EP1487415A2 - Method for the production and the use of microparticles and nanoparticles by constructive micronisation - Google Patents

Abstract

The invention relates to a method for producing microparticles and/or nanoparticles of a substance, wherein particles are formed from a molecularly distributed substance which is simultaneously stabilised in a suspension. The substance is dissolved in a solvent system and subsequently a non-solvent for said substance is added whereby said non-solvent can be mixed with the solvent system for said substance. One or several crystal growth inhibitors are added and a rapid merging of solvents and non-solvents takes place. The substance is precipitated by forming a dispersion of particles whose size lies within the micrometer or nanometer range.

Description

 Process for the production and application of micro- and nanoparticles by micronization

The invention relates to a process for the production of micro- and nanoparticles of solid substances by constructive micronization by means of dissolution and precipitation, and the use of these small particles.

In the pharmaceutical industry, the development of new pharmaceuticals, especially in recent years, has often caused the problem that the pharmaceuticals developed by the chemical development departments have a very low water solubility up to a water insolubility. This can limit the bioavailability of the active ingredient or ingredients of a pharmaceutical preparation. For example, this problem arose in the development of drugs against the immune deficiency disease AIDS, where therapeutically useful drugs were doomed to fail due to their insufficient bioavailability. By reducing the crystal size can be due to the associated with it Increasing the specific surface area will increase the dissolution rate. However, the conventional size reduction processes (= degrading micronization) result in hydrophobic breaking edges and electrostatically charged, high-energy areas. This leads to disadvantages which negatively influence the handling of the substances and their processability. The rate of release is also not increased to the extent that would be expected from the enlargement of the surface, since poor wettability often results, which leads to flotation. Comminution processes often lead to a broad particle size distribution, so that the desired crystal size must subsequently be obtained by fractionation, which is not an economical process. This is the case, for example, with micronization using an air jet mill. This disadvantage is also described in textbooks on pharmaceutical technology (RH Müller in RH Müller, GE Hildebrand, Moderne Arzneimittelformformen, WVG1997, p. 274). In another review article describing micronization by grinding processes, Parrot describes the comminution using gas jet mills as "ineffective" (Parrot, EL, 1990. Comminution. In: Swarbrick, J., Boylan, JC (ed.), Encyclopedia of Pharmaceutical Technology, Vol. 3, Marcel Dekker Inc., New York, pp. 101-121).

But there is also a need for processes for the production of micro- and nanoparticles by constructive micronization for water-soluble drugs. In this context, water-soluble should mean that the water solubility is greater than 1 g / 100 ml.

For example, drugs for use in a powder inhaler should show a low tendency to agglomerate, good flow properties and high batch conformity [York, P., Powdered raw materials: Characterizing batch uniformity. Proc. Resp. Drug del. IV (1994) 83-91]. These requirements often conflict with the properties of a material crushed by grinding. When grinding larger particles there is only a small possibility, the particle size and shape as well as the To influence surface properties and the electrostatic charge [Malcolmson, R. and Embleton, JK, Dry powder formulations for pulmonary delivery. PSTT 1 (1998) 394-399]. Alternative micronization processes are therefore available that do not require grinding, but rather provide the active ingredient with the required properties directly during its production. Small spherical particles can be formed by spray drying a solution. However, spray-dried active ingredients are mostly amorphous. However, spray-dried, amorphous disodium cromoglycic acid (DNCG) only results in a fine particle fraction between 15% (Rotahaler ^® ) and 36% (Dinkihaler ^® at 90 1 / min) depending on the particle size used, air flow and inhaler [Chew, NYK] due to incomplete dispersibility , Bagster, DF and Chan, HK, Effect of particle size, air flow and inhaler device on the aerolization of disodium cromoglycate powders. Int. J. Pharm. 206 (2000) 75-83]. This technique is rarely used for poorly water-soluble active ingredients, since the organic solvents required here cause environmental toxicological problems and require a lot of equipment. It plays in the field of dye chemistry

Crystal size also plays an important role. For example, dispersions with coarsely crystalline beta-carotene are not colored. Colloidal systems are required to achieve staining.

Micronization by comminution of poorly soluble drugs is a widely used method to increase the rate of dissolution. The most common way in pharmacy to produce small particles is comminution using various mills. However, due to the formation of high-energy lipophilic breaking edges, among other things, such a method does not lead to the desired optimal products. Flotation frequently occurs as a problem and hinders a considerable dissolution of the active substance.

To pharmaceutical preparations, such as tablets, coated tablets or preparations in capsules, liquid dosage forms (Suspensions and emulsions) or pharmaceutical forms for pulmonary use, manufacturers, patients, but also the cost bearers in the healthcare system place numerous requirements:

► In order to facilitate the patient's intake and thus the patient's acceptance (= patient

Tablets) should be as small as possible. This means that an optimal tablet formulation should have the highest possible proportion of active ingredient.

* ^■ On the other hand, by increasing the proportion of active ingredients in a pharmaceutical preparation, more economical production is possible through savings in auxiliary materials. ► In order to be able to efficiently deliver the active ingredient to the body, the preparation should be designed so that it has the highest possible bioavailability. This means that a tablet should disintegrate quickly in the gastrointestinal tract and release the active ingredient quickly. In this context, the active substance has to be required to have a high dissolution rate after the release. This is particularly important for those drugs in which the dissolution rate is the step determining absorption. In the case of pharmaceutical forms for pulmonary use, the loss due to the deposition of the particles outside the lungs, which can also lead to undesirable drug effects, must be avoided. The main part of the applied active substance should therefore reach its active site or absorption site in the lungs.

The processes known from the literature for producing microparticles and nanoparticles are mostly processes which achieve micronization by comminuting larger particles. US-A-5 145684 describes wet grinding in the presence of a surface modifier.

US-A-5 021 242 reports particle size reduction by means of a grinding process without auxiliary substances. It describes an increase in bioavailability through micronization.

US Pat. No. 5,202,129 describes micronization in the presence of sugar or sugar alcohols by means of mills ("impaction mill" and "high speed stirring ill").

US-A-5622938 describes an "unexpected bioavailability" as a result of a micronization process. Here, wet grinding is reported in the presence of a grinding medium that contains surface-active additives (surfactants based on sugar).

US-A-5747001 describes beclometazone nanoparticles which have been produced by a grinding process in the presence of surface-modifying substances.

US-A-5 091 187 and US-A-5 091 188 provide an overview of various methods for producing nanocrystals for intravenous application, the particles being coated with phospholipids. Only stabilization of nanocrystals by phospholipids is reported. Degrading processes (ultrasound, air jet mill, high-pressure homogenization) for reducing the particle size are described, but also constructive processes. In the case of the constructive methods, drug and phospholipid are combined in one organic

Solvent dissolved and then precipitated together by spray drying. An "in-flight crystallization" is specified for this: A solution of the drug and lipid is spray-dried. The precipitation takes place during the spray drying of the solution. The particle size is thus determined by the spray drying process since there are no solid particles beforehand. Another method described is "solvent dilution". Here, an organic solution of the lipid and the drug is placed in water, causing the drug and the lipid to precipitate. The precipitated crystals are obtained by filtration or sedimentation. The two building processes mentioned are a water-insoluble coating of the crystals by a lipid. In this process, the lipophilic active ingredient is dissolved in the organic solvent together with a lipophilic auxiliary. Both, ie the active ingredient and the auxiliary, are precipitated out by adding water.

Pace et al. Also describe micronization in the presence of phospholipids. (Pharmaceutical Technology, 1999 (3), pages 116-134). Comminution by means of shear forces or impaction by means of homogenization techniques or grinding techniques are described.

US-A-5 811 609 and WO 91/06292 report wet grinding in the presence of hydrocolloids.

® According to DE-A-44 40 337 NanoCrystals are by a

High pressure homogenization or by means of a grinding process

(Pearl mill). R.H. Müller describes in one

Review article (R.H. Müller, G.E. Hildebrand, Moderne

Pharmaceutical forms, WVG 1997, p. 273 ff.) Dry grinding in a gas jet mill, wet grinding in a pearl mill and

High pressure homogenization as possibilities for the production of

Nano suspensions.

Another frequently used process for comminution by means of a grinding process is high pressure homogenization. Due to the high energy density, which corresponds to that in a nuclear power plant (Müller, RH, Böhm, HL, Grau, MJ, 1999. Nanosuspensionen - formulations for poorly soluble drugs with low bioavailability; 1. Manufacture and properties. Pharm. Ind. 61, 74 - 78), this results in amorphous nanosuspensions. In general, the risk of abrasion, for example, of the grinding balls (particularly important in the case of parenteral application) and the mechanical and (in particular in the case of dry comminution processes) thermal stress on the material to be ground is problematic in all comminuting processes. Air jet mills also lead to a broad particle size distribution, which requires a separation step and thus also questions the economic viability.

As already mentioned, there are also constructive ones in the literature

Procedure described. In the known method, however, a very high is often ^'(> 50%) excipient content is needed, one that more of an embedding speak must, as evidenced by

Information about amorphous structures is underlined.

Ruch and Matijevic (J. Coll. Interf. Sei 229, 207 - 211, 2000) state that although there are numerous dispersions of inorganic substances, stable dispersions from organic substances have not been successfully described. The only exceptions to this are polymer latices and the carotenoid dispersions mentioned above. No other uniform particles of organic matter are known.

In the process of US-A-4,540,602, a fine emulsion of the lipophilic drug dissolved in a water-immiscible organic solvent is prepared in the presence of stabilizers in water. This process is similar to classic microencapsulation.

US-A-4 826 689 describes the precipitation of amorphous organic substances with the aim of using these precipitated substances for an i.v. Application.

US-A-5 726 642, US-A-5 665 331 and US-A-5 662 883 (all Bagchi et al.) Describe micro-precipitation under

Use of surface-active materials. However, the prerequisite is in any case the solution of the drug in an alkali and the addition of an anionic surfactant that has a molecular structure that is at least 75% consistent with the drug. The precipitation is brought about by a pH shift into the acidic range.

US-A-5 700 471 describes the preparation of an amorphous dye or amorphous drug preparation. The fabric is melted and the melt obtained is then emulsified in water and spray dried.

US-A-5133 908 describes a precipitation which leads to matrix formation. The precipitation of a protein forms a colloidal preparation, the precipitation liquid having a temperature which is higher than the coagulation temperature of the protein. Spherical particles of the matrix type are formed.

The formation of matrix particles by precipitation is also described in US Pat. No. 5,118,528. The drug and a film-forming material are precipitated together, which in turn results in spherical particles of the matrix type.

In US-A-4107288 preparations for use in i.v. Applications described. Here the biologically active substance is embedded in a matrix (crosslinked matrix of macromolecules). The crosslinking of the matrix is effected, for example, by glutaraldehyde.

US Pat. No. 5,932,245 describes the production of nanoparticles from poorly water-soluble drugs. However, this requires a surface charge of the drug. Gelatin is used as an adjuvant and the pH is adjusted so that the drug is negative and the gelatin is positively charged.

Spray drying for the production of micronized carotene is described in EP-A-0 410 236 and US-A-5 364 563. An emulsion of carotene is dried by spray drying.

Other sources (US-A-4 522 743, US-A-5 968 251 (= DE 196 37 517 AI), D. Hörn: Preparation and characterization of microdisperse bioavailable carotenoid hydrosols, Die Angewandte Makromolekulare Chemie 166/167, 1989, Pages 139-153; information brochure "Kolloide", published by BASF AG, pp. 50f, Hörn and Rieger in Angewandte Chemie, 2001, 113, 4460 - 4492) describe a process for the production of finely divided, powdered carotenoid preparations. Gelatin is mainly reported as a stabilizer, and the ratio of carotene to gelatin at 1: 2.5 must be rated as extremely unsatisfactory. If the other necessary auxiliary substances are taken into account, a preparation is described which contains only 12.5% by weight of carotene. So there is more of an embedding. The carotene is amorphous. The high proportion of auxiliary substances prevents crystallization. Another patent (US-A-4726955) describes the use of milk as a precipitant, the coagulation of which is used in the presence of alcohols.

The production of budesonide particles in the micrometer range is described by Ruch and Matijevic (J. Coll. Interf. Sei 229, 207-211, 2000), some of which are carried out using ultrasound. Compared to the process according to the invention, the budesonide particles obtained are not sufficiently stabilized against particle size growth. There is a strong dependence of the particle size on the speed of the drying process. The precipitated dispersions show particle size growth and the dry product cannot be redispersed without changing shape and size. A broad particle size distribution and an agglomeration of the particles are described.

Gassmann, List and Sucker (Eur. J. Pharm. Biopharm. 40 (2), 1994, pp. 64-72) and List and Sucker (US-A-5389382) describe hydrosol production by precipitation in the presence of polyvinylpyr- rolidone (PVP) and poloxamers with subsequent freeze or spray drying. An amorphous product is again obtained.

US-A-4 826 689 describes the production of amorphous particles of poorly soluble drugs by precipitation processes. The problem of stability generally arises with amorphous products. No crystallization may occur over the period of use, at different temperatures or during further processing. In addition, high amounts of auxiliary substances are necessary for stabilization.

Esumi et al. (Colloids and Surfaces B: Biointerfaces 11, 1998, pages 223-229) describe a fine, aqueous suspension. The drug CT 112 forms suspensions that are difficult to stabilize. The method described describes a way of stabilization, the suspension being formed by adding acid to an alkaline solution which, in addition to the medicinal substance, also contains PVP and cellulose. The polymers act as dispersants and also prevent crystallization. There is therefore a suspension with an amorphous solid phase.

Another way of constructing micronized substances is by precipitation from supercritical gases (Kerc, J., Srcic, S., Knez, Z., Sencar-Bozic, P., 1999. Micronization of drugs using supercritical carbon dioxide. Int. J Pharm. 182, 33-39; Steckel, H., Thies, J., Müller, BW, 1997. Micronizing of steroids for pulmonary delivery by supercritical carbon dioxide. Int. J. Pharm. 152, 99-110). A disadvantage of this technique is the high expenditure on equipment due to the high pressure required to reach the supercritical gas.

The present invention has for its object to provide a method with which the production of particles with a size in the micro and nanometer range is possible quickly, inexpensively and with little technical effort. At the same time, the disadvantages associated with the usual degrading (comminuting) processes should be avoided. Further the aim is to offer a possibility of producing rapidly soluble pharmaceutical preparations which contain the pharmaceutical substance in finely divided size. It should also be possible to use it in other fields in which it is desirable to use finely divided, poorly soluble solids. The resulting powder should have good properties, for example be flowable and not show strong cohesion, which is important, for example, in pulmonary use, especially in powder inhalers.

This object is achieved according to claim 1 by a process for the production of micro- and / or nanoparticles of a substance, which is characterized in that the substance is solved in a solvent system for this and then a non-solvent for this substance, which with the solvent system is in principle miscible for this substance, is added, one or more crystal growth inhibitor (s) being present and a rapid combination of solvent and non-solvent being carried out, as a result of which the substance precipitates to form a dispersion of particles which is a Have size in the micro or nanometer range.

Preferred embodiments are the subject of the dependent claims.

The substance can form a temporary hybrid gap in the solvent, so that the primary crystallization takes place in a two-phase system. Likewise, production is possible by adding the substance solution to the non-solvent or by mutual mixing, for example in a mixer.

The precipitation, preferably with crystallization, takes place due to a rapidly occurring supersaturation.

This can be achieved by a "solvent change" process, a "temperature change" process or a "solvent evaporation" or a pressure change. A combination of several of these methods is also possible. Precipitation preferably occurs in the presence of one or more additives which reduce the crystal size growth of the resulting particles, ie crystal growth inhibitors.

The solvent system can comprise one or more solvents for the substance. Suitable solvents can be selected from the group of aliphatic or aromatic alcohols, ketones, nitriles and ethers, in particular they can be one of isopropanol, ethanol, methanol, acetone and acetonitrile, tetrahydrofuran (THF), propylene glycol, glycerol and dimethylformamide (DMF) include. A solution in acidic or alkaline water is also possible if the substance is pH-dependent.

The method can be applied to all substances with low solubility in the non-solvent used (precipitation medium). In the case of water as a precipitant, it is therefore applicable to all poorly water-soluble substances (poorly soluble, very poorly soluble, practically insoluble; corresponding to a water solubility of less than 1 g / 100 ml, preferably less than <0.1 g / 100 ml), such as poorly soluble drugs and vitamins. This poor solubility can also be characterized by the octanol / water partition coefficient, which should preferably be> 1.5.

Suitable non-solvents are, of course, depending on the substance, for example one or more selected from water, ketones, short-chain alcohols, DMF, THF, nitriles, glycerol and propylene glycol.

In principle, all organic solvents in which the substance has a solubility of less than 0.1 g / 100 ml are suitable as non-solvents for water-soluble substances. Suitable non-solvents can, for example, linear or branched Ci -C ₁₀ alcohols such as isopropanol, methanol or ethanol, or C ₃ - C ₁₀ - etone as acetone, or aldehydes such as acetaldehyde hyd, or nitriles such as acetonitrile or amides such as dirnethylformamide.

The process according to the invention enables the production of crowned or colloidal powders with an auxiliary content of well below 50% by weight. If desired, however, higher proportions of auxiliary can also be used. However, this is not necessary for the stability of the particles of the final product

► are characterized by an average particle size of 100 μm to 10 n, preferably 50 μm to 20 nm, in particular 30 μm to 30 nm and particularly preferably 15 μm to 100 nm,

► have a narrow particle size distribution (this distinguishes them from particles crushed by an air jet mill, for example, which usually have such a wide particle size distribution that a fractionation of the product is necessary),

► crystalline or amorphous, - are preferably crystalline, ► as a solid in solid dosage forms such as capsules,

Tablets or coated tablets can be used

► which have an accelerated dissolution characteristic as well as an improved wettability, the reason being an enlarged wettable surface, ► can be used partially,

► can be incorporated into semi-solid systems (e.g. for therapeutic, cosmetic, stabilizing or dyeing purposes),

► can be administered by inhalation (powder inhalation or suspension aerosol from a pressure container),

► can be used in liquid preparations after redispersion without particle size growth taking place.

A flotation, as often occurs with a mechanically comminuted drug, cannot be observed. In addition to increasing the dissolution rate, the saturation solubility is increased with a significant reduction in the particle size (especially with a particle size of <1 μm).

The drug is released faster due to the higher release pressure. Since it can then be distributed in a larger compartment or transported away, recrystallization cannot occur.

When used in suspensions, there is no or only extremely slow sedimentation due to the small particle size. A sediment that is formed can be shaken very easily since there is no cacking due to the small particle size and the narrow particle size distribution.

The invention also relates to the use of the products thus produced for the production of pharmaceutical dosage forms. Likewise, an application in food technology, cosmetics, crop protection or in the field of coloring techniques is included according to the invention. The use in liquid preparations can serve, for example, coloring or therapeutic purposes. It is also possible to use a dispersion of colloidal dye pigments (preferably 10 nm - 500 nm), for example in an ink, for example for use in inkjet printers.

These properties are achieved, for example, by the process steps described below:

The method used is based on a solution of the substance which is sparingly or slightly soluble in the non-solvent or precipitant in a solvent system which is miscible with this precipitant. In the case of substances which are sparingly soluble in water (to which reference is essentially made in this description, but without being restricted thereto), the solvents used are, for example, alcohols such as ethanol, methanol, isopropanol, glycerol and propylene glycol, ketones such as acetone, ethers such as THF, DMF and nitriles such as aeetonitrile in question. It is also possible to use hydrophobic solvents both as solvents and as precipitants, such as dichloromethane, ether, or hydrofluoroalkanes. A dispersion is prepared from this solution by adding the precipitant, such as water.

Reverse litigation, i.e. it is possible to add the substance solution to the precipitant. Even if the process according to the invention described here focuses on sparingly water-soluble substances, a reverse process, that is to say the precipitation of water-soluble substances with organic precipitants, is also possible.

In order to further reduce crystal growth in crystals, crystal growth inhibitors or stabilizers are optionally added.

The dispersion can then be converted into a powder by drying (for example spray drying, solvent evaporation or freeze drying), a filtration step or a combination of several of these processes.

The process according to the invention can be carried out either batchwise (ie firstly a batch is prepared, which is subsequently converted into a dry powder) or continuously (ie simultaneously adding solution and precipitant in a suitable ratio and mixing them, for example in a static mixer. Here If the dispersion formed in the mixer (e.g. immediately before the spray nozzle of the spray tower) precipitates and thus dries immediately). There is no change in particle size during the spraying process either.

Examples of suitable auxiliaries for inhibiting crystal growth / stabilizing the dispersion, which are preferably water-soluble in the case of water as the precipitant, are: ► Polyvinyl alcohol, PVA

► Cellulose ethers such as hydroxypropyl cellulose (HPC), hydroxyethyl cellulose (HEC), hydroxypropyl methyl cellulose (HPMC), methyl cellulose (MC), methyl hydroxyethyl cellulose (MHEC)

► Caseinates (such as calcium caseinate) or casein

► Sodium alginate

► Polyvinyl alcohol-polyethylene glycol graft copolymer (e.g.

® Kollicoat IR) ► Polyvinylpyrrolidone, povidone, PVP

► Hydroxyethyl starch, HES (such as HES 130, 400)

®

► Polyacrylates / polymethacrylates (such as Eudragit L)

► Chitosan (if necessary by setting a pH value that leads to a charge of the chitosan) ► Agar

► Pectin

► Sugar such as B. trehalose

► Dextrans (such as Dextran 20, 60, 200)

► Gelatine A, Gelatine B (if necessary by setting a pH value which leads to a loading of the gelatine)

► Gum arabic

* - surfactants such as

Polyoxypropylene-polyoxyethylene block polymers (poloxamers) (to be preferred because there is no micelle formation), partial fatty acid esters of polyoxyethylene sorbitan, such as, for example, polyethylene glycol (20) sorbitan monolaurate, monopalmitate, monostearate, monooleate; Polyethylene glycol (20) sorbitan tristearate and trioleate; Polyoxyethylene (5) sorbitan monooleate; Polyoxyethylene (4) - sorbitan monolaurate (also referred to as polysorbate) polyoxyethylene fatty alcohol ethers, such as, for example, polyoxyethylene (4) lauryl ether, polyoxyethylene (23) lauryl ether, polyoxyethylene (10) cetyl ether, polyoxyethylene (20) cetyl ether, polyoxyethylene (10) stearyl ether,

Polyoxyethylene (20) stearyl ether, polyoxyethylene (10) - oleyl ether, polyoxyethylene (20) oleyl ether (also known as macrogol fatty acid ether)

Polyoxyethylene fatty acid esters, such as, for example, polyoxyethylene stearate, ethoxylated triglycerides, such as polyoxyethylene glycol fatty acid esters, such as, for example, polyoxyethylene glycerol monoisostearate,

Sugar esters (such as, for example, sucrose monolaurate, sucrose monopalmitate, sucrose monostearate, sucrose monomyristate, sucrose monooleate),

sugar ethers

Alkaline soaps (fatty acid salts), such as sodium laurate, palmitate, stearate, oleate, ionic and zwitterionic surfactants, e.g. B. betaines, such as cocobetaine

Phospho1ipide.

The use of other auxiliaries such as plasticizers is also possible. Stabilizers can also be added in relation to other functions, e.g. B. when using substances sensitive to oxidation.

The additives are preferably dissolved in the precipitant, but can also be dissolved or suspended in the solvent or non-solvent.

The concentration of crystal growth inhibitor, based on the substance to be precipitated, is usually in the range from 0.01 to 50% by weight, preferably 0.1 to 30% by weight and preferably 0.5 to 20% by weight.

In a preferred embodiment, the invention provides a method for forming crystals with a significantly reduced crystal size. The crystals can be called icronized to colloidal. The process does not mechanically crush larger crystals, but limits the crystal size growth by means of suitable measures. It deals is therefore a constructive process. The resulting crystals have, for example, a crystal size of 100 μm to 10 nm, preferably 50 μm to 20 nm, in particular 30 μm to 30 nm and particularly preferably 15 μm to 100 nm.

The crystals produced in this way show an accelerated dissolution, so that when used in the pharmaceutical sector for drugs in which the dissolution rate is the step limiting the bioavailability, the result is an accelerated flooding in the blood plasma and an increase in the bioavailability.

The crystals produced in this way also show a low level of cohesion compared to degrading comminution processes. Furthermore, they are not electrostatically charged. This enables them to be used in areas where an easily dispersible powder is required, for example in pharmaceutical forms for pulmonary use.

With a particle size of <400 nm, preferably <200 nm, sterile filtration is possible. This enables the preparation of preparations of thermolabile substances to be administered parenterally or ophthalmologically, since heat sterilization can be replaced by sterile filtration.

Itraconazole, ketoconazole, ibuprofen, beclometasone dipropionate and other drugs that meet the above-mentioned criteria of poor solubility are suitable as poorly or poorly soluble drugs. Such drugs can also be used.

Other suitable sparingly or poorly soluble substances are, for example, carotenoids such as beta-carotene, lycopene, lutein, canthaxanthin, astaxanthin or zeaxanthin. The particles produced, in particular crystals, are also suitable for use in colloidal solutions (for example aqueous dye solutions of poorly soluble dyes).

An exemplary scheme of the manufacturing steps of the method according to the invention is illustrated below:

► Dissolve in the mother liquor

► Precipitation in non-solvent, possibly in the presence of stabilizers

► if necessary drying (spray drying, freeze drying, solvent evaporation)

► If necessary, the product is obtained by filtration techniques or reverse osmosis and ► if necessary, redispersion.

The particle size is determined directly when the particles are precipitated and thus when the dispersion is produced. Spray drying does not affect the size of the individual particles. The dispersion initially only dries. Since the particle size and the particle size distribution are not determined by the spray drying process, the spray drying process can be carried out using the direct current method. This is particularly preferable for thermolabile fabrics. Of course, spray towers operating according to the countercurrent method can also be used. Additional processing aids can be added, such as lactose or mannitol. In general, however, spray drying of the dispersion is possible without further additives.

Another suitable method for drying is freeze drying or the solvent evaporation method or a combination of several methods. However, other drying processes can also be used. Product extraction using filtration techniques is also suitable. The method according to the invention is thus a method that can be used very easily with extremely little technical effort, almost anywhere and leads to a high degree of loading of the end product. Since the product is preferably crystalline, its stability is given, especially when compared to the amorphous products described in the literature. There is no thermal stress as in grinding processes.

An advantage of the method according to the invention is the production of a micronized drug preparation (or substance preparation) with a (medicinal) substance content of over 50% by weight (m / m). Compared to the usual degrading processes, the process according to the invention has the advantage that no input of mechanical energy is necessary for comminution. As a result, all crystal surfaces are of natural origin, no areas of different energy (as they result from mechanical comminution) exist. Mechanical crushing results in breaking edges, which are usually non-polar.

Another commonly used method to increase the rate of dissolution is to encapsulate a poorly soluble drug in cyclodextrins. However, solids containing cyclodextrin have only a very low drug content, generally well below 50% by weight (m / m). Another disadvantage of complexing with the aid of cyclodextrins is that this method cannot be used universally, since the drug has to have an affinity for the cyclodextrin. First and foremost, a certain molecular geometry is required. Effective encapsulation can be prevented, for example, by large substituents. There is usually no connection between the tendency towards complex formation and the physicochemical properties of the drug. In contrast, the use of the method according to the invention described here is tied to the physicochemical properties of the medicinal substance (for example solubility in the solvent and insolubility in the precipitant). The insolubility Wise in water therefore also represents the problem of the slow dissolution rate (and thus the low bioavailability) as well as the problem solving. Thus, the method according to the invention is based on the physicochemical properties of the medicinal product and consequently on all (medicinal) substances which have mentioned problematic physicochemical properties, universally applicable.

Some application examples from the pharmaceutical sector are given below in order to explain the process according to the invention in more detail, but without restricting it to them. It becomes clear that the method presented enables a drastic increase in the dissolution rate of the solid and can be used with a wide variety of (medicinal) substances. Other examples illustrate the suitability of the easy-to-disperse, low-cohesive powder for pulmonary use, with a drastic increase in the proportion of respirable particles being observed. The active substance preferably reaches its place of action, and there is hardly any undesired deposition of particles, for example in the throat area.

Examples

Example 1: Itraconazole

0.75 g of itraconazole are dissolved in 500 ml of acetone. A 0.005% by weight solution of HFMC 4000 (4000 ml) in water is used for the precipitation. The solutions are quickly combined. The particle size distribution in the resulting dispersion is determined by laser diffractometry.

Figure 1 clearly shows that effective stabilization has been achieved: the particle size distribution is shown 24 hours after precipitation. The stabilization of the colloidal state becomes particularly clear when comparing the particle size growth if only water is used without auxiliary substances (Fig. 2).

The dispersion is spray dried (as soon as possible after the precipitation; however, as the particle size distributions show, intermediate storage is also possible). The spray-dried product (drug content = 78.95% by weight) has a particle size distribution which corresponds to that of the dispersion, as can be seen from the SEM image (Fig. 3).

The particle size is therefore already determined during the preparation of the dispersion. Spray drying does not affect the particle size. The submitted dispersion only dries. The accelerated dissolution rate is shown in Fig. 4.

Example 2: Ketoeonazole

0.5 g of ketoonazole are dissolved in 100 ml of acetone. A 0.025% by weight solution of HPMC 4000 (800 ml) in water is used for the precipitation. The solutions are quickly combined. The particle size distribution in the resulting dispersion is determined by laser diffractometry. Figure 5 clearly shows that effective stabilization has been achieved: the particle size distribution is shown 60 min after the precipitation. The dispersion is spray dried (as soon as possible after the precipitation; however, as the particle size distributions show, intermediate storage is also possible). The spray-dried product (drug content = 71.4% by weight) has a particle size distribution which corresponds to that of the dispersion, as can be seen from the 'SEM image (Fig. 6). After redispersion in water, a dispersion is obtained whose particle size distribution (Fig. 7) corresponds to the spray-dried product, which underlines the stability. There is no increase in particle size. When determining the powder dissolution, a clear increase in the release rate can be observed (Fig. 8). Example 3: Ibuprofen

2.5 g of ibuprofen are dissolved in 50 ml of isopropyl alcohol. A 0.1% by weight solution of HPMC 15 (200 ml) in water is used for the precipitation. The solutions are quickly combined.

The particle size distribution in the resulting dispersion is determined by laser diffractometry. It is clear from the figures Fig. 9, Fig. 10 and Fig. 11 that an effective stabilization has been achieved: The particle size distribution after precipitation is shown, with an average particle size of 1800 nm (Fig. 9). The dispersion is spray dried immediately after production. The spray-dried product (drug content = 92.6% by weight) has a particle size distribution that corresponds to that of the dispersion, as can be seen from the SEM image (Fig. 10). After redispersion in water, a dispersion is obtained whose particle size distribution corresponds to the spray-dried product, which underlines the stability. There is no increase in particle size. The increase in solution speed is illustrated in Fig. 12.

Example 4: Ibuprofen, continuous process

25 g of ibuprafen are dissolved in 500 ml of isopropyl alcohol. A 0.1% by weight solution of HPMC 15 (2000 ml) in water is used for the precipitation. The two solutions are conveyed by means of a commercially available peristaltic pump in the ratio 1 + 4 into a commercially available static mixer (for example a spiral mixer from Kennics), which is located directly in front of the spray nozzle of the spray tower. The dispersion formed here is consequently dried immediately after its formation. The properties of the product formed correspond to those from Example 3. Example 5: Beta Carotene:

2.4 g of beta-carotene, 0.4 g of di-alpha-tocopherol and 0.75 g of ascorbyl palmitate are suspended in 10 ml of isopropyl alcohol. With the addition of 25 ml of isopropyl alcohol, the mixture is heated to 175 ° C. for 0.4 seconds and mixed, resulting in a solution. It is then immediately precipitated with 220 ml of an aqueous solution which contains 0.1% by weight of HPMC. This corresponds to a ratio of HPMC to carotene of 9.1: 90.9. Taking the stabilizers into account, an end product with a carotene content of 62.6% by weight is produced. Drying takes place in the spray tower. The result is a colloidal powder.

Example 6: Beta Carotene:

2.4 g of beta-carotene, 0.4 g of di-alpha-tocopherol and 0.75 g of ascorbyl palmitate are suspended in 10 ml of isopropyl alcohol. With the addition of 25 ml of isopropyl alcohol, the mixture is heated to 175 ° C. for 0.4 seconds and mixed, resulting in a solution. It is then immediately precipitated with 220 ml of an aqueous solution which contains 0.2% by weight of HPMC. This corresponds to a ratio of HPMC to carotene of 15.5: 84.5. Taking the stabilizers into account, an end product with a carotene content of 59.3% by weight is produced. Drying takes place in the spray tower. The result is a colloidal powder.

Example 7: Beclometasone Dipropionate

The suitability of the method according to the invention for the production of pulmonary pharmaceutical substances for application by means of a powder inhaler (DPI) is illustrated in the following example: 1 g beclometasone dipropionate is dissolved in 25 ml acetone. A 0.01% by weight solution of HPMC 50 (400 ml) in water is used for the precipitation. The solutions are quickly combined. The resulting dispersion is spray dried. The spray-dried product shows an even, homogeneous, narrow particle size distribution. The powder shows very little Tendency to agglomeration, a very low cohesiveness and is not electrostatically charged. The building micronized drug is compared with the drug that was micronized with the help of a jet mill. This shows a strong agglomeration and an electrostatic charge, which leads to problems during the micronization process. Both the build-up micronized and the drug micronized with the help of the Jet-mill are analyzed to determine the respirable fraction with the aid of a multi-stage liquid impactor (Multi-Stage Liquid Impinger, MSLI) (without the addition of other auxiliaries). This shows dramatic differences: The Jet-mill micronized product has a fine particle fraction (based on the amount of drug made available in the applicator), FPF of 14.4% by weight; 36% by weight of the drug remains in the application aid, a further 22% by weight is deposited in the throat area (and thus get into the digestive tract, which can lead to side effects!) And 23% in the upper airways. Only 14.4% by weight reach their actual destination. On the other hand, the structure of the micronized drug is completely different: 84.4% by weight of the drug in the applicator reaches its place of action in the lungs. The FPF is 84.4% by weight. Only 0.8% by weight remains in the application aid. Only 4.8% by weight of the drug is deposited in the throat area. The distribution of the drug is illustrated in Figures 13 and 14.

Example 8: Continuous Process for Beclometasone Dipropionate

The following example illustrates the application of the continuous process for the production of medicinal products for pulmonary application using a powder inhaler (DPI):

100 g beclometasone dipropionate is dissolved in 2500 ml acetone. A 0.01% by weight solution of HPMC 50 (400 ml) in

Water used. These solutions are mixed in a ratio of 1 + 16 in a static mixer (spiral mixer), where it is used Precipitation of the drug and thus the formation of a fine particulate dispersion. This is fed to the spray tower. The resulting micronizate shows the same properties as described in Example 7.

Example 9: Beclometasone dipropionate in suspension aerosol

The following example illustrates the application of the process for the production of medicinal products for pulmonary application by means of a suspension aerosol (preparation in a pressure container):

1 g beclometasone dipropionate is dissolved in 25 ml acetone. A 0.01% by weight solution of HPMC 50 (400 ml) in water is used for the precipitation. The dispersion is spray dried. The resulting powder is processed in a suspension aerosol (propellant: HFC: HFA227). The result is a uniform suspension. A high inhalable fraction and a high content uniformity are also observed here.

Example 10

The itraconazole powder from Example 1 is redispersed in water. The result is a uniform dispersion which remains unchanged even after 60 days. The particle size distribution, the 60th

Days after redispersion was measured is shown in Fig. 15.

Example 11: Cromoglycic acid disodium salt (DNCG)

The suitability of the method according to the invention for the production of micronized water-soluble medicinal substances (in this example for pulmonary application by means of a powder inhaler (DPI)) is illustrated in the following example:

4 g of cromoglycic acid disodium salt are dissolved in 100 ml of a 1% solution of HPMC in water. The precipitation is carried out with isopropanol with rapid combination in a ratio of 1: 8. The resulting dispersion is spray dried. The spray-dried product shows an even, homogeneous, narrow particle size distribution. The powder shows a very low tendency to agglomerate, a very low cohesiveness and is not electrostatically charged.

The building micronized drug is compared with drug that has been micronized using a gas jet mill. Here there is a strong agglomeration and an electrostatic charge, which leads to problems during the micronization process. Both the build-up micronized and the drug micronized with the help of the Jet-mill are analyzed to determine the respirable fraction with the help of a multi-stage liquid impactor (Multi-Stage Liquid Impinger, MSLI) (without the addition of other auxiliaries). This shows dramatic differences: The Jet-mill micronized product has a fine particle fraction (based on the amount of drug made available in the applicator), FPF of 7.3% by weight. On the other hand, the situation is completely different with the in-situ micronized drug: 74.2% by weight of the drug in the applicator reach their place of action in the lungs. The FPF is 74.2% by weight. The distribution of the drug is illustrated in Figure 16.

Claims

Patentanprüche

1. A method for producing micro- and / or nanoparticles of a substance, characterized in that the molecularly distributed substance is associated with particles and simultaneously stabilized in suspension, the substance being dissolved in a solvent system for this and then a non-solvent for this substance , which is miscible with the solvent system for this substance, is added, one or more crystal growth inhibitor (s) being present and a rapid combination of solvent system and non-solvent being carried out, whereby the substance to form a dispersion of Particles are precipitated, which have a size in the micro or nanometer range.

2. The method according to claim 1, characterized in that the solvent system comprises one or more solvents for the substance.

3. The method according to claim 1 or 2, characterized in that the solvent system comprises one or more solvents selected from aliphatic or aromatic alcohols, ketones, nitriles, in particular one of ethanol, methanol, isopropanol, acetone and / or acetonitrile.

4. The method according to any one of the preceding claims, characterized in that the substance in the non-solvent for this substance has a solubility less than lg / 100 ml, in particular less than 0.1 g / 100 ml.

5. The method according to any one of the preceding claims, characterized in that the non-solvent comprises one or more non-solvents selected from water, organic solvent with a hydrophilic character such as methanol.

6. The method according to any one of the preceding claims, characterized in that the substance is a water-soluble substance and the non-solvent or the mixture of several non-solvents is an organic solvent which is a non-solvent for the substance.

7. The method according to claim 6, characterized in that the non-solvent system one or more non-solvents is selected from aliphatic or aromatic alcohols, ketones, nitriles, alde hydenes or amides, in particular from linear or branched C _x -C ₁₀ alcohols, preferably isopropanol, methanol or ethanol, C ₃ -C ₁₀ etones, preferably acetone, acetaldehyde, acetonitrile or dimethylformamide.

8. The method according to any one of the preceding claims, characterized in that the / the crystal growth inhibitor (s) is selected from polyvinyl alcohols, cellulose ethers, cellulose esters, caseinates, casein, sodium alginate, polyvinyl alcohol-polyethylene glycol graft copolymers, polyvinylpyrrolidone, povidone, PVP , Hydroxyethyl starch, HES, polyacrylates / polymethacrylates, chitosan, agar, pectin, sugar, dextrans, gelatin A, gelatin B, gum arabic, poloxamers, ethoxylated triglycerides, sugar esters, sugar ethers, alkali soaps (fatty acid salts), ionic and zwitterionic surfactants, polyethylenesorbates - Fatty alcohol ethers, polyoxyethylene fatty acid esters and phospholipids or any mixtures thereof, in particular those selected from the group of hydrophilic polymers.

9. The method according to any one of the preceding claims, characterized in that the crystal growth inhibitor (s) is a cellulose ether, selected from the group consisting of hydroxypropyl cellulose, hydroxypropyl methyl cellulose, methyl cellulose and methyl hydroxyethyl cellulose.

10. The method according to any one of the preceding claims, characterized in that the crystal growth inhibitor is hydroxypropyl methyl cellulose.

11. The method according to any one of the preceding claims, characterized in that the concentration of crystal growth inhibitor based on the substance to be precipitated in the range of 0.01 to 50 wt.%, Preferably 0.1 to 30 wt.% And preferably 0.5 to 20 % By weight.

12. The method according to any one of the preceding claims, characterized in that the particles are in crystalline or amorphous form.

13. The method according to any one of the preceding claims, characterized in that the particles are in crystalline or amorphous form and a size of 100 microns to 10 nm, preferably 50 microns to 20 nm, in particular 30 microns to 30 nm and particularly preferably 15 microns to Have 100 nm.

14. The method according to any one of the preceding claims, characterized in that the substance is an active ingredient.

15. The method according to any one of the preceding claims, characterized in that the substance is an active pharmaceutical ingredient.

16. The method according to any one of the preceding claims, characterized in that the dispersion is spray-dried or freeze-dried or dried by solvent evaporation or that the powder is obtained by filtration techniques or that a combination of different of these methods is used.

17. The method according to any one of the preceding claims, characterized in that the micronized substance by this method is a substance or drug that a low cohesiveness, low adhesiveness and only extremely low electrostatic charge.

18. Use of microparticles and / or nanoparticles which have been produced by a process according to one of claims 1 to 17 for the production of colloidal dispersions.

19. Use of microparticles and / or nanoparticles which have been produced by a process according to one of claims 1 to 17 for the production of solid, semi-solid, liquid or air-dispersible medicaments, preparations or use forms.

20. Use of microparticles and / or nanoparticles, which have been produced by a process according to one of claims 1 to 17, in medicaments in order to increase the dissolution rate and thus the bioavailability of the active ingredient.

21. Use of microparticles and / or nanoparticles which have been produced by a process according to one of claims 1 to 17 in medicaments for parenteral use.

22. Use of microparticles and / or nanoparticles which have been produced by a process according to one of Claims 1 to 17 in medicaments for pulmonary use in a powder inhaler with or without the addition of further auxiliaries or carriers.

23. Use of microparticles and / or nanoparticles which have been produced by a process according to one of Claims 1 to 17, in medicaments for pulmonary use in a suspension aerosol (preparation in a pressure container), preferably no further auxiliaries in addition to the propellant or propellant mixture be used.