are chosen from: antibacterials, such as polymyxin B, penicillins (amoxicillin), clavulanic acid, tetracyclines, minocycline, chlortetracycline, aminoglycosides, amikacin, gentamicin, neomycin, silver and salts thereof (silver sulfadiazine), probiotics, silver salts; antiseptics, such as thiomersal, eosin, chlorhexidine, phenylmercuric borate, aqueous hydrogen peroxide solution, Dakin's solution, triclosan, biguanide, hexamidine, thymol, Lugol's solution, iodinated povidone, merbromin, benzalkonium chloride, benzethonium chloride, ethanol or isopropanol; painkillers, such as paracetamol, codeine, dextropropoxyphene, tramadol, morphine and its derivatives, or corticoids and derivatives; anti-inflammatories, such as glucocorticoids, nonsteroidal anti-inflammatories, aspirin, ibuprofen, ketoprofen, flurbiprofen, diclofenac, aceclofenac, ketorolac, meloxicam, piroxicam, tenoxicam, naproxen, indomethacin, naproxcinod, nimesulide, celecoxib, etoricoxib, parecoxib, rofecoxib, valdecoxib, phenylbutazone, niflumic acid or mefenamic acid; active agents which promote healing, such as retinol, vitamin A, vitamin E, N-acetylhydroxyproline, Centella asiatica extracts, papain, silicones, essential oils of thyme, of niaouli, of rosemary and of sage, hyaluronic acid, metformin, allantoin, Hema'tte (Gattefosse), vitamin C, Tego Pep 4-17 (Evonik), Toniskin (Silab), Collageneer (Expanscience), Timecode (Seppic), Gatuline skin repair (Gattefosse), panthenol, PhytoCellTec Alp Rose (Mibelle Biochemistry), Erasyal (Libragen), Serilesine (Lipotec), Heterosides of Talapetraka (Bayer), Stoechiol (Codif), macarose (Sensient), Dermaveil (Ichimaru Pharcos), phycosaccharide AI (Codif) or metformin; depigmenting agents, such as kojic acid (Kojic Acid SLQuimasso (Sino Lion)), arbutin (OlevatinQuimasso (Sino Lion)), the mixture of sodium palmitoylproline and of European water lily extract (SepicalmSeppic) or undecylenoylphenylalanine (SepiwhiteSeppic), antipruritics: hydrocortisone, enoxolone, diphenhydramine, locally applied anti H1 antihistamine, moisturizing active agents, such as Xpermoist (Lipotec), hyaluronic acid, urea, fatty acids, glycerol, waxes or Exossine (Unipex), UV-screening agents, such as Parsol MCX or Parsol 1789, calmatives, such as camomile, bisabolol, Zanthalene, glycyrrhetenic acid, tanactin (CPN) or Calmiskin (Silab), antioxidants, such as vitamin E.
According to one preferred embodiment, the oligosaccharide compounds according to the invention may be used in combination with an antioxidant.

(35) Galenic Form

(36) The compounds used in the context of the present invention may be employed in a galenic formulation, for instance a gel, a solution, an emulsion, a cream, granules or capsules of variable size ranging from a nanometer or micrometer to a millimeter, which will allow them to be applied directly to the wound. Alternatively, the compounds used in the context of the present invention may be employed in a solution for subcutaneous injection.

(37) If they are employed as a mixture of two or more of them or alternatively in combination with one or more other active substances, these compounds may be incorporated into the same galenic formulation or into distinct galenic formulations.

(38) Of course, the amount of synthetic polysulfated oligosaccharides according to the invention used in the galenic formulation is adjusted according to the desired kinetics and also the specific constraints linked to its nature, solubility, heat resistance, etc.

(39) Generally, when it is used in a galenic formulation, the synthetic polysulfated oligosaccharide compound according to the invention may be incorporated in a content of between 0.1 and 50% by weight relative to the total weight of the formulation.

(40) Dressing

(41) Preferentially, the synthetic polysulfated oligosaccharide compounds used in the context of the present invention, or a galenic formulation containing them, will be integrated into a dressing.

(42) The synthetic polysulfated oligosaccharide compounds, and in particular the potassium salt of sucrose octasulfate or a galenic formulation containing it, may be incorporated into any component of the structure of a dressing with the proviso that this compound can directly or indirectly come into contact with the surface of the wound.

(43) Preferably and in order to promote a rapid action, this compound (or a galenic formulation containing it) will be incorporated into the layer of the dressing which comes into contact with the wound or deposited on the surface of the dressing which comes into contact with the wound.

(44) Advantageously, the potassium salt of sucrose octasulfate (or a galenic formulation containing it) may thus be continuously or discontinuously deposited onto the surface intended to come into contact with the wound: either in liquid form, for example by spraying a solution or suspension containing it; or in solid form, for example by sieving a powder containing it.

(45) The layer or surface which comes into contact with the wound may consist, for example, of an absorbent material such as a hydrophilic absorbent polyurethane foam; a textile material such as a compress, for example a nonwoven, a film, a web of fibers; an absorbent or nonabsorbent adhesive material; an adherent or non-adherent interface structure.

(46) Generally, it will be possible to adjust the galenic form or the structure of the dressing in order to obtain a rapid or delayed specific release profile for the potassium salt of sucrose octasulfate, as required.

(47) Of course, the amount of potassium salt of sucrose octasulfate used in the galenic formulation or in the dressing will be adjusted according to the desired kinetics and also the specific constraints linked to its nature, solubility, heat resistance, etc.

(48) For the purpose of the present application, the term dressing is intended to denote any type of dressing used for the treatment of wounds.

(49) Typically, a dressing comprises at least one adhesive or non-adhesive layer or matrix.

(50) The synthetic polysulfated oligosaccharide compounds according to the invention, or a galenic formulation containing them, can be incorporated into any component of the structure of a dressing, for example into the matrix.

(51) Preferably, and in order to promote a rapid action, this compound (or a galenic formulation containing it) can be incorporated into the layer of the dressing which comes into contact with the wound or deposited onto the surface of the layer of the dressing which comes into contact with the wound.

(52) Such depositing techniques are well known to those skilled in the art and some are, for example, described in patent application WO 2006/007814.

(53) In the context of its use in a component of a dressing, the synthetic polysulfated oligosaccharide(s) according to the invention will be incorporated in an amount such that the amount of polysulfated oligosaccharides that is released into the wound exudates is between 0.001 g/l and 50 g/l, and preferably between 0.01 and 10 g/l.

(54) According to one variant of the invention, the synthetic polysulfated oligosaccharide compound according to the invention can be incorporated into an absorbent dressing based on gelling fibers, for instance the product Aquacel sold by the company Convatec.

(55) Very often, when these dressings are applied, the care staff keep them in place using a bandage or cover them with a secondary component such as a second absorbent dressing or a support bandage. It is therefore useful for the dressing to remain secured to the wound so that the hands of care staff remain free to position these secondary components. Generally, any type of adhesive commonly employed in dressings may be used for this purpose.

(56) In order not to alter the healthy tissues or the edges of the wound, in particular during the removal of the dressing, an adhesive which has the property of adhering to the skin without adhering to the wound will be preferred.

(57) By way of example of such an adhesive, mention may thus be made of adhesives based on silicone or polyurethane elastomers, such as silicone or polyurethane gels, and hydrocolloid adhesives.

(58) Such hydrocolloid adhesives in particular consist of an elastomeric matrix based on one or more elastomers chosen from poly(styrene-olefin-styrene) block polymers in combination with one or more compounds chosen from plasticizers, such as mineral oils, tackifying resins and, if necessary, antioxidants, into which matrix is incorporated a preferably low amount of hydrocolloids (from 3% to 20% by weight), for instance sodium carboxymethylcellulose or superabsorbent polymers such as the products sold under the name Luquasorb by the company BASF.

(59) According to one preferred embodiment, the synthetic polysulfated oligosaccharide compounds used in the context of the present invention, or a galenic formulation containing them, will be integrated into a dressing comprising a hydrocolloid adhesive, said polysulfated oligosaccharide being incorporated into said adhesive preferably in an amount of between 1% and 15% by weight, more preferably between 5% and 10% by weight, relative to the weight of the adhesive.

(60) The formulation of such hydrocolloid adhesives is well known to those skilled in the art and is described, for example, in patent applications FR 2 783 412, FR 2 392 076 and FR 2 495 473.

(61) The use of an adhesive net on the nonwoven makes it possible particularly advantageously to decrease or avoid the risk of small fibrils of the textile material coming into contact with the wound and attaching to the tissues, thus causing a painful sensation upon removal, or even an obstacle to the wound healing process. It also makes it possible to better regulate the flow of liquid at the level of the textile material and to reduce or eliminate the risks of gel blocking, resulting from the use of superabsorbent fibers, which in fact limit the absorption capacity of the nonwoven.

(62) According to one preferred embodiment variant of the present invention, the synthetic polysulfated oligosaccharide compound according to the invention is incorporated into such an adhesive at a concentration compatible with its solubility and its heat resistance.

(63) On the basis of these criteria, the synthetic polysulfated oligosaccharide compound according to the invention is preferably used in an amount of between 1% and 15% by weight, and more preferably between 5% and 10% by weight, relative to the total weight of the adhesive.

(64) If it is desired to increase the absorption of this nonwoven dressing, it will be possible to combine the latter with an additional absorbent layer, and preferably an absorbent layer which does not gel, such as, in particular, a compress such as that used in the product Urgotul Duo or Urgotul Trio, an absorbent hydrophilic foam, preferably a hydrophilic polyurethane foam which has an absorption capacity greater than that of the nonwoven, such as that used in the product Cellosorb.

(65) According to one preferred embodiment, the synthetic polysulfated oligosaccharide compound according to the invention is incorporated into a nonwoven dressing, combined with an additional absorbent layer, and preferably an absorbent layer which does not gel, such as in particular a compress.

(66) According to another preferred embodiment, the synthetic polysulfated oligosaccharide compound according to the invention is incorporated into a nonwoven dressing, combined with an additional absorbent layer, and preferably an absorbent layer which does not gel, such as in particular an absorbent hydrophilic foam, preferably a hydrophilic polyurethane foam with an absorption capacity greater than that of the nonwoven.

(67) The nonwoven and the foam can be combined by techniques well known to those skilled in the art, for example by hot calendering, using a hot-melt powder based on TPU/polycaprolactone polymers.

(68) This technique is commonly used for bonding together nonwovens intended for the medical market.

(69) Finally, this foam or the nonwoven (when the latter is used alone) can be covered with a support to protect the wound from the exterior.

(70) This support can be of larger size than the other layers and can be made adhesive continuously or discontinuously on its side which comes into contact with the wound in order to optimize holding of the dressing in place during use, in particular if the wound is located on areas of the body that are not flat.

(71) This support and its adhesive are preferably impermeable to fluids but very permeable to water vapor in order to allow optimal management of the exudates absorbed by the dressing and to avoid problems of maceration.

(72) Such supports are well known to those skilled in the art and consist, for example, of films that can breathe and are impermeable, such as polyurethane films, or foam/film or nonwoven/film complexes.

(73) Additives

(74) In addition to the active agents, the oligosaccharide compounds according to the invention may be used in combination with one (or more) other active substance(s).

(75) The additives commonly used in the preparation of dressings can in particular be chosen from fragrances, preservatives, vitamins, glycerol, citric acid, etc.

(76) The activity of the synthetic polysulfated oligosaccharides according to the invention has been demonstrated in the following nonlimiting examples.

EXAMPLES

Example 1

Demonstration of the Effect of the Potassium Salt of Sucrose Octasulfate (KSOS) on Myofibroblast Differentiation

(77) 1. Culture of Normal Human Dermal Fibroblasts (NHDFs)

(78) Cultures of normal human dermal fibroblasts (NHDFs) were prepared in DMEM/F12 culture medium (sold by the company Invitrogen) supplemented with 10% of fetal calf serum (sold by the company Invitrogen), with 5 g/ml of insulin (sold by the company Promokine) and with 1 ng/ml of bFGF (sold by the company Promokine).

(79) 2. Induction of Differentiation

(80) The differentiation of the fibroblasts into myofibroblasts was then induced.

(81) For this, the NHDF cultures were placed in a P100 dish coated with collagen at 5 g/ml in DMEM/F12 medium supplemented with 10% of fetal calf serum and supplemented with 10 ng/ml of TGF-(sold by the company Promocell), which is a growth factor that controls cell proliferation and differentiation (differentiated control in FIG. 1).

(82) A nondifferentiated control was also prepared using cultures in DMEM/F12 supplemented with 10% calf serum without TGF-.

(83) The KSOS was added to the control and differentiated-control cultures to determine its effect on differentiation, in a proportion of 2 mg/ml.

(84) The results were analyzed after 4 days of culture.

(85) 3. Demonstration of the Inhibition of Fibroblast Differentiation

(86) In order to demonstrate the inhibition of the differentiation of the fibroblasts into myofibroblasts, the expression of -SMA mRNA was measured by quantitative RT-PCR, and the presence of the -SMA protein was detected by the Western blot method. For the measurement of the inhibitory effect of the compound according to the invention, KSOS was added at 2 mg/ml to the cultures undergoing differentiation. By quantitative RT-PCR: the mRNA was extracted using the Trizol, chloroform and isopropanol method. By the Western blot method: total cell extracts were prepared and a Western blot was carried out. The antibodies used are rabbit anti--SMA and mouse anti-actin antibodies (sold by Promega).

(87) The differentiation results on D4 clearly demonstrate the induction of -SMA expression in the cultures in the presence of TGF- and the inhibition of this induction when KSOS is added (FIG. 1). Immunofluorescence: cell cultures were prepared in 12-well plates on glass coverslips coated with collagen. The cells were fixed with 4% formaldehyde and permeabilized with Triton. The immunolabeling is carried out using DAPI staining (which gives a blue color) for the cell nuclei, a rabbit anti--SMA antibody and an anti-rabbit secondary antibody coupled to Cys3 (sold by Promega).

(88) The number of differentiated cells over the total number of cells is determined by cell counting. The diagram of FIG. 1 (D) gives the percentages of differentiated cells.

(89) Here again, the addition of KSOS causes an inhibition of the differentiation normally generated by TGF-.

Example 2

Demonstration of the Effect of the Potassium Salt of Sucrose Octasulfate (KSOS) on Collagen Lattice Retraction

(90) 1. Preparation of Collagen Lattices

(91) The collagen lattices were obtained by seeding 0.810.sup.6 normal human dermal fibroblasts (NHDFs) in a gel of collagen type I with a final concentration of 1.3 mg/ml.

(92) 2. Demonstration of the Effect of the Potassium Salt of Sucrose Octasulfate on Collagen Lattice Retraction

(93) A dressing (sold under the trade name Urgotul Start) comprising 7.5% of the potassium salt of sucrose octasulfate was applied to the surface of the collagen lattices.

(94) A control series, without dressing, was carried out in order to evaluate the normal contraction of the collagen gel by the seeded NHDFs.

(95) Likewise, a positive control was carried out by adding TGF- at a concentration of 10 ng/ml in order to visualize the strong contraction induced by the NHDFs highly differentiated into myofibroblasts.

(96) The incubation was maintained up to 7 days.

(97) 3. Results

(98) The effects of the potassium salt of sucrose octasulfate on the retraction of the collagen lattices was observed by means of photographic analysis (FIG. 2) and image analysis measurement of the area of the lattices once contracted.

(99) The results of the measurements of the average area of the collagen lattices are given in the following table:

(100) TABLE-US-00001 Average of the % relative to Treatment areas (mm.sup.2) the control Day 1 Control 229.7 100 Control + TGF- 217.3 95 Urgotul Start comprising 533.8 232 KSOS according to the invention Day 4 Control 191.0 100 Control + TGF- 145.9 76 Urgotul Start comprising 481.4 252 KSOS according to the invention Day 7 Control 174.7 100 Control + TGF- 97 56 Urgotul Start comprising 484.6 277 KSOS according to the invention

(101) Under the control conditions, the lattices gradually contracted between day 1 and day 7. The application of the Urgotul Start dressing comprising the potassium salt of sucrose octasulfate clearly slowed the contraction of the lattices.

(102) This result demonstrates that the treatment with KSOS limits the contraction of the collagen lattices, which is very positive for the treatment and prevention of pathological scars with significant levels of scar retraction.

Example 3

(103) A formulation of solvent-based filmogel type comprising a synthetic polysulfated oligosaccharide according to the invention, having the following composition, was prepared:

(104) TABLE-US-00002 Constituents % Nitrocellulose 12.800 Castor oil 11.000 Absolute ethanol 24.90 Ethyl acetate 49.70 UV-screening agents 1.500 Potassium salt of sucrose octasulfate KSOS 0.100

(105) The nitrocellulose was diluted in an ethyl acetate/absolute ethanol mixture. The castor oil, the UV-screening agents and the KSOS were then added until dissolution so as to obtain a composition of filmogel type.

Example 4

(106) A formulation of water-based filmogel type comprising a synthetic polysulfated oligosaccharide according to the invention, having the following composition, was prepared:

(107) TABLE-US-00003 Constituents % Demineralized water 93.200 Thickener 0.500 Sorbitol 2.000 Dextran 1.000 Potassium salt of sucrose octasulfate KSOS 1.000 Methylparaben 0.050 Propylparaben 0.050 Phenoxyethanol 0.700 10% NaOH 1.500

(108) The thickener was dispersed in the water with vigorous stirring, and then the sorbitol and the dextran were added while heating to 40 C. so as to obtain better solubility.

(109) The KSOS, the parabens and the phenoxyethanol were added and the mixture was left to stir in order to homogenize. It was then left to cool to ambient temperature by stopping the heating, while if required adjusting the water loss. Finally, the mixture was neutralized with sodium hydroxide and left to stir for 10 minutes before stopping the stirring.

Example 5

(110) A formulation in the form of a cream comprising a synthetic polysulfated oligosaccharide according to the invention, having the following composition, was prepared:

(111) TABLE-US-00004 Constituents % Oil-in-water surfactant 5.000 Emulsifying wax 2.000 Stearic acid 1.000 Isodecyl isononanoate 6.000 Silicone oil 4.000 (Decamethylcyclopentasiloxane) Emollient ester (myristyl lactate) 5.000 Demineralized water 62.100 Thickener 0.300 Glycerol 5.000 Propylene glycol 5.000 Potassium salt of sucrose octasulfate KSOS 0.500 Preservative 1.500 10% NaOH 0.600 Silicone surfactant 2.000

(112) The thickener was dispersed in the water. The glycerol, the propylene glycol, the KSOS and the preservative were added and the mixture was homogenized. It was heated to 70-75 C. When the mixture reached 70-75 C., the amount of water was adjusted and then the mixture was neutralized with 10% sodium hydroxide and the temperature was brought back to 70-75 C.

(113) At the same time, the oil-in-water surfactant, the emulsifying wax, the stearic acid, the isodecyl isononanoate, the silicone oil (decamethylcyclopentasiloxane) and the emollient ester (myristyl lactate) were mixed together and heated to 70-75 C.

(114) When the 2 mixtures reached 70-75 C., the second was added to the first with vigorous stirring and the resulting mixture was left to stir hot for 10 minutes.

(115) The silicone surfactant was then added and the resulting mixture was again left to stir hot for 5 minutes.

(116) Finally, the heating was stopped and the mixture was left to cool to ambient temperature, while maintaining sufficient stirring depending on the viscosity of the mixture. The mixture takes on a nonhomogeneous appearance around 35 C., but the cream then becomes smooth and shiny.