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Title:
PROCESS FOR THE PREPARATION OF CRYSTAL FORMS OF CABERGOLINE VIA NOVEL STABLE SOLVATES OF CABERGOLINE
Document Type and Number:
WIPO Patent Application WO/2008/049884
Kind Code:
A8
Abstract:
The present invention relates to a process for producing cabergoline crystal forms. The process comprises preparation of the desired solvate of cabergoline from a solution of cabergoline in chloroaromatic solvents. Afterwards cabergoline crystal form is prepared by recovery from a solvate of cabergoline by drying or with desolvating in a solvent media.

Inventors:
HAM ZORAN (SI)
CRNUGELJ MARTIN (SI)
Application Number:
PCT/EP2007/061472
Publication Date:
July 30, 2009
Filing Date:
October 25, 2007
Export Citation:
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Assignee:
LEK PHARMACEUTICALS (SI)
HAM ZORAN (SI)
CRNUGELJ MARTIN (SI)
International Classes:
C07D457/06
Attorney, Agent or Firm:
DEMSAR, Marija (Corporate Intellectual Property, Basel, CH)
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Claims:

Claims:

1. A process for the preparation of cabergoline form I comprising:

(a) preparation of a solvate of cabergoline from a chloroaromatic solvent or from a mixture of chloroaromatic solvents and a second solvent and isolating the solvate of cabergoline,

(b) conversion of a solvate of cabergoline to unsolvated cabergoline crystal form by desolvating of solvate of cabergoline with gradual drying or with desolvating in a solvent media, wherein chloroaromatic solvents are chlorobenzene and 2-chlorotoluene.

2. The process according to claim 1 wherein the second solvent is selected form a group of hydrocarbons or ethers.

3. The process according to claim 1 wherein isolating of a solvate of cabergoline comprising cooling a mixture, addition of a third solvent and separation of the product from a solution.

4. The process according to claim 3 wherein cooling means cooling to a temperature of from -15 to -25 5 C.

5. The process according to claim 3 wherein separation method is selected from a group of filtration, decantation and centrifugation.

6. The process according to claim 1 wherein the solvate is 2-chlorotoluene solvate and the gradual drying in step (b) is performed at the temperature range of from 20 to 30 -C.

7. The process according to claim 1 and 6 wherein drying in step (b) is performed at a lower pressure.

8. The process according to claim 1 wherein the solvate is chlorobenzene solvate and gradual drying in step (b) is performed at lower pressure at the temperature range of from 55 to 70 5 C in which temperature rises up to 5 5 C per day .

9. The process according to claim 1 wherein the solvate is chlorobenzene solvate and desolvating in a solvent media is performed in a temperature range between 40 and 70 5 C.

10. The process according to claim 1 wherein solvent for solvent media is selected from a group of group of alkane, cycloalkane or ether.

1 1.The process according to claim 10 wherein alkane is n-heptane.

12. The process according to claim 10 wherein ether is diethylether.

13. A process for the preparation of cabergoline form VII comprising:

(a) preparation of solvate of cabergoline from chloroaromatic solvent to obtain chloroaromatic solvate of cabergoline;

(b) conversion of chloroaromatic solvate of cabergoline to cabergoline crystal form VII by drying at higher temperature, wherein chloroaromatic solvents are chlorobenzene and 2-chlorotoluene.

14. The process according to claim 13 wherein the conversion of chloroaromatic solvate of cabergoline at step b) is carried out with drying at the temperatures from 50 to 70 °-C.

15. Chlorobenzene solvate of cabergoline.

16.2-Chlorotoluene solvate of cabergoline.

17. Chlorobenzene solvate of cabergoline which is characterized by an X-ray diffraction pattern shown in figure 1.

18. Chlorobenzene solvate of cabergoline which is characterized by the following d-values at X-ray diffraction; 10,0 ± 0,1 ; 6,1 ± 0,1 ; 5,2 ± 0,1 ; 4,65 ± 0,01 ; 4,20 ± 0,01 , 4.05 1 0,01

19.2-Chlorotoluene solvate of cabergoline which is characterized by an X-ray diffraction pattern shown in figure 4.

20. Chlorotoluene solvate of cabergoline which is characterized by the following d- values at X-ray diffraction; 1 1 ,4 ± 0,1 ; 7,8 ± 0,1 ; 5,9 ± 0,1 ; 5,2 ± 0,1 ; 4,27 ± 0,01 ; 3,67 ± 0,01.

Description:

PROCESS FOR THE PREPARATION OF CRYSTAL FORMS OF CABERGOLINE VIA NOVEL STABLE SOLVATES OF CABERGOLINE

FIELD OF THE INVENTION

The present invention relates to the novel solvates of cabergoline and to the process for their conversion into pharmaceutically acceptable crystal forms and to pharmaceutical compositions containing them.

BACKGROUND OF THE INVENTION

Cabergoline is the generic name of the compound 1 ((6-allylergolin-8β-yl)-carbonyl)-1 - (3-dimethylaminopropyl)-3-ethylurea (Formula 1 ),

Formula 1

which belongs to the field of pharmaceutical agents for treatment of Parkinson's disease, Restless legs sindrome, treatment of diseases like progressive supranuclear palsy and multisystematic atrophy. The compound was firstly described in the U.S. Patent No. 4,526,892. Eur.J.Med.Chem., 24,421 and GB-2,103,603-B reported the synthesis of cabergoline as well. Il Farmaco, 50 (3), 175-178 (1985) described cabergoline crystal form, which was prepared as transparent plates from diethylether and was later designated as crystal form I. Cabergoline was later described in several crystalline forms. The patent application WO 01/70740 describes form V as a toluene solvate and the process of its desolvatation into crystal form I, WO

03/078392 describes form X as another toluene solvate and the process of conversion into form I. WO 01/72747 describes form Il and its preparation. WO 01/72746 describes crystal form VII and the process of preparing it. WO 2004/101510 discloses amorphous cabergoline and several new crystalline forms of cabergoline such as form VIII (methyl tert-butyl ether solvate), form Xl (xylene solvate), form XII (o-xylene solvate), form XIV (tetrahydropyrane solvate), form XV (cyclohexane solvate), form XVI (p-xylene solvate), form XVII (1 ,2,4- thmethylbenzene solvate), form XVIII (ethylbenzene solvate) and their preparation. WO 2004/094368 discloses new forms of cabergoline (solvate form A (methyl tert- butyl ether solvate) and an amorphous form, free of crystalline cabergoline.

For pharmaceutical use there is a permanent need for preparation of active pharmaceutical ingredients which are free of impurities and residual solvents and which are stable during technological process for the preparation of a final dosage form. Also pharmaceutical ingredients must stay stable during storage. Above mentioned cabergoline solvates are therefore not acceptable for final dosage forms as they contain solvates. Only acceptable forms of cabergoline are crystal form I, form Il and form VII that are unsolvated forms. There is also a need to prepare an intermediate form which could be easily purified and stays stable for a long time. It should be also easily transformed into an unsolvated, pharmaceutically applicable form. We solved that problem by an invention disclosed inhere.

Summary of the invention

One aspect of the present invention is a process for the preparation of unsolvated crystal form of cabergoline comprising:

(a) preparation of a solvate of cabergoline from a chloroaromatic solvent or from a mixture of chloroaromatic solvents and a second solvent and isolating the solvate of cabergoline,

(b) conversion of a solvate of cabergoline to unsolvated cabergoline crystal form by desolvating of solvate of cabergoline with drying or with desolvating in a solvent media.

Preferable chloroaromatic solvents are chlorobenzene and 2-chlorotoluene.

Another aspect of the invention is a process for the preparation of cabergoline crystal form I comprising: a) preparation of the solvate of cabergoline from chloroaromatic solvent or from a mixture of solvents to obtain chloroaromatic solvate of cabergoline; b) conversion of chloroaromatic solvate of cabergoline to cabergoline form I by desolvating of solvate of cabergoline with gradual drying or with desolvating in a solvent media.

Preferable chloroaromatic solvents are chlorobenzene and 2-chlorotoluene.

Another aspect of the invention is a process for the preparation of cabergoline Form VII comprising: c) preparation of solvate of cabergoline from chloroaromatic solvent to obtain chloroaromatic solvate of cabergoline; d) conversion of chloroaromatic solvate of cabergoline to cabergoline crystal form VII by drying at higher temperature.

Preferable chloroaromatic solvents are chlorobenzene and 2-chlorotoluene.

Another aspect of the invention is a chlorobenzene solvate of cabergoline.

Another aspect of the invention is a 2-chlorotoluene solvate of cabergoline.

Another aspect of the invention is cabergoline form I used for the preparation of pharmaceutical composition.

Another aspect of the invention is a method for preparing a pharmaceutical composition comprising combining an amount of cabergoline form I and at least one pharmaceutical acceptable carrier.

Another aspect of the invention is a pharmaceutical composition comprising cabergoline form I used for a treatment of Parkinson's disease, restless legs

sindrome and treatment of progressive supranuclear palsy and multisystematic atrophy and for treating D2 dopamine receptor associated disorders.

Description of the figures

Figure 1 : X-ray powder diffraction pattern of chlorobenzene solvate of cabergoline prepared by example 1

Figure 2: Infrared spectrum of chlorobenzene solvate of cabergoline obtained by experiment prepared by example 1

Figure 3: Differential scanning calohmetry pattern of chlorobenzene solvate of cabergoline prepared by example 1

Figure 4: X-ray powder diffraction pattern of 2-chlorotoluene solvate of cabergoline prepared by example 2

Figure 5: X-ray powder diffraction pattern of cabergoline crystal form I prepared by example 3

Figure 6: Infrared spectrum of cabergoline form I prepared by example 3

Figure 7: Differential scanning calorimetry pattern of cabergoline form I prepared by example 3

Figure 8: X-ray powder diffraction pattern of cabergoline form VII prepared by example 7.

Detailed description of the invention

The present invention provides a simple and efficient process for the preparation of new, well defined and for a long term stable solvates of cabergoline with high yields and their conversion into unsolvated forms of cabergoline crystal forms. Crystal forms prepared by the process disclosed in this invention are cabergoline form VII defined in a patent application WO 01/72746 and crystal form I disclosed in Il Farmaco, 50 (3), 175-178 (1985) and also in other literature disclosed above. The new solvates of cabergoline are prepared from chloroaromatic solvents, preferably from chlorobenzene and 2-chlorotoluene. The chlorobenzene and 2-chlorotoluene solvates are easily prepared with high yield and are transformed into unsolvated cabergoline, preferably into crystal form I and crystal form VII.

Thus, a process for the preparation of unsolvated cabergoline crystal form according to the present invention comprises the steps of:

(a) preparation of a solvate of cabergoline from a chloroaromatic solvent or from a mixture of one of chloroaromatic solvent and a second solvent and isolating the solvate of cabergoline and

(b) conversion of a solvate of cabergoline to unsolvated cabergoline crystal form by desolvating with drying or conversion of solvate of cabergoline to cabergoline crystal form with desolvating in alkane or ether solvent media.

Preparation of a solvate of cabergoline

For the starting cabergoline any known form like crystalline, amorphous, oil or mixture thereof could be used. The process comprises dissolving cabergoline at room temperature in chloroaromatic solvent, selected from a group of chlorobenzene and 2-chlorotoluene or in a mixture of chloroaromatic solvent and a second solvent to obtain a clear solution. An amount of chloroaromatic solvent used is from 2 to 5 ml of chloroaromatic solvent per gram of cabergoline. The second solvent is a solvent selected from a group of hydrocarbons or ethers, preferably from aliphatic hydrocarbons such as heptane.

Afterwards the obtained solution is cooled down to -10 to -30 5 C, preferably to -15 to -25 5 C, more preferably to -20 5 C and let stand for at least 1 hour. During this period a precipitation of a solvate occurs. For the isolation of obtained solvate of cabergoline the mixture is diluted by a third solvent selected from a group of hydrocarbons such as n-heptane, n-heksane, n-pentane, cyclopentane, cyclohexane or methylcyclohexane. Third solvent is added in an amount of 20 ml of third solvent per gram of cabergoline. The mixture is further stirred for 2 to 12 hours, preferably 2 hours at the temperature -10 to -30 5 C, preferably to -15 to -25 5 C, more preferably to -20 5 C. The obtained product is isolated by removing of the solvent by a separation method preferably by filtration and alternatively by decantation or centrifugation. The most preferably used separation method is a filtration through a cold filter under higher pressure. The obtained solid cabergoline substance is identified as solvate of

cabergoline with above described chloroaromatic solvent, i.e. selected from a group of chlorobenzene and 2-chlorotoluene.

Cabergoline solvate with chloroaromatic solvents can be additionally purified by recrystallization from mother solvent, by digestion or by washing with inert solvent such as aliphatic hydrocarbons, preferably by heptane and methylcyclohexane in order to improve chemical purity. For example chlorobenzene solvate can be suspended in heptane for 1 -5 hours to yield highly crystalline white powder with total impurity amount bellow 0,3 %.

Formation of cabergoline crystal form

Although desolvatation of a solvate is usually a routine process for a skilled person the desolvatation of cabergoline solvates may cause problems due to high number of polymorphs and their interconvertability. Many procedures described in literature suffer on repeatability. Selecting the solvates of the present invention and following the procedure of desolvatation leads repeatedly to the particular nonsolvated form.

Thus solvates of cabergoline can be transformed from solvated form to unsolvated cabergoline crystal form by three following methods.

First method comprises desolvatation carried out with heating of free chloroaromatic solvate of cabergoline at a lower pressure.

Cabergoline crystal form I may be prepared by careful drying of solvate of cabergoline beginning at room temperature (20-25 5 C) with very slow gradual rising of temperature up to the desolvatation point. The process is carried out at lower pressure i.e. bellow 100 mbar, preferably at 1 to 10 mbars, preferably at 1 do 5 mbars, more preferably at 1 mbar with prolonged drying for at least for 72 h at 70 5 C.

In a case of desolvatation of 2-chlorotoluene cabergoline solvate it is dried from 20 to 30 5 C for 72 hours. The product obtained is cabergoline crystal form I.

In a case of desolvatation of chlorobenzene cabergoline solvate gradual desolvatation should be carried out below the desolvatation point at 70 5 C and temperature should be slowly increased (up to 5 5 C per day) from 55 5 C to 70 5 C to ensure that chlorobenzene is being removed gradually with simultaneous transformation into form I, preferably drying in high vacuo at 55 5 C, 60 5 C, 64 5 C, 66 5 C, 68 5 C, 70 5 C, each temperature for 24 h. The product obtained is cabergoline crystal form I.

Variation of above process for the preparation of cabergoline crystal form by heating is drying of free chloroaromatic solvate of cabergoline starting between 40 and 70 5 C, more preferably between 50 and 60 5 C and most preferably at 55 5 C for 24 h to obtain cabergoline crystal form VII.

The second method for a desolvatation comprises desolvatation of chloroaromatic solvate of cabergoline carried out in a solution of liquid alkane or cycloalkane. Alkane or cycloalkane used are selected from a group of n-heptane, n-hexane, n-pentane, cyclopentane, cyclohexane or methylcyclohexane. An amount of used alkane or cycloalkane is 30 to 50 ml of alkane or cycloalkane per 1 g of solvate of cabergoline prefereably 40 ml of alkane or cycloalkane per 1 g of solvate of cabergoline. The product obtained after careful desolvatation is identified as cabergoline form I. The preferable temperature of desolvatation in n-heptane media is from -5 to +5 5 C for 2- chlorotoluene solvate and 50 Q to 60 5 C for chlorobenzene solvate.

The third method comprises desolvatation of a chloroaromatic solvate of cabergoline at around 0 5 C in ether solution, preferably in diethyl ether using seeds. Therefore chloroaromatic solvate of cabergoline is dissolved in ether and the solution is concentrated to a lower volume followed by the addition of seeds of cabergoline crystal form I. The mixture is then cooled to -25 to -15 °C. Afterwards an alkane preferably n-heptane precooled to -25 to -15 5 C is added dropwise while stirring in the time of 1 to 2 hours. The suspension is stirred for next 6 to 7 hours at -25 5 C. Finally the suspension was filtered and dried in vacuo at 40 5 C. Obtained product is cabergoline crystal form I.

A similar method of preparation of form I can be applied with more soluble forms without concentration of the solvent. Form I can be obtained from concentrated diethylether solution, which is prepared from amorphous cabergoline. Cabergoline from solution is loaded onto seeds of cabegoline form I, below -15 5 C to obtain additional quantity of form I. Procedure begins with suspending of cabergoline form I in diethylether at temperatures below -15 5 C, preferably below -20 5 C, most preferably below -25 -C in amount between 1 g of form I and 30 ml diethylether and 1 g of form I and 2,5 ml of diethylether, preferably in amount between 1 g of form I and 20 ml diethylether and 1 g of form I and 5 ml of diethylether and most preferably in amount of 1 g of form I and 10 ml diethylether. Afterwards amorphous or oily cabergolin is added in amount not exceeded three times as amount of starting cabergoline form I. After entirely amorphous cabergoline is dissolved the liquid alkane or cycloalkane, for example n-heptane, n-hexane, n-pentane, cyclopentane, cyclohexane or methylcyclohexane is added slowly dropwise in the suspension. The amount of alkane should be equal as amount of diethylether. The stirring after complete addition of alkane should continue at least 4 hours, preferably 6 hours, most preferably 12 hours. Further the suspension is filtered and dried in vacuo at 40 Q C.

Cabergoline form I prepared according to this invention can be used for the preparation of pharmaceutical composition. A pharmaceutical composition can be prepared containing cabergoline form I and at least one pharmaceutical acceptable carrier. Pharmaceutical composition comprising cabergoline form I prepared according to this invention can be used for a treatment of Parkinson's disease, restless legs sindrome and treatment of progressive supranuclear palsy and multisystematic atrophy and for treating D2 dopamine receptor associated disorders.

The embodiment of the invention is characterized but not limited by the following experimental examples:

Example 1 : Preparation of chlorobenzene solvate of cabergoline

2,15 g of cabergoline were dissolved in 8 ml of chlorobenzene by agitating at room temperature. The solution was cooled down to -20 5 C while stirring. The gel-like material was formed after 15 minutes. Furthermore 40 ml of n-heptane were added and let stirring 1 hour. The obtained fine suspension was filtered and washed with 20 ml of cold (-15 5 C) n-heptane. The obtained product (2,03 g) was identified as chlorobenzene solvate of cabergoline with 0,34 % of total impurities.

The product can be recrystallized from hot chlorobenzene/heptane mixture to yield cabergoline solvate with 0,13 % of total impurities.

Chlorobenzene solvate of cabergolin is characterized by the following characteristic peaks in XRD diffractogram with values:

2θ angle d Ul

8.9 10.0 100

14.4 6.1 13

16.9 5.2 50

19.1 4.65 37

21.1 4.20 64

21.9 4.05 20

The characteristic desolvatation endothermic peak in DSC is detected with onset at 67 5 C. The characteristic peak in IR spectrum, appeared at 765 cm "1

Example 2: Preparation of 2-chlorotoluene solvate of cabergoline

The foamy evaporation containing 1 g of pure cabergoline was dissolved in 2 ml of 2- chlorotoluene. The solution was under stirring cooled to a temperature of -15 5 C and subsequently seeded with form I. After 10 minutes of stirring crystalline slurry was obtained and 10 ml of n-hexane was added into the suspension. The obtained precipitate was filtered and 2-chlorotoluene solvate of cabergoline was obtained which was identified by XRD data.

2-Chlorotoluene solvate of cabergoline is characterized by the following characteristic peaks in XRD diffractogram with values:

2θ angle d | re .

7.8 11.4 67

1 1.4 7.8 18

15.1 5.9 36

16.9 5.2 83

20.8 4.27 100

24.2 3.67 28

Example 3: Preparation of cabergoline form I with drying

2,03 g of chlorobenzene solvate of cabergoline was placed in the vacuum dryer and dryed according to the following program:

24 hours at 55 -C and 2 mbar

24 hours at 60 5 C and 2 mbar

24 hours at 65 5 C and 2 mbar

24 hours at 67 5 C and 2 mbar

92 hours at 70 5 C and 2 mbar

The obtained product (1 ,87 g) was identified with X-ray diffractometry as cabergoline form I.

Example 3: Preparation of cabergoline form I with drying

2,08 g of 2-chlorotoluene solvate of cabergoline was placed in the vacuum dryer and dried at 30 5 C for one hour. Separated liquid was poured out after while the temperature was carefully raised to 60 5 C and dried for 24 h at 1 mbar. The hard mass was grinded to powder which was washed by 5 ml of hexane to yield after filtration 1 ,86 g of fine powder identified with X-ray diffractometry as cabergoline form

Example 4: Preparation of cabergoline form I with desolvatation in n-heptane

1 ,0 g of chlorobenzene solvate of cabergoline was placed in 40 ml of n-heptane and stirred at 55 5 C. Cabergoline solvate was desolvated and converted into a compact

substance after couple of minutes. Cabergoline was dried after the decantation of the solvent and identified as cabergoline form I. The yield was above 90 %.

Example 5: Preparation of cabergoline crystal form I in diethylether

1 ,0 g of cabergoline form I, prepared by example 4, was placed in the vessel and 6 ml of diethylether precooled to -35 5 C were added. Paralelly 1 ,2 g of cabergoline chlorobenzene solvate from example 2 was dissolved in 20 ml, concentrated to 6 ml, cooled to -15 5 C and added to. the suspension of form I. The mixture was stirred at - 15 5 C for 1 hour. Afterwards 5 ml of n-heptane precooled to -25 5 C were added dropwise while stirring in the time of 1 hour. The enriched suspension was stirred for next 6 hours at -25 5 C. Finally the suspension was filtered and dried in vacuo at 40 5 C to obtain 1 ,8 g of cabergoline form I.

Example 6: Preparation of cabergoline crystal form I in diethylether

1 ,0 g of cabergoline form I, prepared by example 4, was placed in the vessel and 10 ml of diethylether precooled to -35 5 C were added. The suspension was stirred for 1 hour. Further 1 ,0 g of amorphous cabergoline from example 1 was added in four portions in the suspension at -25 5 C. The suspension was stirred at the same temperature for 1 hour. Afterwards 4 ml of n-heptane precooled to -25 5 C were added dropwise while stirring in the time of 1 hour. The enriched suspension was stirred for next 6 hours at -25 5 C. Finally the suspension was filtered and dried in vacuo at 40 5 C. Obtained product is cabergoline form I.

Example 7: Preparation of cabergoline crystal form VII with drying

1 ,0 g of chlorobenzene solvate of cabergoline was heated at 60 5 C and 100 kPa 24 hours. The obtained product was characterized as cabergoline form VII.

The products were analysed by following methods: X- Ray diffraction Method:

Conditions for obtaining powder x-ray diffraction (XRD) patterns: The powder x-ray diffraction patterns were obtained by methods known in the art using Philips X'Pert PRO diffractometer with X'Celerator detector using CuKa radiation (tube operating at 45 kV and 40 mA) in the Bragg-Brentano (reflection) geometry. Data were recorded from 2 to 40 °2θ in steps of 0.033 °2θ and the measurement time of 50 seconds per step. Variable divergence and antiscatter slits were used to maintain 12 mm of sample length irradiated.

IR spectroscopy Method:Conditions for obtaining infrared spectra: Fourier transform infrared (FTIR) spectra were recorded with a Nicolet Nexus spectrometer. Spectra over a range of 4000 to 400 cm "1 with a resolution of 2 cm "1 (16 scans) were recorded on KBr tablets.

Differential Scanning calorimetry:

Conditions for obtaining DSC thermograms: Thermograms were obtained with Mettler Toledo DSC822 θ differential scanning calorimeter. The sample (4-6 mg) was placed in an unsealed aluminium pan with a hole and heated at 5 °C/min in the temperature range from 30 °C to 200 °C.