EP0641213A1

EP0641213A1 - Use of exogeneous glycosaminoglycanes or derivatives in the treatment of thrombopenias

Info

Publication number: EP0641213A1
Application number: EP93910111A
Authority: EP
Inventors: Zhong Chao Han; Jacques Caen; Jean-Claude Lormeau; Maurice Petitou
Original assignee: Institut des Vaisseaux et du Sang
Current assignee: Institut des Vaisseaux et du Sang
Priority date: 1992-05-15
Filing date: 1993-05-11
Publication date: 1995-03-08
Also published as: FR2691066A1; FR2691066B1; JPH07506584A; WO1993023059A1

Abstract

Use of exogeneous glycosaminoglycanes, their analogues and their fractions, fragments and derivatives in the preparation of drugs for the treatment of thrombopenias.

Description

USE OF EXOGENOUS OR DERIVATIVE GLYCXβAMDKX__LYO \ ES IN THE TREATMENT OF THROMBOPENIA

The invention relates to the use of exogenous glycosaminoglycans, their analogs, as well as their fractions, fragments and derivatives, for the preparation of medicaments intended for the treatment of thrombocytopenia.

Glycosaminoglycans (GAGs) are polysaccharides formed essentially by the regular repetition of the disaccharide sequence [uronic acid (D-glucuronic or L-iduronic) - ^» hexosamine (glucosamine or galactosamine)]. These products exist in several forms: heparin and heparan sulfate, chondroitin sulfate (4- S and 6-S), dermatan sulfate and hyaiuronic acid. The first three are variously substituted by sulfate groups; hyaiuronic acid does not contain a sulfate group. The glycosidic bonds between the different osidic motifs vary according to the forms and are of types 1-4 or 1-3 (Casu B. in Advances in Carbohydrate Chemistry and Biochemistry, Académie press Inc. 1985, 43, pp 51-133; Ruoslahti & Yamaguchi, Cell, 1991, 64 pp 867-869).

Glycosaminoglycans are components of cells and the extracellular matrix. They carry significant negative charges giving them an ability to fix a certain number of substances of cationic nature. As a result, they have multiple biological activities.

By analogues is meant glycosaminoglycans, products such as: dextran sulfate, pentosan polysulfate, sulfated alginic acid, sulfated lactobionic acid, polyvinyl sulfate and sucralfate. These products also often have interesting pharmacological properties.

Fractions, fragments and derivatives of glycosaminoglycans, and more particularly of heparin and heparan sulfate whether or not they have an anticoagulant activity, are also known.

Indeed, glycosaminoglycans, their analogs, as well as their fractions, fragments and derivatives, and in particular heparin, heparan sulfate and dermatan sulfate, have been the subject of numerous studies, which have made it possible to highlight several biological activities. These activities are: anticoagulant activity, the ability to complex various proteins, activity in the complement system, activity as regulators and modulators of the development of certain types of cells, vascular or non-vascular and activity on angiogenesis.

(Casu B., in Advances in Carbohydrate Chemistry and Biochemistry, Académie press Inc. 1985, 43, pp 51-133; Seminar in Thrombosis and Haemostasis, 1991, 17, supl. 1 & 2, pp 1-246. Development of non -heparin glycosaminoglycans as therapeutic agents, JM Walenga, J. Fareed, guest editors, Thieme medical Publishers, Inc. New-York; Ruoslahti E. & Yamaguchi Y., Cell, 1991, 64, pp 867-869; Lindahl U., TP Int. Rev. ScL Org. Chem. Ser. Two, Carbohydrate, 1976, 7, pp 283-312).

Several pharmaceutical specialties contain as active ingredient glycosaminoglycans, their fragments or derivatives. Magnesium heparinate, for example, is the active ingredient in a specialty marketed in France under the name Cutheparin®. It is an anticoagulant acting on several coagulation factors and used in the prevention and treatment of thromboembolic disease and thrombogenic states. Heparin fragments, also known as low molecular weight heparins, are also active ingredients in drugs such as, for example, nadroparin, or dalteparin, enoxaparin, parnaparin or tinzaparin.

These active ingredients have a notorious antithrombotic effect, in particular a powerful activated anti-factor X effect, and a reduced anticoagulant effect ("Dictionnaire Vidal" 1992, Edition du Vidal, Paris).

Patent application EP-A-0 037 319 describes such products and their preparation process.

Furthermore, the activation of heparin cofactor II by heparin and dermatan sulfate was studied by DM Tolfesen (Nouv. Rev. Fr. HématoL, 1984, 26, N ° 4 _r PP 233-237). This author describes the effects of heparin and dermatan sulfate on coagulation factors, and suggests the use of these two products in this same field.

Patent application EP-A-0 199 033 also describes the use of dermatan sulfate and that of heparan sulfate, alone or in combination, for the prevention or treatment of venous thrombosis or manifestations of arteriosclerosis.

Dextran sulfate is also used as an anticoagulant (JEF Reynolds "Martindale, The extra Pharmacopeia", 1989, The Pharmaceutical Press, p 1564). Furthermore, patent application EP-A-0 270 317 describes low molecular weight dextran sulfate derivatives which exert an inhibitory activity on cell fusion and on viral adsorption, and disclose the advantage of using these products in the treatment and prophylaxis of diseases due to viral infections.

Sodium hyaluronate is used as an adjunct in anterior chamber eye surgery. This product provides mechanical protection of the cornea and reduces the risk of synechiae formation ("Dictionnaire Vidal", 1992, Edition du Vidal, Paris). This same product is also used in the treatment of arthritis (J.E.F. Reynolds "Martindale, The extra Pharmacopeia", 1989, The Pharmaceutical Press, p 1617).

The pentosan polysulfate, active ingredient of a specialty marketed in France under the name of Hemoclar®, has anticoagulant, fibrinolytic properties and exerts an activity on the release of lipoprotein lipase ("Dictionnaire Vidal", 1992, Edition du Vidal, Paris and 'The

Merck Index ", 1989, Merck and Co INC, Rahway NJ, USA, p 1131 N ^β 7090).

Chondroitin sulfate, a physiological constituent of the cornea, is used in the symptomatic treatment of hypolacrymia. The mucin structure of this naturally occurring mucopolysaccharide achieves prolonged adhesion to hydrophobic cells of the eyeball and thus maintains effective protection ("Dictionnaire Vidal", 1992, Edition du Vidal, Paris). Chondroitin sulfate also finds its application in the treatment of cardiac ischemia and osteoporosis (J.E.F. Reynolds "Martindale, The extra Pharmacopeia", 1989, The Pharmaceutical Press, p 1556). Furthermore, in the literature, it is also described that this product has antihyperlipoproteinemic activity ('The Merck Index ", 1989, Merck and Co INC, Rahway N.J, USA, p 344 No. 2217).

Patent application EP-A-0 287 477 describes heparins of low molecular weight which can be used for the regulation of certain physiological systems such as the inhibition of angiogenesis, the inhibition on the proliferation of smooth muscle cells or having activity anti-complement.

Oligosaccharides containing at least 5 monosaccharide units (derivatives of glucosamine and uronic acids) consistent with those present in natural heparin and having a specific affinity for cationic or anionic cell growth factors recognizing heparin, are described in patent application EP-A-0244298. These fragments are described as having regulatory activities on cell division and differentiation and find their applications in stimulating the repair of muscle tissue, heart tissue or skin tissue, accelerating the healing of injuries of traumatic origin. , and alone or in combination with steroids, in the inhibition of processes where neoangiogenesis is pathological.

US Pat. No. 3,466,365 describes sodium or potassium salts of polyvinyl sulfate derivatives endowed with antiviral activities.

Derivatives of poly (H-sulfate) lactobionic acid as well as their salts, exhibiting complement inhibiting activity, are described in US Pat. No. 4,258,034.

Megacaryocytopoiesis concerns the engagement of hematopoietic stem cells towards the megakaryocytic line, the proliferation of megakaryocytic progenitors and the maturation of megakaryocytes to give rise to platelets (Mazur EM., Megakaryocytopoiesis and platelet production: A review Exp Hematol., 1987, ^ 5, pp 340-350; Hoffman R., Regulation of megakaryocytopoiesis, Blood, 1989, 74, pp 1196-1212). Platelets play a very important role in certain physiological processes, notably blood coagulation (Caen J.P., Cronberg S. and Kubisz P., Platelet physiology and pathology, New-York, Stratton International, 1977).

It has been shown that megakaryocytopoiesis is directly regulated by a number of hematopoietic growth factors such as "megakaryocyte colony-stimulating factor" (MK-CSF), interleukin-3 (IL3), interleukin-6 (IL6 ), the "granulocyte-macrophage colony-stimulating factor" (GM-CSF) and erythropoietin (Epo). It is also indirectly controlled by interleukin-1 and interleukin-11 (Mazur EM., Exp. HematoL, 1987, 15, pp 340-350; Hoffman R., Blood, 1989, 75, pp 1196- 1212).

Among these factors, IL3, Epo, and GM-CSF have been used in vivo in normal subjects and patients. Their stimulating effects of megakaryocytopoiesis are limited, in particular in aplastic anemias and in secondary hematopoietic insufficiencies (Peters WP. The myeloid colony-stimulating factors, Introduction and overview, Seminars in Hematology, 1991, 28, pp 1-5; Ganser A. et al. , Blood, 1990, 76, pp 1287-1292; Ganser A. et al, Z6, pp 666-676). This shows the existence of another mechanism controlling megakaryocytopoiesis. Note that growth factors have multiple activities. Thus their excessive administration cannot be envisaged since it could cause unexpected and unfavorable side effects (Metcalf D., The consequences of excess ievels of Haematopoietic growth factors. Br. J. Hematol., 1990, 75, pp 1-3) .

The hematopoietic cord is a complex system made up of cells of different types and functions. Its organization can be conceived in five cell compartments: stem cells of the entire hematopoietic line, hematopoietic progenitor cells, mature hematopoietic cells, the micro-environment and accessory cells. Stem cells by a series of differentiations and maturations give rise to progenitor cells which include megakaryocyte progenitors, the latter in turn giving rise to platelets as indicated above. We only know that there are endogenous proteoglycans which play a role on granulopoiesis by a closed compartmental mechanism, targeted on the growth factor GM-CSF (Gordon MY et al., "Compartmentalization of a haematopoietic growth factor (GM-CSF ) by glycosaminoglycans in the bone marrow micoenvironment ", Nature, 1987, 326. pp 403-405; Roberts R. et al., Heparan sulfate bound growth factors, A mechanism for stromal cell mediated haemopoiesis, Nature, 1988, 332. pp 376 -378). However, no information exists on the action of exogenous glycosaminoglycans in the megakaryocytopoiesis system.

It has now been demonstrated that, unexpectedly, exogenous glycosaminoglycans, their analogs, as well as their fractions, fragments and derivatives, if administered to animals or humans, can act in a whole cellular system. quite different from the systems studied to date, namely the hematopoietic medullary system, and more particularly, as specific inducers or modulators of the regulation of human or murine megakaryocytopoiesis, and can be used therapeutically to treat thrombocytopenia.

Thrombocytopenia is a well-known condition, especially during cancer chemotherapy. At present, there is no effective and economical treatment to remedy it. It was therefore of prime interest to find a specific and economical way to combat this pathological situation.

The invention therefore relates to the use, as specific inducers of megakaryocytopoiesis of exogenous glycosaminoglycans, of their analogs, as well as of their fractions, fragments and derivatives, for obtaining medicaments intended for the treatment of thrombocytopenia.

For the preparation of these medicaments, heparins of porcine or bovine origin, extracted from the lungs, from the intestinal mucosa or from any other organ, can be used as unfractionated heparins.

As an example, low molecular weight heparins can be used, nadroparin calcic (DCI) and CY 222 (Laboratoires CHOAY, France; patents FR-2,440,376 and EP-0,037,319), PK 10169 known as also enoxaparin (DCI) (PHARMUKA Laboratories, France; patent application EP-0040 144), dalteparin (DCI) or KABI 2165 (KABI VITRUM, Sweden; Thrombosis Res. (1986) 42, p 435-447), la pamaparin or OP 2123 (OPOCRIN, Italy; patent applications EP-0 121 067 and WO 86/06729), RD 11885 (HEPAR INDUSTRIES, Ohio USA; patent application and patents EP-0244235, GB-2002406 and GB- 2 068011), tinzaparin (DCI) or LHN-1 (NOVO INDUSTRIES, Denmark; patent applications EP-0 244 234 and EP-0244 235). All these products are already described in the literature (Haemostasis 1988, 18 sup 3, pp 3-15), and the majority of them are active ingredients from the specialties already made available to the medical profession. Thus, for example, caicic nadroparin is the active ingredient in the specialty Fraxiparine®, dalteparin is the active ingredient in the specialty Fragmine®, enoxaparin is the active ingredient in the specialties Lovenox® and Clexan®, tinzaparin is the active ingredient Logiparin ^® and Innohep ^® specialties, and pamaparin is the active ingredient in Fluxam® and Minidalton ^® specialties. Fragments of non-anticoagulant heparins and derivatives of hypersulphated heparins, which can be used for the preparation of medicaments according to the invention, are described respectively in patent applications EP-0287477 and EP-0 214 879. Derivatives O-acylated heparins are described in patent application EP-0 356275. Other fragments of heparins (hexasaccharides, octasaccharides, etc.) are described in patent application EP-0244298.

Chondroitin sulfate, dermatan sulfate, hyaiuronic acid and heparan sulfate are commercially available products.

In a particular embodiment of the invention, the glycosaminoglycans used are, chondroitins sulfate 4-S and 6-S, dermatan sulfate as well as their fractions, fragments and derivatives.

In another particular embodiment of the invention, the glycosaminoglycans used are hyaiuronic acid, its fractions, fragments and derivatives.

In yet another particular embodiment of the invention, the glycosaminoglycans used are heparin and heparan sulfate, as well as their fractions, fragments and derivatives. In a particularly advantageous embodiment of the invention, the glycosaminoglycans used are heparin, as well as its fractions, fragments and derivatives.

In another advantageous embodiment of the invention, analogs of glycosaminoglycans are used, such as the following products: dextran sulfate, pentosan polysulfate, alginic acid sulfate, lactobionic acid sulfate, polyvinyl sulfate and sucralfate. Preferably, dextran sulfate and pentosan polysulfate are used.

Advantageously, according to the present invention, there are used for the preparation of medicaments, glycosaminoglycans, their analogs as well as their fractions, fragments and derivatives devoid of anticoagulant activity.

Very preferably, low molecular weight heparins, such as caicic nadroparin, are used as exogenous glycosaminoglycans.

In vitro tests in humans and mice, and in vivo tests in normal mice and in mice made aplastic by chemotherapy treatment, have shown that glycosaminoglycans exogenous, their analogs as well as their fractions, fragments and derivatives are positive regulators of megakaryocytopoiesis. Given their stimulatory or modulatory effects on megakaryocytopoiesis, and their mechanism of action, these products can therefore be used for the therapeutic treatment of different types of thrombocytopenia, such as:

- peripheral thrombocytopenia of various mechanisms (idiopathic thrombocytopenic purpuras and other immune thrombocytopenia).

- acquired central thrombocytopenia, in particular those recovering from chemotherapy (cancer, leukemia, AIDS, etc.) and a bone marrow transplant. The evolution on spinal cord recovery, in particular megakaryocytic and platelet, would be important. It has been shown that in patients undergoing chemotherapy or bone marrow transplant, plasma MK-CSF activity is very high (Mazur EM. Et al. Blood, 1990, 76, pp 290-297; Fauser et al. , Transplantation, 1988, 46, pp 543-547; Hoffman R., Blood, 1989, 74, pp 1196-1212).

- other types of thrombocytopenia such as "Gray platelet syndrome" platelet syndrome.

The dosage used depends on the patient's age, weight, route and frequency of administration, severity of thrombocytopenia and associated treatments. It varies from 40 μg to 1 mg per kg of body and per dose, when glycosaminoglycans, their analogs, their fragments, fractions or derivatives, are administered by intravenous, intramuscular or subcutaneous route. When administered orally, doses of 40 μg to 10 mg per kg of body weight and per dose are required. The daily doses by parenteral can vary from 40 μg to 2 mg per kg of body weight, and by oral route, from 40 μg to 20 mg per kg of body weight.

The invention also extends to pharmaceutical compositions which can be used in the treatment of thrombocytopenia, containing as active principle an exogenous glycosaminoglycan, one of its analogs, of its fragments, fractions or derivatives, in combination with one or more inert and suitable excipients, or in combination with other compounds used for the treatment of thrombocytopenia.

Various pharmaceutical forms can be envisaged, such as injectable solutions, tablets, dragees, capsules, glossettes or other galenical preparations suitable for sublingual administration, nanoparticles, microcapsules and solutions for endonasal spraying. Of preferably, gastro-resistant formulations are used for oral administration.

The pharmaceutical forms indicated above are given by way of examples and are not limiting. Other pharmaceutical forms and other routes of administration can be envisaged.

The invention will be illustrated with the aid of the examples below, which contain experimental results obtained during the various pharmacological tests.

Products tested

- Chondroitin sulfate (6-S), dermatan sulfate, heparan sulfate, hyaiuronic acid, (Sigma Chemical, USA).

- Unfractionated heparin sold under the name Cutheparin ^® , supplied by Biosedra, Paris.

- Heparin fragments:

* Nadroparin calcium, active ingredient of the specialty Fraxiparine ^® , supplied by Laboratoires Choay, Paris;

* CY 222: Product described in patent EP-0 037 319 (Example 1), supplied by Elf Sanofi;

^• Product A: Heparin fragment practically devoid of anticoagulant activity. To obtain this product, the heparin was subjected to a gentle oxidation using periodic acid, then to a depolymerization by addition of a strong base and finally, the products resulting from the polymerization were subjected to a reduction according to the process described in patent application EP-0 287 477 (Example 1). Product A has an average molecular weight of 6500 Da and a degree of sulfation of 2.3. Product A was supplied by Elf Sanofi, Paris;

* Product B: It is a hexasaccharide prepared from heparin, according to the process described in patent application EP-0 244 298. This compound is explicitly described in the same application, and it was supplied by Elf Sanofi , Paris.

Fragments of dermatan sulfate:

These products were obtained by depolymerization of dermatan sulfate using periodic acid (Tollefsen DM, Nouv. Rev. Fr., Hematol. 1984, 26, No. 4, pp 233-237). They are composed of a number of monosaccharide units (derivatives of L-iduronic acid and D-galactosamine) well determined, given below:

^* Product C: consisting of 3 monosaccharide units ^* Product D: consisting of 5 monosaccharide units

^* Product E: consisting of 7 monosaccharide units

^* Product F: consisting of 9 monosaccharide units

* Product G: made up of 11 monosaccharide units

* Product H: consisting of 13 monosaccharide units All these products were supplied by Elf Sanofi, Paris.

- Glycosaminoglycan analogues:

^* Dextran sulfate supplied by Sigma Chemical, USA

* Pentosane polysulfate, supplied by Elf Sanofi, Paris.

EXAMPLE 1

Effects on the stimulation of megakaryocytopoiesis in vitro: tests on a system of murine mononuclear cell cultures of mouse femur marrow

Effects of glycosaminoglycans, their analogs as well as their fractions, fragments and derivatives on megakaryocytopoiesis in vitro were examined using a culture system of megakaryocytic progenitors (Han ZC. Et al.; CR Acad. Sci., Paris, 1991 , t 313, Series III, pp 553-558).

In this culture system, the murine mononuclear cells of the femoral marrow are taken from Balb / c mice (IFFA CREDO). 2.10 ⁵ murine mononuclear cells are added, at least in triplicate, in a volume of 1 ml of a base medium (alpha medium) containing: 10% bovine plasma citrate, 1% bovine serum albumin, 10% mercaptoethanoi (final concentration of 1 (HM), 0.34 mg ml of calcium chloride with or without 10% aplasia serum. The different quantities of test products are diluted in a volume of 0.2 ml of alpha medium , and the solutions thus obtained, having different concentrations, are added to the plasma clots formed after coagulation of the plasma. The pig aplasia serum is used for these murine marrow cultures. The megakaryocytes and their murine colonies are identified by ia acetylcholinesterase staining (Jackson CW. _t Blood, 1973, 42, pp 413-421). 1- Results obtained with heparin, heparan sulfate and Fraxiparine®

- Effects on the formation of megakaryocytic colonies:

The test products including a standard unfractionated heparin, Fraxiparin ^® and heparan sulfate were used in different doses, given in Table I. The results represent the mean ± SEM for the number of colonies 2.10 ⁵ cells from 3 separate experiments, done in triplicate. Statistical significance (*) was established according to Student's t test for p <0.05.

TABLE I

Effects of heparin and heparan sulfate on the formation of megakaryocytic (CFU-MK) and granulocyte-macrophagic (CFU-GM) colonies in vitro

The results indicated in Table I demonstrate that standard heparin, Fraxiparine ^® and heparan sulfate are capable of significantly increasing the formation of megakaryocytic colonies on the piasmatic clot culture system, in particular in the presence of serum. aplastic pork, obtained from irradiated pigs, which is rich in an activity known as MK-CSF. On the other hand, they do not significantly stimulate the formation of CFU-GM colonies, whether in the presence or in the absence of aplastic serum. - Effect on the maturation and the size of megakaryocytes and their colonies:

Over 500 colonies and 100 individual megakaryocytes were analyzed. Statistical significance (*) p <0.05. The results of this test are given in Table II.

TABLE II

Standard heparin, Fraxiparine® and heparan sulfate, are capable of promoting maturation and increasing the size of megakaryocytes and their colonies.

2- Results obtained with Product A, Product B and CY 222

Product A, heparin depolymerized with periodic acid and having a very reduced anticoagulant activity, Product B, regular hexasaccharide of heparin and CY 222, are also capable of significantly stimulating the formation of megakaryocytic colonies on the system. plasma clot. During these tests, the cells were cultured in the presence of aplastic pig serum. The results reported in Table III represent the mean ± SEM of the number of colonies for 2.10 ⁵ cells, from 3 separate experiments carried out in triplicate; statistical significance HP <0.05.

TABLE III

3- Results obtained with chondroitin sulfate, hyaiuronic acid, dermatan sulfate and its fragments

The products have been tested at doses ranging from 0 to 100 μg / ml. The results of this study are shown in Table IV.

TABLE IV

H P <0.05

Chondroitin sulfate, dermatan sulfate, its fragments and hyaiuronic acid, added to murine marrow cultures in the presence of aplastic serum at concentrations of 10-100 μg / ml, are capable of significantly stimulating the formation of megakaryocytic colonies.

4- Results obtained with glycosaminoglycan analogues

The products examined are indicated in Table V.

TABLE V

HP <0.05 The results in Table V demonstrate that the products examined stimulate, in a dose-dependent and significant manner, the formation of megakaryocytic colonies in cultures containing aplastic serum.

EXAMPLE 2

Effects on stimulation of megakaryocytopoiesis in vitro, tests on a culture system of human spinal mononuclear cells

The megakaryocytic progenitor culture system used is that described by Han ZC. et al, Exp. Hematol, 1989, 1 £ pp 46-52.

Human spinal cord mononuclear cells are taken from healthy individuals (the various samples were taken with the consent of healthy volunteers). 2.10 ⁵ spinal mononuclear cells are added, at least in triplicate, in a volume of 1 ml of a basic medium containing: 10% bovine citrate plasma, 1% bovine serum albumin, 10% mercaptoethanol (final concentration of 10 ^-4 M), 0.34 mg / ml of calcium chloride with or without 10% aplasia serum. Human aplasia serum is used for human marrow cultures. Heparin and heparan are added in a volume of 0.2 ml of alpha medium (cf. Example 1), on the plasma clots formed after coagulation of the plasma. Human megakaryocyte colonies are identified by immunoperoxidase staining using a monoclonal antibody directed against platelet glycoprotein llb / IIIa (Han ZC. Et al., Exp Hemato., 1989, 7, 46-52).

The products tested are unfractionated heparin and heparan sulfate.

The doses used were from 1 to 5 IU / ml for heparin and from 10 to 50 μg / ml for heparan sulfate. The method used for this study is that of the plasma clot. The results reported in Table VI represent the mean ± SEM of the number of MK colonies from two experiments. It is found that heparin and heparan sulfate stimulate the formation of megakaryocytic colonies in normal marrow cultures in the presence of human aplastic serum.

These results indicate that heparin and heparan sulfate, at doses of 5 IU / ml and 50 μg / ml respectively, are capable of inducing the growth of human megakaryocytes. TABLE VI

H P <0.05

EXAMPLE 3

Study of the interaction of standard heparin and Fraxiparine® with growth factors acting on megakaryocytopoiesis

The effects of standard heparin and Fraxiparine® have been studied in the presence of various growth factors on the formation of murine megakaryocytic colonies. The results indicated in FIG. 1, represent the mean ± SEM of the number of MK colonies from at least

3 separate experiments. Statistical significance (*) p <0.05.

Standard heparin and Fraxiparine® increase the activity potential of aplastic serum (rich in MK-CSF). When the aplasia serum is replaced by another growth factor, the effect of heparin on megakaryocytopoiesis is not visible. This is the case, for example, when adding IL3 (Genzyme, USA), IL6 (Genzyme, USA), GM-CSF (Genzyme, USA) or Epo (Amersham, France).

The effects of monoclonal antibodies directed against murine IL3 or PIL6 on the formation of murine megakaryocytic colonies (MK) induced by IL3 OR IL6, by aplasia serum and Fraxiparine®, and by serum d and heparin have also been studied. The protocol used is identical to that described in Example 1. The results indicated in Table VII below represent the mean ± SEM of two or three experiments.

It is noted that the addition of monoclonal antibodies directed against IL3 OR IL6 munn, neutralizes the action of IL3 or of added NL6, but does not suppress the activity of Fraxiparine® and heparin standard. This suggests an effect of heparin, independent of NL3 and IL6. TABLE VII

5

EXAMPLE 4

In vivo tests in normal mice

0 1- In vivo effects of Fraxiparine® on hematopoiesis and on the size of megakaryocytes and their colonies

Fraxiparine ^® was injected subcutaneously in mice

Balb / c bi-daily for 4 days at concentrations of 0, 4, 20, 40, 5200 and 1000 IU / kg. The "control" mice only received phosphate buffer (PBS Eurobio). The animals were killed by cervical dislocation 2 days after the last injection.

The number of CFU-MK, CFU-GM, megakaryocyte and blood formulas were examined using the methods described by Han Z.C. et al ; .C.R. Acad. Sci. Paris, 1991, 313, pp 553-558.

The spinal cells were obtained from the femurs and the blood was obtained by cardiac puncture. Medullary cells at a concentration of 2.10 ⁵ mononuclear cells per ml were re-cultured in five copies in the presence of megakaryocytic progenitors or CFU-MK and granulomonocytic progenitors or CFU-GM.

The number of megakaryocytes (MK) was evaluated on non-cultured medullary cells but seeded in culture dishes after obtaining from femurs. The number of platelets, white blood cells and hemoglobin were measured using an automatic hematopoietic counter.

The results indicated in Tables VIII and IX represent the mean ± SEM. Each group contains 5 or more mice. Statistical significance ( ^* ) p <0.05.

TABLE VIII

IN VIVO EFFECT OF FRAXIPARINE® ON HEMATOPOIESIS

TABLE IX

EFFECT OF FRAXIPARINE® ADMINISTRATION ON SIZE

MEGACARYOCYTES (MK)) AND THEIR COLONIES

It is seen that the number of CFU-MK medullary single megakaryocytes and platelets, such as the size of megakaryocytes and their colonies increase significantly 24 hours after the last injection of Fraxiparine ^® at doses of 20 to 200 IU / kg. However, the number of CFU-GM, white blood cells and hemoglobin level are not affected. 2- Study of the duration of action of Fraxiparine ^® on the production of megakaryocytes and platelets

Fraxiparine ^® was injected at an optimal dose of 40 IU / kg subcutaneously, into Balb / c mice bi-daily for 4 days. The marrow and blood samples were taken on days 2, 5, and 8, after the last injection, according to the protocol indicated above. The results in Table X represent the mean ± SEM. Each group contains 5 or more mice. Statistical significance (*) p <0.05.

PAINTINGS

As can be seen, the stimulating effect of Fraxiparine ^® on the production of platelets lasts at least 5 days after the last injection. These results indicate ou'in vivo, Fraxiparine ^® specifically increases ia producing megakaryocytes and platelets.

3- Results obtained with other glycosaminoglycans or their. analogs, fragments or fractions on hematopoiesis

Dermatan sulfate, dextran sulfate (5000 Da), heparin, Product A and Product B were injected in the same way as Fraxiparine®, at a concentration of 10 μg / injection and per mouse. The marrow and blood samples were taken on day 2, after the last injection. The results of this study are given in Table XI. TABLE XI

(*) p <0.05

It has been observed, as with Fraxiparine®, that the products tested are capable of promoting the production of megakaryocytes and platelets (Product A).

EXAMPLE 5

Effects of Fraxiparine ^® . dextran sulfate and Product B on spinal cord injury caused by the injection of 5-fluorouracyl

Balb / c mice (5-10 mice per group) were initially injected with 150 mg kg of 5-fluorouracyia. Two days later, Fraxiparine ^® (40 IU / kg) or Product B (40 IU / kg), were injected subcutaneously (one injection per day for 4 days). For the "control" mice, phosphate buffer (PBS-Eurobio) was used. The animals were killed by cervical dislocation. The spinal cells were obtained from the femurs and the blood was obtained by cardiac puncture. The spinal cells at a concentration of 5.10 ⁴ per ml, were re-cultured in five copies in the presence of aplastic pig serum for one week, to test the number of CFU-MK. The number of megakaryocytes (MK) was evaluated on spinal cells not cultivated but seeded in culture dishes after their obtaining from femurs (Han ZC et al; CR Acad. Sci. Paris, 1991, 3 3, pp 553 -558). The number of platelets, white blood cells and hemoglobin level were measured using an automatic hematopoietic counter.

The results indicated in Table XII represent the mean ± SEM. Statistical significance (*) p <0.05. TABLE XII

(*): PBS = Witness

The results obtained show that the administration of Fraxiparine® to mice treated with 5-fluorouracyl accelerates megakaryocytic recovery. Thus on days 2 and 3, after the injection of Fraxiparine®, the number of CFU-MK and megakaryocytes isolated, increases appreciably in the marrow as well as the number of platelets.

Dextran sulfate (5000 Da) and Product B were injected in the same way as Fraxiparine ^® , at a dose of 10 μg / injection in mice treated with 5-fluorouracyl. The administration of these two products also accelerates the recovery of platelets on day 2 after the last injection.

EXAMPLE 6

Complementary experiments aimed at demonstrating the specificity of the action of αlvcosaminoαlvcanes

The effect of protamine sulfate (Choay Laboratories, Paris), the main heparin neutralizing agent was tested in murine marrow cultures according to the protocol described in Example 1. The protamine, in the concentrations of 50-100 μg / ml, completely neutralizes the activity of Fraxiparine®.

Heparinase (Sigma USA) and chondroitinase ABC (Sigma, USA), when added at concentrations of 0.1-1 μg / ml, significantly inhibit the formation of megakaryocytic colonies. These results clearly show that glycosaminoglycans are responsible for the activity observed on megakaryocytopoiesis.

The results of these studies are respectively grouped in Tables XIII and XIV. They represent the average of 3 experiments ± SEM. Statistical significance (*) p <0.05.

TABLE XIII Effects of protamine sulfate on the action of Fraxiparine ^® in murine marrow cultures

TABLE XIV

Effects of heparinase and chondroitinase ABC on the formation of MK colonies in vitro (2.10 ⁵ cells)

Claims

1- Use of exogenous glycosaminoglycans, their analogs, their fractions, fragments or derivatives, for obtaining drugs intended for the treatment of thrombocytopenia.

2- Use according to claim 1, characterized in that the exogenous glycosaminoglycan is heparin, heparan sulfate, their analogs, as well as their fragment and derivative fractions.

3- Use according to claim 1 or 2, characterized in that the exogenous glycosaminoglycan is a heparin of low molecular weight.

4- Use according to claim 1, characterized in that the exogenous glycosaminoglycan is chondroitin sulfate 4-S, chondroitin sulfate 6-S, dermatan sulfate, their fractions, fragments or their derivatives.

5- Use according to claim 1, characterized in that the exogenous glycosaminoglycan is hyaiuronic acid, its fragment fractions or its derivatives.

6- Use according to claim 1, characterized in that the analogs of glycosaminoglycans are chosen from dextran sulfate, pentosan polysulfate, alginic sulfated acid, lactobionic sulfated acid, polyvinyl sulfate or sucralfate.

7- Use according to any one of claims 1 to 6, characterized in that the exogenous glycosaminoglycans, their analogs, their fractions, fragments, or derivatives are devoid of anticoagulant action.

8- Pharmaceutical composition for the treatment of thrombocytopenia containing as active principle, exogenous glycosaminoglycans, their analogs, their fractions, fragments or derivatives. 9 - Pharmaceutical composition for the treatment of thrombocytopenia, containing as active principle, exogenous glycosaminoglycans, their analogs, their fractions, fragments or derivatives in association with another compound usable in the treatment of thrombocytopenia.

10 - Process for the treatment of thrombocytopenia, which comprises the administration, to a human being in need thereof, of an effective quantity of a compound chosen from exogenous glycosaminoglycans, their analogs, their fractions, fragments and derivatives -

11 - Process according to claim 10, which comprises the administration of the compound by the parenteral route at a daily dose of 40 μg to 2 mg per kg of body weight.

12 - Process according to claim 10, which comprises the administration of the compound orally at a daily dose of 40 μg to 20 mg per kg of body weight.

13 - A method for the treatment of thrombocytopenia, which comprises the administration, to a human being in need thereof, of an effective amount of a compound chosen from exogenous glycosaminoglycans, their analogs, their fractions, fragments and derivatives, in combination with an effective amount of another compound for the treatment of thrombocytopenia.