The invention relates to the field of pharmaceutical patch formations, in particular patch formulations containing rasagiline or derivatives or analogues thereof.
Rasagiline, a selective inhibitor of monoamine oxidase-B, is known for the treatment of central nervous system diseases such as Parkinson's disease (PD), depression, etc., and has gone on sale in Europe. The chemical structure of rasagiline is as follows:
Rasagiline is the active ingredient in the anti Parkinson medicament market in Europe under the brand name Azilect®. This is a tablet which contains a salt of rasagiline, namely the rasagiline mesylate. The tablet has to be taken once daily.
Since the majority of Parkinson patients have difficulties in walking and oral taking, it is desirable to formulate rasagiline in a transdermal administration so that rasagiline may be administered less frequently than every other day or more. Desirable is an administration which is for example only twice or once a week.
The administration of an active ingredient (active pharmaceutical ingredient) as a patch formulation requires that the active ingredient can sufficiently penetrate the skin. In case of rasagiline this is thought to require the use of the free base, since the solubility of the salt thereof in a lipophilic polymer matrix used in transdermal patch formulation as well as its penetration into the skin is too little.
WO2007/101400 A1 describes a transdermal patch formulation containing rasagiline salt. In order to overcome the drawbacks thereof in terms of limited solubility and penetration rate into the skin, this patent application suggests to further add a penetration regulator and a penetration enhancer into the patch formulation. If rasagiline free base is contained in the formulation of WO2007/101400 A1 it is in situ converted from the rasagiline salt into the free base by the addition of bases. However this conversion is disadvantageous since it requires additional steps in the manufacture process and furthermore raises unwanted regulatory hurdles since the conversion may be incomplete.
The patch formulation of WO2007/101400 A1 can either be manufactured according to the standard hot melt technique or according to the standard solvent/casting/drying process. In the hot melt technique, the active ingredient is added to a melted polymer material at a temperature of 50 to 200° C. The molten material is then applied to an inert backing layer and cooled to form the substrate layer. In the solvent/casting/drying technique, the active ingredient is dispersed in a volatile solvent first, and then an organic polymer material is added to the solution. This mixture then is used to form the substrate layer, whereby the solvent is evaporated. The drying step may be performed after the substrate layer has been formed and usually involves temperatures of 50 to 120° C. Such elevated temperatures are considered to be essential for completing the drying procedure at all or at least quickly enough to allow an economically reasonable manufacturing process.
The inventors now found, that applying these techniques to the manufacture of a patch formulation containing the free base of rasagiline inevitably leads to a substantial loss of the active ingredient, which can even be up to 90 or 95% of the originally introduced amount of the active ingredient. This is most likely due to the volatility of the active ingredient causing the active ingredient to sublime or to evaporate during the manufacturing process or to be carried along with evaporating solvent during a drying step. Rasagiline base has a low melting point of 42° C. and is known to sublimate already at low temperatures (e.g. lower than 42° C.). Consequently, the manufacture of transdermal patch formulations comprising rasagiline base according to the standard hot melt technique or according to the standard solvent/casting/drying process is not possible in a reasonable way.
Thus, it is objective of the present invention to provide novel means for the manufacture of transdermal patch formulations, in particular patch formulations containing an active ingredient/drug substance with a high volatility, in particular the free base of rasagiline, which allows for a reduced loss of active ingredient. In particular this manufacture process should be simple and easy to perform, quick, precise, non-hazardous and/or economical. It is furthermore desired that the resulting transdermal patch is comfortable for a patient to apply and/or to wear, safe, allows an extended wearing time, an effective skin permeation of the active pharmaceutical ingredient and/or an extended period in which the administered amount of active pharmaceutical ingredient increases linearly with wearing time.
This objective is solved by the method according to claim 1. Further embodiments of the invention are subject matter of additional independent or dependent claims. Furthermore novel and favourable patch formulations are suggested.
The core concept of the invention is based on the findings that an incubation of the volatile active ingredient in retaining means before admixing the active ingredient into the polymer matrix (“carrier material”) of the patch formulation or—generally spoken—before applying the active ingredient to the polymer matrix of the patch formulation results in a substantially reduced loss of active ingredient during the manufacture process. Due to this pre-incubation of the active ingredient in a retaining means the recovery rate of the active ingredient in the final patch formulation is significantly increased compared to the known processes. The recovery rate according to the invention is at least 20%, favourably at least 50% or 70%. Most preferably the recovery rate is at least 80% or even 100%. In this context, the term incubation or pre-incubation preferably refers to a stage in which the active ingredient is contacted with the retaining means to form a composition before this composition is applied to a pre-existing layer of the polymer matrix. The composition preferably does not contain material identical to polymer matrix to which the composition is to be applied.
From the above said it is apparent that the polymer matrix (carrier material) is not a backing layer or a release layer.
Preferably, before the composition comprising the active ingredient is applied to the polymer matrix (carrier material), the polymer matrix is dry. This preferably means that, before applying the composition, the polymer matrix is touch dry, more preferably that it contains less than 2%, 1%, 0.5%, 0.2% or 0.1% or does not contain any solvent, and even more preferably that it contains more than 98%, 99%, 99.5%, 99.8% or 99.9% or only solid components. In a preferred embodiment, the carrier material is a dried layer of polymer matrix, preferably a dried layer of adhesive polymer matrix.
The objective of the present invention can be achieved, in contrast to the standard hot melt technique and in contrast to the standard solvent/casting/drying process, by a method in which at first the active pharmaceutical ingredient is left out when forming the layer containing the polymer material and instead the active pharmaceutical ingredient is applied afterwards. In particular, the active pharmaceutical ingredient should not be present during the high-temperature drying step required for the carrier material (polymer matrix). According to the invention, in particular by applying the active pharmaceutical ingredient to a dry polymer matrix, it is possible to avoid subsequent drying at increased temperatures. Thus, in the method according to the invention preferably no drying at a temperature higher than 50° C., 45° C., 40° C. or 35° C. is performed after the composition comprising the active pharmaceutical ingredient has been applied to the carrier material. Preferably, for the active pharmaceutical ingredient either a solvent is chosen that evaporates well at room temperature or a manufacturing process is chosen that does not require drying.
The composition provided by contacting the active pharmaceutical ingredient with the retaining means either migrates into the carrier material, preferably completely, or remains on its surface. The substrate layer formed may—preferably in the case when a liquid retaining means is used—result from the mentioned composition blending with (e.g. soaking into) the carrier material so that the composition and the carrier material together form a single homogeneous or substantially homogeneous substrate layer. Alternatively, the substrate layer formed may—preferably in the case when a solid retaining means is used—result in an extra layer, which is separate or substantially separate from the carrier material.
Advantageously the transdermal patch according to the invention containing the retaining means does not require any further additive such as penetration enhancers or penetration regulators to provide a sufficient penetration of the active ingredient into the skin.
The method according to the invention is suitable for any active ingredients or mixtures thereof. However, it is preferably used to prepare transdermal patches with volatile active pharmaceutical ingredients, in particular carbamates such as rasagiline or its derivatives or analogues, preferably in the form of the free base. A volatile active pharmaceutical ingredient is any drug substance either with a melting point at room temperature of below 100° C. and/or which evaporates at a temperature of more than 30° C., more than 50° C. or more than 70° C.
The active pharmaceutical ingredient used in the present invention preferably has a chemical structure according to one of the following formulas:
wherein
R1 is hydrogen, halogen, alkyl, alkoxy, acyl, acyloxy, aryl, aralkyl, hydroxy, carboxy, amine, alkylamine, dialkylamine, nitro, or —OC(O)NR12R13, and may be substituted by one or more substituents selected from alkyl, halogen, hydroxy, carboxy, amine, alkylamine, dialkylamine;
R2, R3, R4, R5, R6, R12 and R13 independent from each other are hydrogen, halogen or alkyl.
One or more, preferably one or two, of the carbon atoms in the formula including the substituents may be replaced by a heteroatom such as nitrogen, oxygen or sulfur. Preferably, R1 is hydrogen or —OC(O)NR12R13, wherein R12 and R13 preferably are methyl and/or ethyl, more preferably R12 is methyl and R13 is ethyl. R2, R3, R4, R5 and R6 each preferably are hydrogen.
wherein
R7 is hydrogen, halogen, alkyl, alkoxy, acyl, acyloxy, aryl, aralkyl, hydroxy, carboxy, amine, alkylamine, dialkylamine, nitro, or —OC(O)NR14R15, and may be substituted by one or more substituents selected from alkyl, halogen, hydroxy, carboxy, amine, alkylamine, dialkylamine;
R8, R9, R10, R14 and R15 independent from each other are hydrogen, halogen or alkyl, wherein if more than one R9 is present, these R9 groups may also be different from each other;
R11 is hydrogen, halogen or alkyl optionally substituted by halogen or hydroxy;
n is an integer from 1 to 4, preferably 1 or 2.
One or more, preferably one or two, of the carbon atoms in the formula including the substituents may be replaced by a heteroatom such as nitrogen, oxygen or sulfur. Preferably, R7 is hydrogen or —OC(O)NR14R15, wherein R14 and R15 preferably are methyl and/or ethyl, more preferably R14 is methyl and R15 is ethyl. R8 preferably is hydrogen. R9 preferably is hydrogen or methyl, n preferably is 1 or 2. The group —[CHR9]n— preferably is —CH2—CH(CH3)— or —CH(CH3)—. R10 preferably is 2-propynyl (—CH2—C≡CH) or methyl. R11 preferably is methyl.
Racemic mixtures as well as isolated stereochemical forms of the above structures are encompassed by the formulas, including any isomers, stereoisomers, diastereoisomers and enantiomers.
Halogen preferably refers to fluorine, chlorine, bromine or iodine. Alkyl refers to a saturated or partially unsaturated, linear or branched carbohydrate chain preferably comprising 1 to 20 carbon atoms, more preferably 1 to 10, or 1 to 6 carbon atoms, and most preferably 1 to 4 carbon atoms. Alkyl includes unsaturated carbohydrate chains, i.e. alkenyl and alkynyl, having one or more carbon-carbon double bonds and/or one or more carbon-carbon triple bonds. Examples of alkyl are methyl, ethyl, n-propyl, isopropyl, n-butyl, tert, butyl, pentyl, hexyl, vinyl, and 2-propynyl. Alkoxy refers to the group —O-alkyl. Acyl refers to —C(O)-alkyl. Acyloxy refers to the group —OC(O)-alkyl. Aryl refers to an aromatic carbocyclic group preferably having 6 to 20 carbon atoms, more preferably 6 to 10 carbon atoms, having a single ring or multiple rings or multiple condensed rings. Examples are phenyl, naphthyl and biphenyl. Aralkyl refers to the group -alkyl-aryl.
The active pharmaceutical ingredient preferably is rasagiline or a derivative or analogue thereof. Exemplary derivatives or analogues of rasagiline are:
Ladostigil (TV3326, [(N-propargyl)-(3R)-aminoindan-5-yl]-ethyl methyl carbamate)
TV3279 [(N-propargyl)-(3S)-aminoindan-5-yl]-ethyl methyl carbamate
Selegiline (R)—N-methyl-N-(1-phenylpropan-2-yl)prop-2-yn-1-amine
The retaining means are defined as any substance matter which either chemically or physically interacts with the active ingredient and therewith or thereby prevents its evaporation or sublimation from the polymer matrix, in particular during the manufacturing process. Preferred is a substantial interaction with the active ingredient. “Preventing evaporation or sublimation” in the context of the invention means, that the recovery rate of the active ingredient at room temperature and after the manufacture process is at least 20%, favourably at least 50% or 70%. Most preferably the recovery rate is at least 80% or even 100%.
The retaining means may be a solid or liquid substance having e.g. the active pharmaceutical ingredient attached or bound to its surface or incorporated into its body.
Suitable liquid retaining means are e.g. selected from the group consisting of natural or synthetic oils, fatty alcohols such as e.g. polidocanol, isopropyl myristate, polyalkoxylated fatty acids and polyalkoxylated fatty alcohols (in particular polyethoxylated fatty acids and fatty alcohols) with lower molecular weight, i.e. a molecular weight which renders them liquid at room temperature, and mixtures thereof. Suitable liquid retaining means have a low vapour pressure. Preferably they are compatible with the carrier material to which they are to be applied.
Suitable solid retaining means are selected e.g. from the group consisting of Eudragit polymers (such as Eudragit EPO), PVP, PEO, PVA, cellulose or derivatives, starch or derivatives, PVPVA or their blends, polyalkoxylated fatty acids and polyalkoxylated fatty alcohols (in particular polyethoxylated fatty acids and fatty alcohols) with higher molecular weight, i.e. a molecular weight which renders them solid at room temperature, and mixtures thereof. Solid and liquid retaining means can also be mixed.
The physical state of the retaining means (liquid/solid) is well known to a person skilled in the art being a function of molecular weight.
When solid retaining means are used, the step of contacting an active pharmaceutical ingredient with a retaining means to provide a composition preferably involves preparing a solution or suspension comprising the active pharmaceutical ingredient and the retaining means in a highly volatile solvent (such as acetone, ethyl acetate or cyclohexane). In such a case, the method for preparing the transdermal patch preferably comprises the step of drying the formed substrate layer of the transdermal patch. The use of a highly volatile solvent allows for drying at low temperatures, preferably lower than 50° C., 45° C., 40° C. or 35° C. Preferred temperature ranges are e.g. 20 to 50° C., 20 to 45° C., 20 to 40° C., 20 to 35° C., 25 to 45° C., 25 to 40° C., 25 to 35° C., 30 to 40° C. or 30 to 35° C.
Solid retaining means allow for drying the substrate layer at room temperature, leading to a decreased loss of active pharmaceutical ingredient. Solid retaining means also allow for precise manufacturing of the transdermal patch. It is possible to manufacture the respective solid layers separately and to join the finished layers afterwards, e.g. by laminating. This results in a lower variation of the desired layer thickness as compared to the case when multiple layers are manufactured directly on top of each other.
The retaining means may be covered or coated with the active pharmaceutical ingredient in any manner known in the art, for example by applying the active pharmaceutical ingredient in a molten state and solidifying it, by applying a solution of the active pharmaceutical ingredient and drying it, or by any other method. The incorporation of the active pharmaceutical ingredient into the retaining means may be achieved by melting both materials, mixing them and cooling the mixture, or by solving both materials in the same solution and drying (e.g. spray-drying) the solution. The resulting composition can then be applied to the polymer matrix.
In a preferred embodiment the retaining means is a liquid with a low volatility (“low volatile solvent”). This is defined as any substance that is liquid from room temperature up to 70° C.
As a carrier material (“polymer matrix”) any common or suitable material may be used. The mixture including the active ingredient and the retaining means are added to the polymer matrix to form the “substrate layer” of the final transdermal patch.
Preferably, the carrier material comprises at least one type of the following polymer materials: polyacrylates and derivatives thereof, silicone polymers and derivatives thereof, polyisobutylene (PIB) and derivatives thereof, ethylene-vinyl acetate copolymers and derivatives thereof, Styrene-block-co-polymers and derivatives thereof, polyacrylic acids and derivatives thereof, polyoxazolines (POX) and derivatives thereof, poylurethanes and derivatives thereof, polyolefines and derivatives thereof, polyesters and derivatives thereof.
The carrier material may be adhesive, thus constituting the support layer for the active ingredient as well as the adhesive layer for the adherence of the patch to the skin. It can also be non-adhesive. Then a separate adhesive layer has to be incorporated into the transdermal patch.
In one embodiment of the invention, the retaining means may be a liquid. In this case, the active pharmaceutical ingredient can be solved or dispersed first in the retaining means, forming a solution or suspension. Then the carrier matrix is soaked with the solution or suspension.
To aid the soaking process, well known soaking additives such as Plastoid B, Eudragit polymers, SiO2, PEO, PVP, PVA, cellulose or derivatives, starch and derivatives, cyclodextrins and the like, either alone or in combination may be added to the carrier material or to the solution/suspension comprising the active pharmaceutical ingredient (drug). A soaking additive added to the carrier may help in preventing softening of the carrier. Softening on the one hand increases an adhesive force, but also results in undesired properties such as cold flow or stringing effects during removal of the release liner. A soaking additive added to the solution or suspension may help in increasing the viscosity, however the solution or suspension should not be too viscous in order to ensure efficient soaking. Furthermore, the solution or suspension may be made viscous by adding an additive such as a non-adhesive carrier material and may then be applied to the surface of the carrier matrix. It is advantageous if the solution/suspension is viscous enough to allow knife-coating. This technique is widely used for the preparation of transdermal patches, so that standard equipment may be used for such solutions/suspensions, which allows for a more economical manufacturing process. Additionally, it is more precise than spraying, which furthermore may be hazardous due to created aerosols.
When a liquid retaining means is used, it is preferred to choose an adhesive carrier material compatible to the solution/suspension to be applied, so that no phase separation occurs.
In preferred embodiments, the solid composition is ground. The ground material may then be dispersed in a melt or solution of the carrier material, followed by the cooling or drying of the mixture to form the substrate layer of the transdermal patch. Alternatively, the solid composition comprising the retaining means and the active pharmaceutical ingredient may be applied to the solid carrier material being adhesive. Here, the composition may either be applied as granulate material or powder (e.g. after grinding) or as bulk material (e.g. as fleece material).
The transdermal patch prepared by the methods according to the invention may further comprise a backing layer, preferably an inert backing layer, i.e. a backing layer which does not interfere with the activity or bioavailability of the active pharmaceutical ingredient, a protective layer, i.e., e.g., a layer protecting the bottom of the transdermal patch during storage which has to be peeled off prior to use, and/or a release controlling layer which regulates the rate of release of the active ingredient. The backing layer (overlay) can e.g. be a foil or a film of polyethylene or polypropylene or a non-woven fabric. The protective layer (antistick layer, release liner) can also be a foil, or a complex film formed by materials such as polyethylene or polypropylene or polycarbonate, etc, or a thick slick paper pretreated with paraffin oil or siliconized or fluoro coated. The release controlling layer may be a membrane having a defined pore size and may be used for slowing the release and/or achieving a release that has an extended linear phase.
The transdermal patch preferably comprises an adhesive layer for contacting the skin, which is adjacent to the substrate layer or adjacent to an optionally present release controlling layer. This layer is preferably added a certain time (e.g. 10 to 60 min, preferably 20 to 40 min) after the composition comprising the active pharmaceutical ingredient has been applied to the carrier material, during which resting step the assembly is preferably kept at room temperature. In the case of using a liquid retaining means, the resting step is advantageously performed so that the composition is allowed to migrate into the carrier material. Adding the adhesive layer is preferably done by laminating. Such an adhesive layer adjacent to the substrate layer may be particularly useful when using a certain liquid retaining means such as an oily liquid retaining means, because oil may be present on the surface of the soaked layer, which might result in an impaired adhesiveness. An adhesive layer may also be particularly useful when the substrate layer (or the optionally present release controlling layer) is not sufficiently adhesive.
In one embodiment of the invention, the retaining means is a low volatile liquid plasticizer and the carrier material is a mixture of an adhesive polymer and a non-adhesive polymer. The carrier material preferably is chosen such that it exhibits a rather low adhesiveness. Upon soaking of the carrier material with the retaining means comprising the active pharmaceutical ingredient, the carrier material is softened by the plasticizer and its adhesiveness is increased to a suitable level.
In preferred embodiments, no penetration enhancer in addition to the retaining means—which itself may be a penetration enhancer—is added to the transdermal patch. More preferably no penetration enhancer at all is added to the transdermal patch. At times it is advantageous if the transdermal patch does not contain further additives such as metal salts.
In the following, particular embodiments of the method according to the invention are described:
One embodiment comprises the steps of
In a further embodiment the method comprises the steps of:
In yet another embodiment the method comprises the steps of:
In a further embodiment the method comprises the steps of:
In another embodiment the method comprises the steps of:
In yet another embodiment the method comprises the steps of:
Furthermore, the present invention relates to a method for preparing a transdermal patch comprising a substrate layer, the method comprising the steps of:
In this method, the carrier material preferably is an adhesive, the substrate layer preferably is formed on a backing layer and/or the substrate layer preferably is cooled by forming it on a cooled surface. Furthermore, each of the specific embodiments described herein with respect to the methods for preparing a transdermal patch also apply to this method, if appropriate.
In another aspect, the present invention provides a transdermal patch comprising a backing layer and a substrate layer comprising a volatile active pharmaceutical ingredient, a carrier material and a retaining agent. Preferably, the transdermal patch is obtainable or prepared by any one of the methods according to the invention. Furthermore, the embodiments described herein with respect to the preparation methods also apply accordingly to the transdermal patch according to the invention.
In preferred embodiments, the transdermal patch does not contain a penetration enhancer in addition to the retaining means which itself may be a penetration enhancer. More preferably, the transdermal patch does not contain any penetration enhancer at all.
The transdermal patch preferably contains at least 1% (w/w) of the retaining means. Furthermore, it preferably contains at least 0.1% (w/w) of the active pharmaceutical ingredient.
Preferred prototypes are manufactured as follows:
An acrylate adhesive layer (without active pharmaceutical ingredient) is coated or laminated to a backing layer. Rasagilin base is dissolved in Plastoid B and neutral oil and directly coated to the dry acrylate adhesive layer. The assembly is allowed to rest at 30° C. or below, e.g. at room temperature so that the rasagilin base/Plastoid B/neutral oil mass may diffuse into the acrylate layer. After this, a second, dry acrylate layer is added by laminating. The final laminate is a sandwich.
An acrylate adhesive layer (without active pharmaceutical ingredient) is coated or laminated to a backing layer. Rasagilin base is dissolved in Eudragit EPO and acetone and directly coated to the dry acrylate adhesive layer. A preferred alternative is coating the rasagilin base/Eudragit EPO/acetone mass onto a foil. After coating with the rasagilin base/Eudragit EPO/acetone mass, drying is done at 30° C. or below, e.g. at room temperature. This is possible due to the high vapour pressure of acetone. The result is a solid, non-adhesive rasagilin base/Eudragit EPO layer. A second, dry acrylate layer is added by laminating. The final laminate is a sandwich.
Prototype 3 is manufactured like prototype 2, however using a membrane. Thus a further acrylate adhesive layer is necessary.
In one embodiment, the transdermal patch according to the invention is for use in medicine. In particular, it contains rasagiline or a derivative thereof as the active pharmaceutical ingredient and is for treatment or prophylaxis of a nervous system disease, preferably a nervous system disease selected from the group consisting of Parkinson's disease, Alzheimer's disease, depression, hyperactive child syndrome, restless leg syndrome, multiple sclerosis and abstinence syndrome.
Thus, in one specific embodiment the invention provides a rasagiline transdermal patch for treatment or prophylaxis of nervous system diseases, wherein the patch comprises an inert backing layer chemically inert to substrate ingredients, a substrate layer comprising the free base of rasagiline and a protective layer to be peeled off before use, wherein the substrate layer is a drug-carrying reservoir comprising an organic polymer that is soaked with pharmaceutically acceptable low volatile solvent containing rasagiline or that is dispersed with a ground absorber material comprising rasagiline.
The inventors have found that that a transdermal patch (TDS) comprising an organic matrix which is soaked with a low volatile solvent solubilising the rasagiline permits a highly efficient skin penetration. Furthermore, rasagiline in TDS formulations according to this invention exhibits the stability that is required for a pharmaceutical formulation.
This skin penetration was tested in an in vitro method using excised human skin, representing a model that is highly relevant for the human clinical situation.
Due to the use of a low volatile solvent a subsequent drying step is not necessary. This results in a more efficient production process and prevents the rasagiline and the patch material from drying-associated damage especially as result of the high drying temperature.
The low volatile solvent can also act as an enhancer for the transdermal absorption of rasagiline. If appropriate, the transdermal patch may further comprise a controlled release substrate layer, a release controlling layer, such as a membrane having a defined pore size and/or an adhesive layer. If the drug reservoir substrate layer or the controlled release substrate layer has an appropriate adhesiveness, the adhesive layer as a separate layer may be unnecessary.
Furthermore, a rasagiline transdermal patch is provided wherein the substrate layer comprises a ground layer containing an organic polymer coated with a high viscosity layer comprising a pharmaceutically acceptable low volatile solvent containing rasagiline.
In the above rasagiline transdermal patch, rasagiline has an effective amount of 0.01 to 50 mg/cm2 in the TDS,
The rasagiline transdermal patch of the present invention has an administration area of about 1 cm2 to 50 cm2 during a transdermal therapy.
Throughout this application certain trademarks for chemicals are mentioned. This is in each case meant to be a reference to the following generic groups of chemicals, respectively, as long as they fulfil the respective function to a sufficient degree:
However, in these cases the specific chemicals covered by the trademark at the filing date of this application or closely related chemicals are preferred.
The following figures and examples serve the purpose to illustrate the present invention without in any way limiting this scope thereof. However, they relate to preferred embodiments of the present invention.
An acrylic adhesive matrix comprising Durotak 2287 further containing either 40 or 60% (w/w) of Plastoid B as absorber were prepared by solvent casting. Rasagiline base solutions were prepared and applied to the above described matrix, after complete soaking of this solution into the matrix, a protective liner was added. A solution of Rasagiline was prepared by dissolving Rasagiline base at room temperature with polidocanol as solvent versus IPM as solvent. Samples were then tested for rasagiline base permeation from these patches across excised human skin.
An acrylic adhesive matrix comprising Durotak 2287 further containing either 40% (w/w) of Plastoid B as absorber were prepared by solvent casting. Rasagiline base solutions were prepared and applied to the above described matrix, after complete soaking of this solution into the matrix, a protective liner was added. A solution of Rasagiline was prepared by dissolving Rasagiline base at room temperature with IPM as solvent versus Brij or Crodet at slightly elevated temperature as solvent. Samples were then tested for rasagiline base permeation from these patches across excised human skin.
The top view shows the stage in which the applied rasagilin base/Plastoid B/neutral oil mass diffuses into the acrylate layer. The bottom view shows the final laminate.
Goal: Compatibility of liquid retaining means and carrier materials
1.3 Use of IPM in combination with acrylate/Eudragit E
Goal: Compatibility of liquid retaining means and carrier materials
1.4 Use of Silicone Oil in Combination with BioPSA 7-4301
Goal: Compatibility of liquid retaining means and carrier materials
Goal: Compatibility of liquid retaining means and carrier materials
thickens, and becomes pasty, can not be streaked
IPM is applied on a 10 cm2 TDS, can be spread over the complete TDS
Result: Only sporadic crystals were observed, macroscopically the patches exhibit a wave-like structure
Result: Only sporadic crystals were observed, macroscopically the patches exhibit a prominent wave-like structure
1.9 Application of a Rasagiline IPM Solution onto Acrylate-Plastoid B-TDS
Preparation of a 10 cm2 TDS with 20%, 40% and 60% Plastoid B in Durotak 87-4287 (RAS021, RAS022, RAS023)
Result: Patch from exp. 1.9 shows superior skin permeation compared to patch from exp. 1.8. Analysis of the patches RAS021-023 in skin permeability revealed a high cumulative permeation rate for all three patches (see
A processing of the rasagiline in volatile/low boiling solvents is not possible. Even a slight increase in temperature results in a sublimation/evaporation of the substance.
A particularly promising strategy includes the preparation of a placebo patch with subsequent application of a rasagiline solution.
In order to realize this strategy, an additional absorbent polymer or layer has to be added to the PSA (pressure sensitive adhesive). For this purpose Plastoid B/Eudragit polymers and the like are preferably suited. Preferably, the additional polymer or layer diffuses into the placebo patch so that it does not form an additional layer in the final patch.
Particularly suitable solvents are IPM and silicone oil. However, a relatively high concentration of rasagiline in the solvent is required, preferably a cone. >50%, in order to restrict the smoothening of the patch and to allow a proper soaking. IPM proved to be a particularly successful solvent.
It should be analysed if Polidocanol is as good as IPM for application of rasagiline.
The strategy of applying a rasagiline solution onto a placebo patch (particularly by dropping onto the patch) yielded good results. The solvent IPM has the disadvantage of being a penetration enhancer. Alternative solvents should be identified that lack a penetration enhancing effect.
2.1 Application of Ca. 20 Mg Polidocanol onto the Placebo Patches RAS021TS_D001, RAS022TS_D001, or RAS023TS_D001.
Result: Polidocanol permeates the patch.
Mixing of 48.5 mg rasagiline and 147.0 mg polidocanol Result: rasagiline is completely soluble.
Siehe manufacturing protocol for RAS032TS_D001, RAS033TS_D001 or RAS034TS_D001
analysis of skin permeation
Based on the results polidocanol is a suitable solvent for rasagiline. Furthermore the solvent completely permeates the patch, which constitutes an ideal requirement for the further development. It is known that polidocanol is hardly released from an acrylate matrix. Therefore it can be expected that no or only a limited co-diffusion of rasagiline and polidocanol will take place.
The prototypes RAS033TS_D001 and RAS034TS_D001 were further analysed in a skin permeation experiment and revealed an excellent cumulative skin permeation rate that was even higher as the permeation rate observed for the Plastoid-containing patches (see
In pre-tests the Plastoid B was initially mixed with the adhesive matrix. This resulted in patches with a very little adhesive force. In order to overcome this problem the strategy of a multiple layer prototype was tested build up from an adhesive layer and a plastoid layer.
The plastoid layer is created using a 2% Miglyol solution. Therefore 0.1 g Plastoid B (WE8656) were solubilised in Miglyol 812 (WE8884) ad 5.0 g.
As an adhesive layer DuroTak 4287 (WE7984, solid content ˜38%) is used. The adhesive is streaked onto FL2000 in a way that the dry area-weight equates ca. 60 The layers are dried at room temperature for 10 min, followed by 30 min at 70° C. A web was streaked and the resulting laminate bisected.
For the application of the Plastoid two variants were tested:
Plastoid does not solubilize as 2% solution in miglyol. The plastoid remains as unsolubilised crystals. In further experiments (see exp.; 3.2 and 3.3) the solution was warmed with caution while stirring to a temperature of ca. 50° C. The plastoid dissolves and remains solubilised. The resulting solution exhibits a very low viscosity.
Herein Eudragit E was used for a multi-layer TDS. Eudragit E and Miglyol were weighed in a ratio of 1:1 in an aluminium dish and mixed with a Pasteur pipet. The mixture which was very dry in the beginning liquefied during the time to result in a viscous clear mass (viscosity similar to viscous honey).
Plastoid B and Miglyol were weighed in a ratio of 1:1 in an aluminium dish and mixed which resulted in a crystalline mass. This was heated in a heating oven at 50° C. yielding a clear “clump”. After addition of Miglyol to obtain a ration of 1:2 and further heating at 50° C., a viscous clear mass similar to exp. 3.2. was obtained (viscosity similar to viscous honey).
A 12% Plastoid B solution as prepared. This solution was stirred at ca. 50° C. until the Plastoid was completely dissolved. After 3 hours the solution was clear, however, undissolved plastoid particles could be seen at the border of the glass. The viscosity of the resulting solution is too low to be streaked (even after cooling). After two days of holding time the solution becomes more viscous.
A 25% Plastoid B solution as prepared. This solution was stirred at ca. 50 to 60° C. until the Plastoid was completely dissolved. After 2.5 hours the solution was clear, no plastoid particles could be observed. Accordingly neutral oil was added. The resulting 20% solution still exhibits a high viscosity. It was found that a solution of 16.67% possesses an acceptable viscosity. This solution was further processed in experiment 3.6.
A placebo laminate was prepared by streaking Durotak 4287 with a dry area weight of 60 g/m2.
Web No 1. R.III 200 μm dry area weight of 69.177 g/m2
The batch RAS035TS_D001 was prepared. The Plastoid Bconcentration in the final laminate should equate 20%.
The batch RAS036TS_D001 was prepared by using three different concentrations of Plastoid B (12.5%, 22.5% or 32.5%). The coating of the neutral oil-Plastoid Bsolution is performed according to the manufacturer's protocol:
The FL2000 layer is aspirated with the non-siliconized side onto the coating plate. The adhesive laminate pieces are attached with an adhesive tape on the liner, so that centrally and at the edges an open area is produced allowing a free guidance of the scraper. The scraper adjustment is calculated based on the foil thickness, area weight of the adhesive matrix, plus the targeted area weight of the Plastoid Bneutral oil solution Targeted area weight of the adhesive matrix 80 g/m2 total area weight (Placebo) 95 g/m2
Since the laminates produced in exp. 3.9 possess good adhesive properties they were produced as API containing patches of the following batches: RAS037TS_D001 (32.5% Plastoid B); RAS038TS_D001 (22.5% Plastoid B)
Preparation protocol see example 6
Targeted area weight of the adhesive matrix 80 g/m2
Targeted total area weight (Placebo) 100 g/m2
From each batch 6 patches were analysed in an in vitro skin permeation assay. The batch RAS022TS_D001 was used as reference.
The rasagiline TDS resulted at both Plastoid Bconcentrations in a good aspect.
Previous experiments showed that polidocanol is a very good solvent for rasagiline. However, the polidocanol possesses a pharmaceutical effect (antipruritic) which could pose regulatory problems. Therefore polidocanol analogues with longer chains and lacking pharmacological effects were analysed. Furthermore also macrogol esters were tested. Since these substances are solid compounds it was tried to melt them for further processing.
It was tried to liquefy the compounds Brij S20, Brij CS20, Crodet S40 und Cithrol 10 at a temperature of 40° C.
Ca. 0.5 g were weighed in a beaker glass and heated on a heating plate up to 40° C. while the melting characteristics of the compounds were observed.
Ca. 0.5 g were weighed in a beaker glass and heated on a heating plate while stirring. The heating plate had a temperature of ca. 65-70° C., resulting in a melting temperature of ca. 40-50° C. within the glass.
All solid compounds can be melted at a low temperature therefore permitting a processing. However, the experiment shows also that the molten compounds will quickly become solid again when the temperature is lowered.
The solubility of the rasagiline in the macrogol derivatives should be analysed and acrylate patches should be prepared using a placebo or an API-containing solution.
The above listed substances were melted at 40° C. From each molten substance 20 mg were dropped onto a placebo acrylate patch and dispersed. As placebo patch rectangular 10 cm2 die-cut sheets from the laminate RAS022TS_D001 were used. The handling and the soaking characteristics were documented. Macrogol derivates with good processability were analysed as follows:
210 mg of the macrogol derivate was molten and 70 mg rasagiline were added. The salvation characteristics of the rasagiline was observed and documented. The solvation process has to be performed under stirring.
API containing patches were produced using the macrogol derivates with good solubility of rasagiline. The handling and the soaking characteristics were documented.
Die resulting patches were analysed for skin permeation, for content/purity or presence of crystals.
For the following experiments the pipets and the placebo TDS were pre-warmed in a drying oven. The TDS batch RAS022TS (round, area of 10 cm2) was used.
70 mg rasagiline was weighed into a small screw cap glass. Cithrol 10MS was melted in a drying oven at 50° C. and 210 mg molten Cithrol was added with the pre-warmed pipet to the rasagiline.
During the addition the rasagiline melts. After cooling the mixture solidifies quickly.
The mixture of rasagiline and Cithrol is melted for 2 minutes in the drying oven and homogenized subsequently for ca. 1 minute. 20 mg of this mixture is applied on to a pre-warmed placebo and dispersed using a Pasteur pipet. The TDS is covered and cooled. The rasagiline-macrogol derivate mixture solidifies unevenly and criss-crosses on the TDS.
70 mg rasagiline was weighed into a small screw cap glass. Brij S20 was melted in a drying oven at 50° C. and 210 mg molten Brij S20 was added with the pre-warmed pipet to the rasagiline.
The added Brij S20 solidifies more quickly, resulting in a “wax-like drop”. The mixture is melted in a drying oven, whereby the rasagiline is molten within 2 minutes and the Brij within further 7 minutes. The molten mixture is homogenized subsequently for ca. 1 minute.
20 mg of this mixture is applied on to a pre-warmed placebo and dispersed using a Pasteur pipet whereby the mixture solidifies very quickly. The mixture is melted again in the drying oven and dispersed again. The TDS is covered and cooled. The rasagiline-macrogol derivate mixture solidifies quickly but disperses more evenly and was coated with a adhesive silicone matrix.
70 mg rasagiline was weighed into a small screw cap glass. CrodetS40 was melted in a drying oven at 55° C. and 210 mg molten CrodetS40 was added with the pre-warmed pipet to the rasagiline.
The added CrodetS40 solidifies very quickly, resulting in a “wax-like drop”. The mixture is melted in a drying oven, whereby the rasagiline is molten within 2 minutes and the Crodet within further 7 minutes. The molten mixture is homogenized subsequently for ca. 1 minute.
20 mg of this mixture is applied on to a pre-warmed placebo and dispersed using a Pasteur pipet whereby the mixture solidifies very quickly. As a result it was not possible to disperse the mixture evenly on the TDS. The mixture is melted again in the drying oven and dispersed again. The TDS is covered and cooled. The rasagiline-macrogol derivate mixture solidifies quickly but disperses more evenly and was coated with an adhesive silicone matrix.
As a reference for the skin permeation experiments, a “fresh” TDS using IPM as solvent was prepared. Therefore 70 mg rasagiline were solubilised in IPM. 20 mg of this solution were applied on a 10 cm2 acrylate patch and dispersed evenly. (In analogy to example 1).
It is possible to produce TDS patches by slight warming treatment. BrijS20 and Crodet are particularly suited as solvents for rasagiline. Since the macrogol derivates form a wax-like sheet, they are coated with a thin silicone layer (ca. 20 G/m2) as “skin streak”. The samples with the following batch numbers wee tested for skin permeation:
As reference a freshly prepared patch of the same batch without silicone layer with IPM as solvent was used:
Analysis of the patches RAS022TD containing Brij or Crodet regarding skin permeability revealed a high cumulative permeation rate for both patches which is similar to the Plastoid containing reference patch (see
Based on a solution of rasagiline in neutral oil and Plastoid B a multi-layer TDS should be prepared.
The following substances were mixed to generate Mixture A:
The following substances were mixed to generate Mixture B:
The preparation of the patch includes the following steps: The adhesive laminate pieces are attached with an adhesive tape on the liner, so that centrally and at the edges an open area is produced allowing a free guidance of the scraper.
Thus, the patches according to the present invention having an area of about 1 to 50 cm2 able to transdermaly provide a therapeutic dose needed for up to 7 days treatment, and the penetration rate of rasagiline could be controlled by using multilayer patches. Since the raw materials for preparing the patches are widely and readily available, and rasagiline could be transferred through the whole surface of the substrate for transdermal absorption, the patches of the present invention could be prepared simply with widely available raw materials, have smooth release profiles and a prolonged period for controlled release, and may be more effectively absorbed through skin in comparison with the system as described in WO 2007/101400.
Number | Date | Country | Kind |
---|---|---|---|
09 011533.8 | Sep 2009 | EP | regional |
Number | Date | Country | |
---|---|---|---|
Parent | 13394204 | Jun 2012 | US |
Child | 14186520 | US |