WO1986004579A1 - L-dopa derivatives, preparation thereof and pharmaceutical compositions containing them - Google Patents

Abstract

L-Dopa derivatives wherein L-Dopa is coupled to a glycerol derivative by forming an ester bound with a hydroxyl function of glycerol, at least one of the remaining hydroxyl positions being esterified by an acyl chain and the other remaining hydroxyl position being also esterified either by an acyl chain different from or similar to the first one, or by an esterification agent of another nature but pharmacologically acceptable. A preferred compound of the invention has the formula (III). The invention also relates to a process for the preparation of such compounds and the utilization thereof for preparing drugs against the Parkinson disease presenting improved properties.

Description

         

  
 



   L-DOPA derivatives, their preparation and
 pharmaceutical compositions containing them.



   The present invention relates to new derivatives of L-Dopa or (L)-dihydroxy-3,4-phenylalanine having improved properties compared to the
L-Dopa itself, processes for their preparation, pharmaceutical compositions containing such compounds and extends to their application in human medicine in particular.



   L-Dopa is commonly used in the treatment of the most debilitating symptoms of Parkinson's disease (tremors, rigidity, bradykinesia). Nevertheless, although the treatment may be effective for several years, it suffers from significant drawbacks due to the too short biological half-life of L-Dopa and its rapid degradation into dopamine, which leads to significant fluctuations and rapid blood levels and the appearance of side effects due to circulating dopamine, phenomena responsible for harmful side effects such as dyskinesia, gastrointestinal and cardiovascular disorders. This state of affairs is very largely due to a very marked first-pass effect, at the hepatic level, but especially at the gastrointestinal level.



   The aim of the present invention is essentially to provide new compounds and pharmaceutical compositions containing these compounds which make it possible to avoid the aforementioned drawbacks.



   The strategy which was adopted to combat these problems consisted in the synthesis of a derivative of the
L-Dopa by coupling the latter to a derivative of glycerol by forming an ester bond with a hydroxyl function of the glycerol, at least one of the remaining hydroxyl positions being esterified by an acyl chain and the other remaining hydroxyl position also being esterified either by an acyl chain identical to or different from the first, or by an esterification agent of another nature but pharmacologically acceptable.



   The incorporation of L-Dopa into a glyceride structure improves the therapeutic value of the latter in several ways: - by reducing the intestinal and hepatic first-pass effect and thus the side effects linked to the formation of certain metabolites ( in particular, dopamine) - by ensuring blood concentrations that are better spread over time, which eliminates the excessive fluctuations in blood levels observed with L-Dopa, - by bypassing the active transport system which ensures intestinal resorption of L-Dopa, which is at least partly responsible for the variability of the therapeutic response.



   Preferred compounds of the present invention may be represented by formula (I)
EMI2.1
 * = form L in which R1 represents a glycerol residue and R2 and R3, which may be identical or different, represent an acyl residue comprising from 4 to 22 carbon atoms or a pharmacologically acceptable acid residue, at least one of these two residues being an acyl residue comprising from 4 to 22 carbon atoms.



   Preference is given to compounds of formula (II)
EMI2.2
   * = form L and most particularly those in which R2 and R3 represent an acyl residue containing from 4 to 22 carbon atoms.



   The compounds in which R2 and R3 represent identical residues are very particularly preferred.



   Provided that one of the residues R2 and R3 represents an acyl residue comprising from 4 to 22 carbon atoms, the other residue may however be different and in particular be a phosphoric acid residue for example.



   The invention also extends to compounds analogous to those mentioned above where the acyl residue of L-dopa, instead of being fixed in position 2 of the glycerol, is in position 1 or 3.



   The aforementioned compounds can be used as active principle in the treatment of Parkinson's disease or serve as intermediate products for the characterization, purification or synthesis of such active products, in particular by transesterification.



   As an example of a compound particularly studied in the context of the present invention, mention may be made of the compound of formula (III)
EMI3.1
   * = L-shape
 L-Dopa derivatives are already known, in particular dipeptides or tripeptides which do not however have the advantages of the compounds of the present invention, namely to allow resorption via the lymphatic route while avoiding significant destruction of the compound in the tract. intestinal or via the liver.



  The administration to patients of large quantities of L-Dopa which is currently necessary for the availability of dopamine in sufficient quantities to the brain after crossing the blood-brain barrier is thus avoided. In addition, this results in a reduction of the harmful side effects due to the presence of peripheral dopamine, responsible in particular for nausea, etc.



   The compounds of the invention are preferably administered per os in the form of pharmaceutical preparations obtained in the conventional manner, by well-known galenic techniques by addition of conventional adjuvants, excipients and carriers. They can be presented in the form of emulsions, suspensions, capsules or syrup in particular.



     It should be noted, insofar as the substitutions on the glycerol residue in the aforementioned molecules have the consequence of making an asymmetric carbon atom that the invention extends to the racemic mixture and to the various diastereoisomeric forms resulting from the conjunction of the carbon asymmetric carbon of the L-dopa part and asymmetric carbon of the glyceride part.



   It is observed that the compounds of the invention make it possible to obtain the same pharmacological effects as those of L-Dopa with improved pharmacokinetic properties, in particular a slow-release effect, as will be demonstrated by the examples which follow.



   The dose and dosage of the pharmaceutical compositions of the invention depend on the compounds chosen.



  Those skilled in the art will be able to easily adapt the doses and the posology chosen according in particular to the importance of the damage observed and the general condition of the patient.



  In principle, sufficient doses and posologies will be chosen to achieve cerebral dopamine availability values for the compounds of the invention similar to those currently recommended for the use of L-Dopa, knowing that it is currently accepted that Only one percent of L-Dopa taken orally is transformed in the central nervous system into active dopamine. It should be noted that the significant reduction in side effects resulting from a better possible use of the active ingredient thanks to the compounds of the invention makes it possible, if desired, to increase the administered dose of these compounds.



   It is also part of the invention to combine the compounds of the invention with inhibitors of peripheral dopadecarboxylase, such as benserazide or carbidopa, which makes it possible, as is known, to increase the availability of the dopamine in the brain.



   The combination of the compounds of the invention with other active compounds also falls within the scope of the invention.



     SUMMARY OF STATE OF THE ART
 It should be noted that various molecules exhibiting a certain structural similarity with those of the invention have been described in the literature. Mention may in particular be made of documents US Pat. No. 4,360,533 (A.A.

 

  patchett); US-A-4 134 991 (J.J. BALDWIN et al.) which corresponds to FR-A-2 365 341 (SYNTHELABO) US-A-4 254 273 (B.F. POWELL et al.) which corresponds to FR-A-2 313 922 (MERCK) and EP-A-0 030 734 (MFRCK).



   Among these documents only US-A-4,134,991 (J.J. BALDWIN et al.) mention an application for the treatment of Parkinson's disease.



   None of the documents predicted that the products in question would act to improve therapeutic value like the products of the invention for the treatment of Parkinson's disease.



   SYNTHESIS PROCESSES
 Different synthetic routes are possible to obtain the compounds of the invention. These synthetic routes will be illustrated with reference to the examples which follow relating to a particular compound of the invention of formula III and schematized in the appended FIG.



   Example 1: (Method A of Figure 1)
 (L)-N,O,O'-tricarbobenzyloxidopa ester of 1,3-dipalmitin (3 > .



   To a solution of 28.4 g of trihydroxy-l,2,3-propane dipalmitate (1,3-dipalmitin) (2) (50 mmol) and 30.1 g of (L)-N,O,O '-tricarbobenzyloxidopa (1) (50 mmol) in 250 ml of dichloromethane, stirred magnetically and cooled to O "C by means of an ice bath, 10.3 g of dicyclohexyl-carbodiimide (50 mmol ) and 100 mg of pyrrolidino-4-pyridine. After one hour, the ice bath is removed. The reaction mixture is then stirred for 25 hours at room temperature.



  The dicyclohexylurea precipitate is filtered off and the filtrate is washed with water (10Oml), 5% sodium bicarbonate (100 ml) (w/v), then with 0.05M hydrochloric acid (100 ml) . The organic solution is dried over magnesium sulphate, filtered and evaporated to dryness. The residue is chromatographed on silica gel and the desired compound (3) is eluted using an n-hexane:diethyl ether (70:30, v/v) mixture. After evaporation of the fractions containing 3 to dryness, the residue is recrystallized from ethanol.



  Yield = 388. The product is characterized by its melting point of 75"C and its optical rotation [a125
 D of -3.14 (C 3, methanol).



   L-dopa ester of 1,3-dipalmitin.



   I (1)
   A solution of 10.0 g of 3 in tetrahydrofuran (150 ml) is hydrogenolyzed in the presence of palladium on carbon (1.0 g) under an initial pressure of 250 kPa for 18 h. The suspension is then filtered and the filtrate is evaporated to dryness. The residue is purified by chromatography under the same conditions as for 3. Recrystallization from ethanol gives a product with a melting point of 78"C and an optical rotation [aJ25 of
 D-6.23 (C-3.2, DMF).



   Elemental Analysis (C44H77108)
 Calculated values C 70.64% found 70.61
 H 10.37 10.25
 O 17.11 16.94
 N 1.87 2.20
 Mass spectrum (m/e): 747 (M+), 477, 256,
 239.



   Example 2: (Method B of Figure 1)
 The same compound (III) can be synthesized by route B of Figure 1. The yields which still require optimization are however lower.



   Example 3: (Method C of Figure 1)
 By method C it is also possible to obtain the compound of formula III. Remarks similar to those of Example 2 also apply.



   Example 4: Pharmacological and pharmacokinetic evaluations
 The derivative obtained according to example-1 was evaluated from the point of view of its antiparkinsonian activity by means of c-ux conventional tests; the oxotremorine test and the reserpine test following the general protocol described by Horst et al. (ref. Burop.J.Pharmacol.21, 337342, 1973). In the reserpine test, efficacy is measured by inhibition of ptosis and catatonia; in the oxotremorine test by inhibition of tremor and hypothermia, the calculation of ED50 was carried out according to the classic method of Litchfield and Wilcoxon (J.Pharmacol. Exptl. Therap., 96, 69... (1949)).



   The operating protocol followed by these two tests is given below.



  A) RESERPINE TEST.



   1. Reserpine is administered i.p. at a dose of 5 mg/kg
 2. Four hours later, the compounds to be tested: L-dopa and
 its glyceride derivative are administered p.o. to
 different doses and this at the rate of five mice per
 dose.



   3. The evolution of reserpine-induced effects
 catatonia and ptosis is monitored at different times: 15,
 30, 60, 90, 120 mins.



   4:15, 30, 60, 90, 120 mins
 Reserpine L-dopa and its dericatatonia and
 Smg/kg, i.p. ve glyceride, p.o. ptosis
B) OXOTREMORINE TEST,
 1. Compounds to be tested: L-;dopa and its derivative
 glyceride are administered p,o. at different doses
 and this at the rate of five mice per dose.



   2. Oxotremorine (0.5 mg/kg i.p.) is administered to
 mice pretreated after different times: 15, 45,
 90, 120 mins.



   3. The response of animals to the effects of toxotremorine e
 hypothermia and tremor is measured respectively 15 and
 30 min after administration of the cholinergic agent
 15, 45, 90, 120 mins 15 mins 15 mins
 L-dopa and its deri- oxotremorine hypothermia tremor
 glyceride, p.o. 0.5 mg/kg, i.p.



   For these two tests, male NMRI mice weighing between 22 and 25 g were used.



   L-dopa and its glyceride derivative are administered by gavage in suspension in a 5% gum arabic solution.



   The effects observed have been reproduced in the form of graphs in Figures 2 to 5 which follow.

 

   It appears from these two tests that the glyceride derivative III − exhibits an antiparkinsonian activity substantially of the same order of magnitude, but this activity lasts for times approximately double those observed for L-Dopa.



   From a pharmacokinetic point of view, Figures 6 and 7 dramatically demonstrate the lymphotropic effect produced by the grafting of 1,3-dipalmitin onto L-Dopa. It is observed that after oral administration of an equivalent dose of 0.5 m mol/kg is
L-Dopa, or the glyceride derivative of L-dopa (III), we obtain lymphatic levels more than 40 times higher in the case of III than in that of
L-Dopa, which also appears predominantly in the form of its metabolite, dopamine.


      

Claims

1. Derivative of L-Dopa characterized in that the L-Dopa is coupled to a glycerol derivative by forming an ester bond with a glycerol hydroxyl function, at least one of the remaining hydroxyl positions being esterified by an acyl chain and the other remaining hydroxyl position also being esterified either by an identical acyl chain or different from the first, or by an esterification agent of another nature but pharmacologically acceptable. 2. Derivative of L-Dopa according to claim 1 characterized in that it corresponds to the formula (I) EMI10.1 * = form L in which R1 represents a glycerol residue and R2 and R3, which may be identical or different, represent an acyl residue comprising 10 to 20 carbon atoms or a pharmacologically acceptable acid residue, at least one of these two residues being an acyl residue comprising from 4 to 22 carbon atoms. 3. Derivative of L-Dopa according to claim 1 characterized in that it corresponds to the formula (II) EMI10.2 * = form L in which R2 and R3 represent an acyl residue containing from 4 to 22 carbon atoms. 4. Derivative of L-Dopa according to claim 3 characterized in that it corresponds to the formula (III) EMI11.1 * - L-shape 5. Derivative of L-Dopa according to claim 2 characterized in that one of the residues R2 and R3 represents an acyl residue comprising from 4 to 22 carbon atoms and the other residue represents an acid residue of another natural but pharmacologically acceptable. 6. Derivative of L-Dopa according to claim 1 characterized in that the acyl residue of L-Dopa is fixed in position 1 of glycerol. 7. Process for the preparation of derivatives of the L-Dopa according to any one of Claims 1 to 6, characterized in that a derivative of glycerol is coupled to a derivative of L-Dopa, by forming an ester bond with a hydroxyl function of the glycerol, at least one of the hydroxyl positions remaining being esterified by an acyl chain and the other remaining hydroxyl position also being esterified either by an acyl chain identical to or different from the first, or by an esterification agent of another nature but pharmacologically acceptable. 8. Use of the derivatives according to any one of claims 1 to 6 or obtained according to the process of claim 7 as an active ingredient in the treatment of Parkinson's disease or to serve as intermediate products for the characterization, purification or the synthesis of such active products, in particular by transesterification. 9. Pharmaceutical preparation, intended particularly for per os administration, characterized in that it contains at least derivatives according to any one of claims 1 to 6 or obtained according to claim 7 mixed with adjuvants, excipients and conventional carriers , and presented in the form of emulsions, suspensions, capsules or syrup. 10. Pharmaceutical preparation according to claim 9, characterized in that it also contains a peripheral dopadecarboxylase inhibitor, such as benserazide or carbidopa.