EP1673066A2

EP1673066A2 - Aqueous aerosol preparation

Info

Publication number: EP1673066A2
Application number: EP04790427A
Authority: EP
Inventors: Jürgen JAUERNIG; Frank-Christophe Lintz; Manfred Keller
Original assignee: PARI GmbH
Current assignee: PARI Pharma GmbH
Priority date: 2003-10-15
Filing date: 2004-10-14
Publication date: 2006-06-28
Also published as: WO2005037246A2; DE10347994A1; RU2363449C2; BRPI0415470A; CA2542666A1; NZ546824A; US7758886B2; WO2005037246A3; AU2004281531A1; RU2006114451A; MXPA06004132A; US20050244339A1

Abstract

Disclosed are sterile aqueous preparations that are to be inhaled as an aerosol and contain an active substance, a nonionic surfactant, and a phospholipid. Said preparations are suitable for administering poorly soluble active substances by way of inhalation in the form of colloidal solutions and can also be used for administering bad-tasting active substances that irritate the mucus and cause cough or bronchoconstrictions. The inventive preparations can be nebulized by means of conventional devices and are preferably used in pediatrics.

Description

Aqueous aerosol preparation

Technical field of the invention

The invention relates to aqueous preparations for application as an aerosol. The preparations contain active ingredients and can be used pharmaceutically or to promote wellness. The invention relates in particular to sterile, aqueous preparations which are suitable for inhalation with a nebulizing system such as, for. B. a pump, nozzle, ultrasound, vibrating membrane nebulizer or other aerosol generation system are intended for aqueous preparations. It also relates to the nasal or pulmonary administration of physicochemically, organoleptically or physiologically problematic active substances. In further aspects, the invention relates to methods for producing such preparations and their uses.

Background of the Invention

The treatment of lung diseases by means of aerosols allows targeted

Medicinal therapy, since the active ingredient can be brought directly to the pharmacological destination using inhalation devices [D. Köhler and W. Fleischer: Theory and practice of inhalation therapy, Arcis Verlag GmbH, Munich, 2000, ISBN 3-89075-140-7]. The prerequisite is that the inhaled droplets or particles reach the target tissue and are deposited there. The smaller the diameter of the aerosol particles, the greater the likelihood that active substances will reach the peripheral lung areas. Depending on the type and extent of the deposition, diseases such as e.g. As asthma, chronic obstructive bronchitis (COPD) or a pulmonary emphysema quasi topically treat, but also active ingredients such. B. Transfer insulin into the bloodstream using predominantly alveolar absorption. Today, mostly propellant-driven metered dose inhalers, powder inhalers and liquid nebulizers are used to apply active ingredients. The type and extent of the deposition at the destination depend on the droplet or particle size, the anatomy of the respiratory tract of humans or animals and the breathing pattern. For the deposition of aerosols in the lungs of rodents, such as B. the rat you need much smaller droplets than z. B. for horses. For adult lung deposition, the aerosol droplets or particles should have an aerodynamic diameter of less than 5 - 6 μm, for small children less than 2 - 3 μm. Furthermore, small children breathe through the nose, which is why only nebulizing systems with a nasal mask should be used to apply active ingredients by inhalation. This restriction also applies to other species, such as rodents. The influences on aerosol production and deposition are essentially influenced by 3 factors, which can be broken down as follows:

(1) the biological-physiological factors, which are characterized by:

- the type of breathing maneuver, such as breathing frequency, flow, speed and volume,

- The anatomy of the respiratory tract, especially the glottic region

- The age and health or disease status of the patient

(2) the droplet or particle spectrum, which in turn is influenced by:

- the type and construction of the inhalation device - the time between generation and inhalation (drying properties)

- the modification of the droplet or particle ice spectrum by the inhalation flow

- The stability or integrity of the aerosol cloud generated

(3) the active ingredient or the active ingredient preparation, the properties of which are influenced by: - the particle size

- the dosage form (e.g. solution, suspension, emulsion, liposome dispersion)

- The shape and surface properties of the active ingredient particles or the carrier particles (smooth spheres or folded porous structures) in the case of powder aerosols

- the hygroscopicity (influences the growth of the particles) - the interface properties, such as wettability and spreadability

- The evaporation or evaporation properties of the carrier medium The advantages and disadvantages of the various inhalers and the possibilities to compensate for the system-related disadvantages were discussed by M. Keller [Development and Trends in Pulmonary Drug Delivery, Chimica Oggi, Chemistry today, No. 11/12, 1998].

The question of where aerosol particles deposit in the bronchial tree has been the subject of numerous studies for years. These are supplemented by constantly improving ones

Calculation models of lung deposition. The regional deposition pattern in mouth breathing is highly variable due to the breathing maneuver and the different anatomy of the bronchial tree. The respirable size range of 0.5 - 6 μm, which is often mentioned in the literature, does not take into account the overlapping deposit areas nor the quantitative or percentage deposition rates.

In a healthy adult, about 40-60% of the particles in the range of 2.5-4.5 μm are preferably deposited in the alveolar area by mouth breathing. A bronchial deposition in the order of magnitude of about 5 - 28% has particles of 2 to 8 μm, while the oropharyngeal deposition increases in parallel. The deposition in the oropharynx is already 25 - 45% for particles of 6 μm and increases to 60 - 80%. for particles with a diameter of 10 μm. From this it is deduced that particle sizes of 1, 5 - 3 μm are favorable for optimal qualitative and quantitative alveolar deposition in adults if the oropharyngeal and bronchial deposition should be as low as possible. The bronchial deposition with about 18 - 28% for particles in the size range of 6 - 9 μm is relatively low and is always accompanied by a correspondingly higher oropharyngeal deposition. Depending on the

Disease status, the geometry of the bronchial tree and the age of the patients shift the above orders of magnitude, especially in children and babies, to smaller particle sizes. In young children under the age of 1, it is discussed that only droplets and particles with an aerodynamic diameter smaller than 2 - 3 μm reach the deeper areas of the lungs to any appreciable extent.

For the treatment of sinusitis, it is also known that only the smallest aerosol droplets reach the paranasal sinus through the small ostial openings, with a pulsed aerosol in turn being able to deposit more active substance at the destination than with continuous nebulization.

The deposition of the aerosol particles in the respiratory tract is essentially determined by the following four parameters: - the particle size,

- the particle velocity,

- the geometry of the respiratory tract, and

- the inhalation technique or the breathing maneuver

According to Stokes' law, it can be deduced that the flow velocity and density of the aerosol particles are important, which is why the aerodynamic and not the geometric particle diameter is used as a measure of the deposition behavior in the respiratory tract. It is known from various studies that only droplet or particle sizes with an aerodynamic diameter of approximately 0.6-6 μm can be used for pulmonary therapy. Particles with an aerodynamic

Diameters larger than about 6 μm impact in the upper respiratory tract, those smaller than 0.6 μm are exhaled again after inhalation. This means that e.g. B. powder with very low density and an aerodynamic diameter of about 3 microns a geometric diameter of z. B. may have greater than 10 microns. In contrast, the geometrical and aerodynamic diameter is approximately the same for aqueous systems with a density of approximately 1 mg / cm ³ .

The composition and shape of the aerosols are very varied. Depending on their composition, aerosols have a short or long life; their droplet or particle size is subject to changes which are influenced by the physicochemical properties of the formulation components. Small, aqueous droplets evaporate quickly depending on the air humidity to a solid core, so that the concentration of the dissolved substance (s) is 100% when completely evaporated. The resulting diameter (d ₂ ) starting from the original diameter (d corresponds to the third root from the concentration ratio before (c and after (c ₂ ) shrinkage (assuming density of 1 g / cm ³ for the dissolved substance) according to the formula: d ₂ = di ³ !> £ & ι / c ₂ ), for example the drying of surf aerosols by the wind with a sea water droplet (c ^ = 3.6%) of 20 μm leads to a salt particle with a diameter of approx. 6.7 μm, which makes it respirable, and this effect is used, for example, in liquid nebulisers to reduce the particle size by drying effects (eg heating with PARI Therm) or by adding dry air.

Conversely, particles can grow in a moist environment, and this growth is particularly dependent on the hygroscopy of the active ingredient and / or excipient. For example a dry sodium chloride particle of 0.5 μm takes about 1 second to fully grow, with a 5 μm particle this takes about 10 seconds, which is proof that the speed with regard to particle growth is also size-dependent. Solid particles from powder nebulizers and metered dose aerosols can grow up to 4 - 5 times their original size, because the air humidity in the bronchial tree is 95 - 100%. (D. Köhler and W. Fleischer: Theory and practice of inhalation therapy, Arcis Verlag GmbH, Munich, 2000, ISBN 3-89075-140-7).

Rodents and dogs are often used for toxicological studies. Rodents breathe through the nose in a similar way to toddlers, which is why the aerosol should be applied using a nasal mask in order to achieve high lung deposition.

For the treatment of some lung diseases such as B. Asthma corticosteroids, beta-agonists and anticholinergics are predominantly used, which are brought directly to the site of action by means of metered dose inhalers, powder inhalers and jet or ultrasonic nebulizers. The pulmonary application of corticosteroids for the treatment of asthma has proven to be particularly advantageous compared to oral therapy because it is possible to effectively inhibit the underlying inflammatory process with much smaller doses of medication while significantly reducing the undesirable side effects. Active ingredients, such as beclometasone dipropionate (BDP), budesonide (Bud), and fluticasone propionate (FP) are mainly used as pump sprays for the treatment of allergic diseases in the nasal area, while for pulmonary application metered dose inhalers (MDI), powder inhalers (DPI) and Jet nebulizers are used.

Powder nebulisers are generally not suitable for the therapy of children under 5 years of age because the children are unable to generate the respiratory streams with which the powders can be reproducibly deagglomerated into respirable particles and deposited in the lungs with sufficient dosing accuracy , Metered aerosols in turn have the disadvantage that the aerosol is released at a speed of up to 100 km / h after actuation of the valve. As a result of the lack of coordination between the triggering of the spray and inhalation, more than 90% of the active ingredient impacted the throat, which can lead to undesirable side effects (hoarseness, voice changes, thrush, etc.). In addition, the evaporation of the propellant gas can cause a cold stimulus, which in hyper-reactive patients can lead to occlusion of the epiglottis or an asthma attack, which is why steroids should always be inhaled with ancillary chambers, so-called spacers with a volume of approx. 250 - 750 ml , There is nasal breathing for the application of steroids to small children who cannot carry out mouth breathing -specially spacer designs (e.g. Babyhaler ^® ). However, the use of MDIs and spacers is very complex because active substances sediment during the inhalation process, adsorb on the spacer walls or can become electrostatically charged. This can lead to inadequate dosing accuracy and non-reproducible drug therapy. This is the reason why nebulization of aqueous preparations by means of jet, membrane or ultrasonic nebulizers is advantageous for pulmonary application of active substances in children and toddlers compared to metered dose inhalers and powder inhalers if sufficiently small droplets or particles are generated.

The ideal prerequisite for therapy by means of nebulisation of an aqueous formulation is a drug which is sufficiently soluble and stable in water or isotonic saline solution and in which the chemical-physical characteristics do not change during the course of manufacture and storage. However, if the solubility of the drug is too low to produce an aqueous solution of sufficient concentration, nebulization in the form of a suspension can be considered. With the aid of a breath simulator, different nebulization efficiencies can be demonstrated with regard to the selected drug form (suspension or solution) (dose applied, amount of drug remaining in the nebulizer, etc.). The respirable, ie respirable part of the generated aerosol can be calculated by determining the percentage of active substance-containing droplets with a geometric or aerodynamic diameter of less than 5 or 3 μm by means of laser diffraction or impactor measurement [N. Luangkhot et. al .; Characterization of salbutamol solution compared to budesonide suspensions consisting of submicron and micrometer particles in the PARI LC STAR and a new PARI Electronic Nebuliser (eFlowT). Drug delivery to the Lungs XI, 11 & 12. 12. 2000, p.14 - 17]. In the study mentioned, it is reported that suspensions containing budesonide, in which the particle size of the suspended drug is significantly smaller than 1 μm, can be atomized as efficiently as a salbutamol sulfate solution, in contrast to a microsuspension. This finding is confirmed by Keller et al. [Nebulizer nanosuspensions. Important device and formulation interactions, Resp. Drug Delivery VIII, 2002, p. 197-206]. In addition, it is stated that microsuspensions should not be nebulized with an ultrasonic nebulizer. In the case of nebulization of a budesonide suspension (Pulmicort ^® ), ultracentrifugation could be used to show that approx. 4.6% of the budesonide was dissolved or solubilized in Pulmicort ^{® in a} molecularly dispersed manner and only this portion could be aerosolized by an ultrasonic nebulizer. The aqueous corticosteroid preparations previously available for nebulization are microsuspensions of beclomethasone dipropionate (Clenil ^® ), budesonide (Pulmicort ^® ) and fiuticasone propionate (Flixotide ^® ), i.e. the micronized active ingredient (approx. 90% of the suspended drug particles are smaller 5 μm) is finely dispersed and stabilized in water. The smaller the particle size of the active ingredient and the smaller the difference in density between the active ingredient and the dispersing medium, the longer the active ingredient remains in suspension, ie the slower sedimentation generally takes place. Before use, the sedimented particles or agglomerates must be finely dispersed again by shaking the packaging to ensure that as little active substance as possible remains in the container and that the nebuliser can be filled with the declared dose. For this purpose and to improve the wetting of the lipophilic active substance surface with water, a surfactant or wetting agent is usually added, but this must be harmless to inhalation toxicity in order to avoid undesirable side effects. As an example, Pulmicort ^{® should be} used, which is available in two dosage strengths of 0.5 mg and 1 mg budesonide per 2 ml. Budesonide is suspended in saline, which is buffered with citric acid and sodium citrate and contains polysorbate 80 (= Tween ^® 80) as a wetting agent. The average particle size of 3 measured Pulmicort ^® batches was larger than specified (approx. 2.8 - 3.2 μm) and spread between 3.7 and 4.4 μm. The differing finding may be due to the measurement method (laser diffraction), but also to particle growth or particle agglomeration. In a publication by Vaghi et al. [In-vitro comparison of Pumicort Respules with Clenil ^® per aerosol in combination with threee nebulisers, ERS, Annual Congress Stockholm, Sept. 14-18, 2002], electron microscope images of Pulmicort ^® and Clenil ^{® were} shown, from which it emerges that the particles in Clenil ^{® are} needle-shaped and mostly larger than 10 μm, while the Pulmicort ^® particles are more rounded and move in a range of approx. 1 - 6 μm in diameter. Another disadvantage is that the aerosol characteristics of such microsuspensions can change during nebulization. This can be done e.g. B. derive from the increase in the budesonide concentration in the non-nebulized residual Pulmicort ^® suspension. This effect can be explained, among other things, by the fact that larger particles cannot be transported by aerosol droplets with a smaller diameter and therefore remain as a residue in the nebuliser. In membrane nebulizers, the coarse particles are retained by the sieve effect of the membrane that generates the aerosol. This is not to be endorsed from an economic point of view.

In-vitro investigations with a Baby Cast SAINT model (Sophia Anatomical Infant Nose Throat) have shown that when using Pulmicort ^® and a Nozzle nebulizer could only detect about 1% of the declared amount of active substance as a lung dose. These findings coincide with e.g. T. with clinical findings from pediatricians who report inadequate efficacy of Pulmicort ^® nebulizer therapy in young children and thus explain that too little active ingredient can be transported into the lungs because both the particles and droplets are too large for young children.

Therapy of the nasal mucosa appears to be somewhat easier to handle. Here it usually succeeds with simple devices for aerosol generation such. B. mechanical atomizers to wet the mucous membrane with a preparation containing active ingredient. However, poorly soluble active ingredients also present a challenge here. The effectiveness of the active ingredient suspensions used in practice is rather low and not reliable in relation to the amount of active ingredient used, which is probably due to the particularly slow dissolution of the active ingredient in the small volumes of liquid available on the nasal mucosa stand, is due.

On the other hand, it is particularly difficult to treat the mucous membrane in the little-ventilated cavities of the upper respiratory tract with active ingredients that are easy to handle, and even more so with active ingredients that are difficult to dissolve. As a rule, only a very small proportion of the dose of a suspended active ingredient in aerosolized form reaches these target tissues.

State of the art

There are a number of proposals in the literature on how to solubilize or dissolve water-insoluble active substances. In particular, attempts were made to manufacture particulate systems with particle sizes in the nanometer range.

The publication DE 101 45 361 A1 describes methods for producing nanoparticulate systems and a method for producing a sterile submicron suspension. Although such submicron suspensions represent an advance over conventional microsuspensions with particle diameters of approx. 1-6 μm for the reasons set out above, they still have certain disadvantages, because even in the presence of a stabilizing wetting agent the particle growth due to "Ostwald Ripening" during the Storage cannot be completely suppressed. Under certain storage conditions, dissolved particles can also precipitate and promote particle growth as seed crystals. However, since particle size is fundamental to therapeutic efficiency, products are theirs Particle size cannot be kept constant during pharmaceutically usual storage times of 2-3 years, to be classified as critical.

WO 00/27376 describes nanoparticulate aqueous active substance preparations for the production of aerosols, the active substance particles having sizes of less than 1000 nm, preferably less than 50 nm. These preparations are produced using surface-modifying agents which adsorb on the surface of the active substance particles. Vitamin E-TPGS is suggested as such an agent.

The document RU 1280217 describes a propylene glycol-containing mixture as a solubilizer for the production of budesonide-containing aqueous preparations. This

However, preparations have a high viscosity and are hyperosmolar, which is why there is no irritation-free inhalation treatment, especially since the auxiliaries used have not yet been classified as harmless from an inhalation toxicological point of view. The use of propylene glycol leads to hyperosmolar solutions from a concentration of about 1%, which trigger a cough after inhalation. Furthermore, they have high viscosities, which is why formulations which have been produced using this auxiliary are unsuitable for inhalation therapy and, because of their physical properties alone, cannot be used with a vibrating membrane nebulizer.

In summary, it can be stated that the problem of the administration of poorly soluble active ingredients by nasal or pulmonary aerosols has not yet been satisfactorily solved. In particular, the pulmonary administration of such substances to pediatric patients is still extremely problematic according to the prior art.

Other types of active substances, the inhalative administration of which is not yet satisfactory, are substances which are perceived as unpleasant by the patient because of their organoleptic properties, in particular their bad taste, or because of their properties which irritate the mucous membranes or cause coughs or bronchoconstrictions. which can be an obstacle to adequate compliance with prescribed therapy and thus to therapy success. Description of the invention

It is therefore an object of the invention to provide improved preparations for application as an aerosol which do not have the disadvantages of the previously known preparations. In particular, it is an object of the invention to enable the inhaled administration of those active ingredients which, owing to their low water solubility, their bad taste or their properties which irritate the mucous membrane, could not be administered by inhalation or only in an unsatisfactory manner. Another object is to provide processes for the preparation of such preparations.

The primary task is solved according to the invention by a preparation according to claim 1. Preferred embodiments of the invention are specified in the subclaims.

It has been found that a combination of a nonionic surfactant and a phospholipid in aqueous inhalation preparations, especially in connection with physiologically or physicochemically problematic active ingredients, can impart desirable pharmaceutical properties to an extent unexpected from the knowledge of the mode of action of the individual surfactants, which are detailed below become.

The preparations according to the invention are aqueous preparations. This generic term refers to liquid compositions in which the liquid carrier or solvent consists predominantly of water and which, in addition to the carrier, contain at least one further substance which serves as an active ingredient or auxiliary. The liquid state of matter means that it is either a liquid single-phase system or a multi-phase system with a liquid coherent phase. The preparations of the invention thus include aqueous solutions, colloidal solutions, suspensions and emulsions. Even if the liquid carrier consists predominantly of water, it can in individual cases contain portions of one or more liquids which are at least partially miscible with water, e.g. As ethanol, glycerol, propylene glycol or polyethylene glycol. Preparations which are largely free of such non-aqueous liquids are preferred according to the invention.

In connection with the present invention, the term sterility is to be understood in the usual pharmaceutical sense. It is understood as freedom from germs capable of reproduction, and is proven by means of suitable tests, which are bindingly laid down in the currently valid pharmacopoeia. According to today's state of science contamination rate (Sterility Assurance Level) of ^{10 -6} is considered acceptable for sterile preparations in general, that in a million units a unit may be contaminated. In practice, however, the contamination rate is likely to be higher. So you go z. B. assume that in aseptically prepared preparations the contamination rate should be around 10 ^"3. On the one hand, the scope of sterility tests for quality control of batches according to the pharmacopoeia is limited and, on the other hand, even contamination can be caused as artifacts when the tests are carried out, it is difficult to demand sterility in the absolute sense as a property or to prove it for a certain object. Therefore, the sterility of a preparation should be understood here in particular so that the preparation in question meets the requirements of the currently valid pharmacopoeia with regard to sterility.

In order to be suitable for inhalation, preparations must be present as an aerosol or, as provided according to the invention, can be converted into an aerosol in situ. Aerosols are generally defined as dispersions of liquid or solid particles (= particles) in a gas - usually in air. Aqueous preparations which can be converted into aerosols for use must - unlike e.g. B. organic solutions or suspensions in pressure-liquefied propellants - be aerosolized in special nebulizers.

The preparations according to the invention are now characterized in that they contain an active ingredient and a combination of a nonionic surfactant and a phospholipid.

An active ingredient is to be understood here as a substance or mixture of substances which can be used for therapeutic, diagnostic, prophylactic or other purposes serving the well-being. The active ingredient can be a chemically defined ("small") molecule or a peptide, protein or polysaccharide derived from nature. The active ingredient is not a surfactant and preferably not another substance, which is also usually used as a pharmaceutical excipient and the effect of which is predominantly based on its physicochemical properties.

Surfactants are to be understood as amphiphilic, surface or surface-active substances. Such compounds have at least one more hydrophilic and at least one more hydrophobic or lipophilic molecular region. They accumulate in phase boundaries and lower the interfacial tension. Among other things, surfactants are used to stabilize multiphase systems. Non-ionic surfactants are surfactants that do not have a real ionic charge in aqueous media at largely neutral pH values (e.g. between pH 4 and 10), but at most partial charges. Phospholipids are defined as amphiphilic lipids that contain phosphorus. Also known as phosphatides, they play an important role in nature, particularly as double-layer-forming components of biological membranes. Phospholipids which are chemically derived from phosphatidic acid are widespread and frequently used for pharmaceutical purposes. This is a (mostly double) acylated glycerol-3-phosphate, in which the fatty acid residues can be of different lengths. The descendants of phosphatidic acid are e.g. B. the phosphocholines or phosphatidylcholines, in which the phosphate group is additionally esterified with choline, phosphatidylethanolamines, phosphatidylinosites, etc. lecithins are natural mixtures of various phospholipids, which generally have a high proportion of phosphatidylcholines.

Suitable nonionic surfactants are, above all, those that are considered safe for inhalation. These primarily include tyloxapol, polysorbates, especially polysorbate 80, and vitamin E TPGS. The most preferred nonionic surfactant currently by the inventors is tyloxapol.

Suitable phospholipids are also those that are suitable for inhalation administration due to their physiological properties. These include, above all, phospholipid mixtures which are extracted in the form of lecithin from natural sources such as soybeans or chicken egg yolk, preferably in hydrogenated form and / or freed from lysolecithins, and purified, enriched or partially synthetically obtained phospholipids, preferably with saturated fatty acid residues. Purified, enriched or partially synthetically obtained medium to long-chain zwitterionic phospholipids are particularly preferred which are largely free of unsaturation in the acyl chains and free of lysolecithins and peroxides. Of the phospholipid mixtures, lecithin is particularly preferred. Examples of enriched or pure compounds are dimyristoylphosphatidylcholine (DMPC),

Distearoylphosphatidylcholine (DSPC) and Dipalmitoylphosphatidylcholine (DPPC). Of these, DMPC is currently the most preferred. Alternatively, phospholipids with oleyl residues and phosphatidylglycerols without choline residues are suitable for some configurations and applications of the invention.

The fact that the combination of tyloxapol with a phospholipid is pharmaceutically and physiologically acceptable is evident, among other things, from the fact that it is contained in the inhalation product Exosurf Neonatal ^® . The product is used to replace lung surfactant in acute neonatal respiratory distress syndrome (RDS). Unlike in the Preparations according to the invention contains Exosurf Neonatal ^® surfactants other than itself has no further active ingredient in the traditional sense.

In one preferred embodiment, the preparation contains tyloxapol as a nonionic surfactant and lecithin as a phospholipid, and in a further preferred embodiment, tyloxapol as a nonionic surfactant and DMPC as a phospholipid.

In individual cases it can be advantageous to use a further surfactant in addition to the nonionic surfactant and the phospholipid. This can be another nonionic surfactant, another phospholipid or an ionic surfactant without phosphorus. However, it is preferably a nonionic surfactant. The nonionic surfactants already mentioned are particularly suitable.

The surfactant to be used according to the invention and the phospholipid to be used according to the invention can fulfill different functions. However, one of the remarkable effects of the combination is its ability to solubilize poorly soluble active ingredients colloidally, better than is possible with a single surfactant - even with a correspondingly increased concentration within the physiologically acceptable limits (see also Example 1).

The use of the surfactant combination in inhalation preparations for the colloidal solubilization of poorly soluble active ingredients is an important embodiment of the invention. In a preferred embodiment, the preparation is therefore a single-phase system, i.e. H. as an aqueous solution. “Single-phase” and “solution” also mean, in particular, colloidal solutions in which the solutes or some of them are present in a colloidal dispersion rather than in a molecularly dispersed manner. Without the inventors wishing to restrict themselves to the validity of certain theories, it can be assumed that in many cases the surfactants of the preparations according to the invention form micelles or mixed micelles in which poorly soluble active ingredients can be solubilized. The position of the molecules that are solubilized in such micelles or mixed micelles depends on the structure of these molecules and the surfactants used. For example, it can be assumed that particularly non-polar molecules are primarily located inside the colloidal structures, while polar substances are more likely to be found on the surface.

The colloidal systems, as the single-phase preparations can present themselves, therefore contain particles that are on average in the colloidal size range, i.e. below about 1 μm according to the generally customary definition, or between 1 and about 500 nm, as described by other sources (H. Stricker, Physikalische Pharmazie, 3. Edition, p. 440). They are therefore practically invisible with a light microscope and do not lead to a pronounced clouding of the solution, but at most to an opalescence. The single-phase, colloidal preparations of the invention preferably contain association colloids with an average particle size of less than 500 nm (measured by photon correlation spectroscopy). Colloids with medium ones are particularly preferred

Particle sizes up to about 200 nm, and in further preferred embodiments, colloids with average particle sizes up to about 100 nm and up to about 50 nm are included.

In addition to the micelles, mixed micelles and other colloidal structures in the lower size range, it is also possible for the surfactants to form colloids with double-membrane structures in which poorly soluble active ingredients can also be present in solubilized form. Such colloids appear mainly as liposomes. Methods for the production and characterization of liposomes and liposomal preparations are known per se to the person skilled in the art. Among the known liposomes, those are preferred according to the invention which have a predominantly colloidal size, i. H. whose average particle size is below about 1 μm, better still at a maximum of about 500 nm or even at a maximum of about 200 nm. An average particle size of up to about 200 nm generally allows sterile filtration through a filter with a pore size of 0.22 μm.

Depending on which structures are to be formed and which other pharmaceutical effects are to be achieved, the weight ratio between the nonionic surfactant and the phospholipid must be determined or optimized, taking into account the selection of the surfactants. According to the invention, a weight ratio of about 5: 1 to about 1: 2 is preferred. Particularly good solubilization is usually achieved with ratios of about 3: 1 to 1.5: 1, that is to say with a slight excess of the nonionic surfactant, for example about 2: 1 This is particularly true if the preferred tyloxapol is selected as the nonionic surfactant and the preferred DMPC (or DPPC or DSPC) as the phospholipid. In particular, poorly soluble corticoids such as budesonide can be surprisingly well solubilized.

The total content of surfactant in the preparation should be limited to a maximum value of approximately 3% by weight, especially for physiological reasons, if pulmonary application is provided. With a nasal application, higher amounts of surfactant can also be considered, e.g. B. up to about 10 wt .-%. To avoid irritation of the mucous membrane, it would be advantageous to limit the surfactant content to as little as possible not more than about 5% by weight. In contrast, in the case of pulmonary application, the preparation preferably contains a surfactant content of approximately 0.01 to 3.0% by weight. Contents of about 0.1 to 2.0% by weight are particularly preferred. However, the optimal amount of surfactants used also depends on the active ingredient, ie its physicochemical properties and its content in the preparation, as well as on the selection of the surfactants and the intended effects and

Product characteristics. If, for example, the solubilization of a poorly soluble active ingredient such as budesonide is primarily intended and the preferred surfactants tyloxapol are selected in combination with DMPC or lecithin, the particularly preferred total surfactant content is about 1 to 2% by weight, in particular about 1.5% by weight. -%. If, on the other hand, an improvement in the organoleptic properties of the preparation is desired, u. U. a significantly lower surfactant content is sufficient and therefore pharmaceutically advantageous, e.g. B. a content of not more than about 1.0 wt .-%, and better still one of not more than about 0.5 wt .-%.

As already mentioned, the active ingredient content must of course also be taken into account. Very low-dose active ingredients tend to be both solubilized and masked in taste with lower surfactant contents. In addition, smaller amounts of surfactant are sufficient to alleviate the properties of active substances that are irritating to the mucous membranes, which cause cough and bronchospasm. A preferred weight ratio between the surfactant content (i.e. total content of surfactant and phospholipid) and active ingredient content is at least about 1: 1, particularly preferably at least about 5: 1. Ratios of more than 10: 1 may even be required for the solubilization of some poorly soluble active ingredients. In a preferred embodiment, a ratio of about 50: 1 to 100: 1 should be selected for the solubilization of the poorly soluble active ingredient budesonide. However, significantly lower surfactant-drug ratios can usually suffice if no colloidal solubilization of the drug is desired or necessary and the surfactant mixture is used primarily to mask undesirable organoleptic or physiological properties of the drug or to improve the spreading of the aerosol in the respiratory tract.

When selecting the surfactants, the surfactant content and the ratio of the same to the active ingredient content, the effects on the physicochemical properties of the preparation which are important for atomization into an aerosol that can be administered by inhalation must of course be considered. Above all, this includes surface tension and dynamic viscosity.

The surface tension, especially for pulmonary application, should be set so that it is approximately 25 to 80 mN / m, preferably approximately 30 to 75 mN / m. It is too Please note that a particularly good spread of the preparation in the respiratory tract is to be expected in the lowest area of this interval, but that the quality of the aerosol and the efficiency of the nebulization can suffer. On the other hand, with the use of surfactants, which is necessary for the colloidal solubilization of a poorly soluble active ingredient, it can hardly be avoided that the surface tension is lowered quite far below that of water or physiological buffer solution. In each case, a compromise can be found that has to be adjusted depending on the active ingredient and the intended use. Especially for the solubilization of poorly soluble active ingredients, a surface tension in the range from about 30 to 50 mN / m is particularly preferred.

The dynamic viscosity also has a significant influence on the

Particle size distribution of the aerosol generated during the nebulization and on the nebulization efficiency. It should be set in the range from about 1 to about 3 mPas. A dynamic viscosity in the range from approximately 1.0 to approximately 2.5 mPas is particularly preferred.

As mentioned above, aqueous preparations according to the invention are to be used for application as an aerosol which is used in situ. H. immediately during use - generated by a suitable device. Common types of nebulizers with which such preparations can be aerosolized have already been presented at the beginning. Nozzle nebulizers have been used in therapy for a long time, and for some time also ultrasound nebulizers. Recently, powerful nebulizers have been developed that are named after their piezoelectric, electrohydrodynamic and / or functional principle based on a vibrating membrane or with pores (e.g. eFlow ™, eFlow Baby ™, AeroNeb ™, AeroDose ™ or AERx ™) are. The different mechanisms of aerosol production lead to differences in the nebulization quality for certain preparations.

The preparations of the present invention are particularly geared to the requirements of nebulization by the nebulizers (vibrating membrane nebulizers) working with vibrating, porous membranes. A particularly preferred nebulizer for which the preparation is intended to be used is the eFlow ™ from Pari GmbH. This nebulizer and the devices of a similar type are particularly suitable for modern aerosol therapy: they are small and nebulize relatively large volumes of liquid within a short period of time to generally high-quality aerosols. Of course, these nebulizers also have limitations or application problems, e.g. B. when it comes to the nebulization of suspensions of poorly soluble active ingredients. The fact that during aerosol generation, the inhalation liquid is extruded through the pores of a vibrating membrane, larger solid particles are either completely excluded from aerosolization (if their diameter is at least approximately as large as the pore diameter) or - with particle sizes in the lower micrometer range - at least lead to a more or less pronounced sieving effect. This leads to a reduced active ingredient content in the aerosol actually released by the nebulizer and available for inhalation. The present invention is particularly advantageous for the administration of poorly soluble active ingredients with such nebulizers: for example, these active ingredients can now be formulated and inhaled as a colloidal solution instead of as a microsuspension, which practically eliminates or at least significantly reduces the sieving effect through the pores of the membrane.

In another embodiment of the invention, the preparation for the treatment of the oral or nasal mucosa is e.g. B. in allergic rhinitis, vasomotor rhinitis, nasal polyps, or in inflammatory diseases of the oral mucosa. In principle, very simple devices for generating the aerosol can also be used for this application, e.g. B. mechanical atomizers, as are often used for oral or nasal sprays. Alternatively, nozzle, ultrasonic or piezoelectric ones can also be used

Vibrating membrane nebulizers are used, which may need to be adapted accordingly in the case of nasal application.

In a further embodiment, the preparation is intended for the treatment of the mucous membrane of the sinus, jaw or frontal sinus. These mucous membranes are basically accessible to aerosol therapy. The efficient application of an aerosol is difficult due to the low ventilation of these cavities and can hardly be carried out with the usual nebulizers. The simple nasal inhalation of an aerosolized active ingredient preparation leads it close to the sinuses, but the aerosol flow predominantly passes through the openings (ostia) to the sinuses without a significant proportion of the aerosol entering the sinuses. On the other hand, the frontal and paranasal sinuses are very often the site of inflammatory processes that can be treated with budesonide.

Recently, however, specially adapted jet nebulizers have become available, with which the sinuses can be reached much better than before. On the one hand, these nebulizers have a nose piece for directing the aerosol flow into the nose. If only one nostril is used to inhale the aerosol, the other must be closed using a suitable device. These nebulizers are also characterized by the fact that they release an aerosol with pulsating pressure. The pulsating pressure zones ensure intensive ventilation of the sinuses, so that an aerosol inhaled at the same time can be better distributed in these cavities. Examples of corresponding nebulizer devices are disclosed in DE 102 39 321 B3. In one of the preferred embodiments, the preparation of the invention is used to produce a medicament for application with the aid of one of the devices described there for the treatment of infections of the upper respiratory tract, in particular with a device of the PARI Sinus type.

In the sense of a compatible aerosol, the preparation should be adjusted to the most physiological tonicity or osmolality possible. It is therefore desirable to have an osmolality that is not too strongly different from that of physiological liquids, ie. H. deviates from about 290 mOsmol / kg. However, here too, compromises have to be made in individual cases between the physicochemical or pharmaceutical requirements on the one hand and the physiological requirements on the other. In general there is an osmolality in the

Range of about 200 to 550 mOsmol / kg and in particular in the range of about 230 to about 350 mOsmol / kg are preferred for the preparations according to the invention.

If the required or desired osmolality is undershot by the active ingredient and the surfactants contained in the preparation, it can be adjusted to the desired value by adding one or more suitable, osmotically active auxiliaries. Such auxiliaries are above all harmless mineral salts that react largely neutrally (unless, such auxiliaries should adjust or buffer the pH at the same time), such as. B. sodium, calcium or magnesium chlorides, sulfates or phosphates. One of the particularly preferred adjuvants is sodium chloride. Magnesium and calcium sulfate and chloride are further preferred auxiliaries for this purpose. It is known from these calcium and magnesium salts that they can have a positive or supportive influence on the inhalation of active ingredient solutions, possibly because they themselves counteract the local irritation caused by the application and exert a bronchodilatory effect, which is currently in the clinical literature is postulated (e.g. BR Hughes et al., Lancet. 2003; 361 (9375): 2114-7). Magnesium sulfate in particular has excellent pulmonary tolerance.

As an alternative to the neutral mineral salts, physiologically acceptable organic auxiliaries can also be used as isotonizing agents. Water-soluble substances with a relatively low molecular weight, for. B. with a molecular weight of less than 300, or better still less than 200, and with a correspondingly high osmotic activity. Examples of such auxiliaries are sugar and sugar alcohols, in particular trehalose, mannitol, sorbitol and isomalt.

In the sense of a compatible aerosol, the preparation according to the invention should be adjusted to an euhydric pH. The term euhydrisch already includes that in turn, a tension can exist between pharmaceutical and physiological requirements, so that a compromise must be found, e.g. B. just guaranteed in the economic sense sufficient stability of the preparation during storage, on the other hand is largely compatible. The pH value is preferably in the slightly acidic to neutral range, that is between pH values of approximately pH 4 to pH 8. It should be noted that deviations from the weakly acidic environment can be tolerated rather than shifts in the pH value in the alkaline area. A pH in the range from about 4.5 to about 7.5 is particularly preferred.

Again, physiologically largely harmless acids, bases and salts can be used to adjust and, if necessary, buffer the pH. Suitable auxiliaries for lowering the pH or as acidic components of a buffer system are strong mineral acids, especially sulfuric acid and hydrochloric acid. Furthermore, medium-strong inorganic or organic acids and acid salts are also possible, for. As phosphoric acid, citric acid, tartaric acid, succinic acid, fumaric acid, methionine, acidic hydrogen phosphates with sodium or potassium, lactic acid, glucuronic acid, etc. However, most preferred are sulfuric acid and hydrochloric acid. Mineral bases such as sodium hydroxide or other alkali and alkaline earth metal hydroxides and oxides such as in particular magnesium hydroxide and calcium hydroxide, ammonium hydroxide and basic ammonium salts such as ammonium acetate and basic amino acids such as lysine are particularly suitable for raising the pH or as basic components of a buffer system , Carbonates such as sodium or magnesium carbonate, sodium hydrogen carbonate, citrates such as sodium citrate etc.

In a preferred embodiment, the preparation according to the invention contains a buffer system consisting of two components, and one of the particularly preferred buffer systems contains citric acid and sodium citrate.

The chemical stabilization of the preparation by additional additives may be indicated not primarily from physiological, but from pharmaceutical considerations. This mainly depends on the type of active ingredient contained. The most common degradation reactions of chemically defined active substances in aqueous preparations include, above all, hydrolysis reactions, which are primarily limited by an optimal pH setting, as well as oxidation reactions. Examples of active substances which are susceptible to oxidation are those which have olefinic, aldehyde, primary or secondary hydroxyl, ether, thioether, endiol, keto or amino groups. In the case of such active substances which are sensitive to oxidation, the addition of an antioxidant or an auxiliary which is synergistic with an antioxidant may therefore be recommended or necessary. Antioxidants are natural or synthetic substances that can prevent or interrupt the oxidation of the active ingredients. These are primarily auxiliaries that can themselves be oxidized or occur as reducing agents, such as tocopherol acetate, reduced glutathione, catalase peroxide bismuthase. Synergistic substances are e.g. B. Those that do not appear directly as reactants in oxidation processes, but which counteract oxidation by an indirect mechanism such as the complexation of metal ions that have a catalytic effect on oxidation, as is the case, for example, with EDTA derivatives (EDTA: ethylene ediaminetetraacetic acid ) the case is. Other suitable antioxidants are ascorbic acid, sodium ascorbate and other salts and esters of ascorbic acid (e.g. ascorbyl palmitate), fumaric acid and its salts, malic acid and its salts, butylated hydroxyanisole, propyl gallate and sulfites such as sodium metabisulphite. In addition to EDTA and its salts, citric acid and citrates, malic acid and its salts and maltol (3-hydroxy-2-methyl-4H-pyran-4-one) may also act as chelating agents.

In one of the preferred embodiments, the preparation contains at least one antioxidant. In a further embodiment, it contains both an antioxidant and a chelating agent. The combination of a vitamin E derivative, in particular vitamin E acetate, with an EDTA derivative, in particular sodium edetate, is particularly preferred. With certain active ingredients, this combination has proven to be particularly advantageous for achieving a high chemical stability and durability of the preparation. This combination of excipients is particularly preferred in combination with the active ingredient budesonide.

As already mentioned, the combination of a nonionic surfactant and a phospholipid according to the invention has a markedly high ability to collubilize poorly soluble active ingredients. It can be assumed that micelles or mixed micelles with a lipophilic core and a hydrophilic outer region form. A particular advantage of colloidal solutions like these is that they are better (i.e. without high

Loss of active ingredient in the nebulizer) can be aerosolized and that aerosols with finer droplet sizes can be produced than this, for. B. is the case in the case of microsuspensions.

An aerosol with a small average particle size or with a high proportion of droplets in the lower micrometer range is particularly important if inhalation is to reach the deeper regions of the respiratory tract, ie the fine branches of the bronchioles or even the alveoli. It is also particularly important and advantageous if the patients are children whose anatomical structures are significantly smaller than those of adults. In one of the preferred embodiments, the preparation is therefore intended for use on children, with which infants, toddlers, Children and adolescents are meant. In particular, the determination for use on infants and young children is preferred.

Another advantage of micellar and mixed micellar solutions is that they can be filtered through membrane filters with a pore size of 0.22 μm to remove any germs (sterile filtration). This method of sterilization is particularly important whenever heat or radiation sterilization does not seem possible or is not favorable for chemical or physicochemical reasons.

The achievable by the inventive surfactant combination of colloidal solutions over microsuspension such. B. Pulmicort ^® suspension for inhalation is therefore obvious. Accordingly, in a particularly preferred embodiment, the active ingredient is a poorly water-soluble active ingredient. Active substances that are sparingly soluble in water are substances that are used in aqueous media at room temperature and largely neutral pH, eg. B. at pH 4 to pH 10, but especially at pH 5 to 8 are sparingly soluble. In this context, sparingly soluble means that the solubility of an active ingredient is so low that at least 30 parts of water are required to dissolve one part of the active ingredient. This corresponds to substances which can be assigned to the frequently used terms "sparingly soluble", "slightly soluble", "very slightly soluble", "practically insoluble" and "insoluble". Poorly soluble active ingredients are also to be understood as meaning poorly soluble active derivatives or salts of active ingredients, of which there are definitely more soluble salts or derivatives. The invention is particularly advantageous for the formulation of active ingredients which have a saturation solubility in water at room temperature of not more than about 0.1% by weight. In addition, active ingredients of the categories "very slightly soluble", "practically insoluble" and "insoluble" are particularly preferred.

In a further preferred embodiment, it is a poorly soluble active ingredient which belongs to the group of corticoids, betamimetics, anticholinergics, anesthetics,

Immunomodulators and anti-infectives including antibiotics, antivirals and antifungals is selected. A particularly preferred poorly soluble active ingredient is budesonide.

The content of the sparingly soluble active ingredient is generally not more than about 2% by weight, preferably in the range from about 0.01 to 1.0% by weight. In the case of budesonide, a colloidal solution with an active ingredient content of approximately 0.15 to 0.35 mg / ml is particularly preferred, and very particularly with a content of approximately 0.2 mg / ml. In this embodiment, a physiologically well-tolerated preparation is provided which, in contrast to the previously known budesonide preparations for inhalation with modern nebulizers, also with Those that work with a porous, vibrating membrane can be nebulized quickly, efficiently and without major loss of active ingredient, and that to fine, high-quality aerosols that are also suitable for pediatric use.

In addition to the described advantages for the formulation of poorly soluble active ingredients, the preparations according to the invention offer further advantages and

Applications. For example, the inventors found in test trials that preparations with a combination of a nonionic surfactant and a phospholipid are surprisingly able to mask the bad taste of active ingredients during inhalation. A pronounced bad taste is extremely unpleasant and annoying when inhaling aerosols, and it can lead to non-compliance and thus to therapy failure. The bad taste is perceived by the patient through the proportion of the aerosol, which is reflected in the inhalation in the mouth and throat. Even if it can be achieved by optimizing the particle size of the aerosol that the smallest possible proportion of the preparation is deposited there - this is also lost for the therapy, unless the mucous membrane of the mouth, throat or nose area is the tissue to be treated - it is hardly achievable with today's means that this proportion is reduced so much that the bad taste of an active ingredient is therefore no longer perceived. In this respect, a taste lamination, which is imparted by the combination of excipients in the preparation, is particularly advantageous.

Accordingly, in a further, preferred embodiment, the preparation according to the invention contains a bad-tasting active ingredient. A bad taste can have different forms, all of which are included here, e.g. B. acidic, sharp, metallic, biting, bad, spoiled, anesthetic, etc. The active ingredient with bad taste - in contrast to other embodiments of the invention - can have any water solubility. The active ingredient preferably belongs to the group of corticoids, betamimetics, anticholinergics, anesthetics and anti-infectives. A preferred active ingredient in this context is the antibiotic tobramycin, including its salts and other derivatives.

Poor drug activity sometimes, but not necessarily, goes hand in hand with irritation of the mucous membrane caused by the substance. Different stages occur, which can lead to slight irritation of the throat and / or the respiratory tract to coughing, coughing fits, bronchoconstrictions and bronchospasms when inhaled. From the inventors Inhalation tests carried out with such substances surprisingly indicate that these undesirable effects can also be mitigated or concealed by the inventive preparation of the preparation. In a further embodiment of the invention, the preparation accordingly contains an active ingredient which irritates the mucous membrane or causes cough or bronchoconstrictions. This active ingredient can have any water solubility. In this context, preference is again given to those active ingredients which come from the group of corticoids, betamimetics, anticholinergics, anesthetics and anti-infectives.

A particularly preferred active ingredient is the antibiotic tobramycin, including its salts and derivatives. This ingredient is known to be coughing and

Can trigger bronchoconstrictions if it is applied in the form of the previously known preparations.

Other preferred active ingredients, some of which can be assigned to the preferred criteria already defined for the active ingredients contained in the preparation, are selected from the group consisting of corticosteroids, beta-sympathomimetics, anticholinergics, local anesthetics, immunomodulators, anti-infectives, angiotension converting enzyme (ACE) inhibitors, cytostatics, in particular Budesonide, ciclesonide, fluticasone, mometasone, beclomethasone, flunisolide; Formoterol, salmeterol, levalbuterol; Thiotropium, oxitropium, ipratropium; Lidocaine, prilocaine, mepivacaine, bupivacaine, articaine, ciclosporin, tacrolimus, sirolimus, rapamycin, azathioprine; Ciprofloxacin, moxifloxacin, azithromycin, clarithromycin, erythromycin, metronidazole, ketoconazole, itraconazole, voriconazole, clotrimazoi, bifonazole, fluconazole, amphotericin B, natamycin, nystatin, amikaciraminacinaminacinaminacin , Ribivarin, captopril, lisinopril, perindopril, trandolapril, cilazapril, carmustine, lomustine, taxol, etopside, cis-platinum; Acetylcysteine, N-acetylcysteine, reduced glutathione, TNF-alpha antibodies including the pharmaceutically acceptable derivatives of these substances such as. B. the salts, conjugates, enantiomers, racemates, epimers, diastereomers or complexes of one of these active ingredients.

In a further embodiment, the preparation contains at least one further active ingredient. This can be advantageous in asthma therapy, for example, if more than one active ingredient has to be inhaled for therapeutic reasons and the patient should be able to use it with as little time as possible. Important combinations of active ingredients in this context are e.g. B. (a) a betamimetic and a parasympatholytic, (b) a betamimetic and a corticoid, and (c) a parasympatholytic and a corticoid. Other combinations are available with mast cell stabilizers such as cromoglicic acid or nedocromil including their therapeutically usable salts. Combinations of antibiotics and bronchodilators as well as a mucolytic agent can also be useful. In principle, the addition of physiologically safe and well-tolerated antioxidants, such as. B. tocopherols, catalase, peroxide bismuthase, since these can trap or reduce radical oxygen, which is responsible for many inflammatory processes.

In addition to therapeutic agents, agents can also be selected which are primarily intended for diagnostic, prophylactic or well-being purposes. A preparation according to the invention can accordingly be intended for therapeutic, diagnostic and prophylactic applications. The determination for therapeutic use is particularly preferred.

Regardless of whether a therapeutic, diagnostic or prophylactic effect is intended, the active ingredient can be administered in the form of the preparation according to the invention in order to have its effect locally (e.g. in the nose, throat or bronchial tubes) at or near the Mucous membrane of the respiratory tract to develop, or it can have a systemic effect after absorption into the bloodstream. However, a more local effect will be the focus of therapy for respiratory diseases of the upper and lower respiratory tract.

The use of the preparation of the invention is particularly advantageous for the production of medicaments which are used for the prophylaxis or treatment of bronchial or pulmonary diseases or symptoms, e.g. B. bronchial asthma or chronic obstructive bronchitis. In this case, the preparation is preferably intended for inhalation with a nozzle, ultrasound or piezoelectric vibrating membrane nebulizer, e.g. B. with a PARI eFlow ™ or - in the case of a pediatric application - an eFlow Baby ™.

The preparation of the invention can also be used for the production of medicaments which are to be used for the prophylaxis or treatment of diseases or symptoms of the mucous membrane of the forehead, jaw or paranasal sinuses, e.g. B. from acute and chronic sinusitis or from polyps. For this use it is advantageous if the application of the preparation with the aid of a nozzle nebuliser such as. B. happens the PARI Sinus, which is specially adapted for this application. Such suitable nebulizers have on the one hand a nose piece for directing the aeroso stream into the nose. If only one nostril is used to inhale the aerosol, the other must be closed using a suitable device. Furthermore, these nebulizers are characterized in that they let out an aerosol with pulsating pressure. The pulsating pressure waves ensure intensive ventilation of the sinuses, so that an aerosol inhaled at the same time can be better distributed in these cavities. Examples of corresponding nebulizer devices are disclosed in DE 102 39 321 B3.

Alternatively, the use of the preparation of the invention for the manufacture of medicaments intended for the prophylaxis or treatment of diseases or symptoms of the mucous membrane of the oral and / or nasal cavity, e.g. B. from stomatitis, aphthae, allergic rhinitis, vasomotor rhinitis, chronic rhinitis, or polyps. In this case, the application can be carried out by a device with a mechanical atomizer, as is often used in nasal or mouth sprays, or with the aid of a possibly adapted nozzle, ultrasound or vibrating membrane nebulizer.

The preparation is produced using a combination of process steps known per se, each of which must be selected and, if necessary, adapted in view of the special requirements of the active ingredient and the desired product properties. In addition to the general pharmaceutical requirements that apply to all pharmaceutical preparations, the special requirements for preparations for inhalation must also be taken into account. The preparations must be sterile, that is to say they must be free of any reproductive elements, which must be ensured by careful selection and execution of the process steps. Additional requirements may arise from special application regulations. If e.g. B. the preparation for inhalation with a nebulizer of the type that works with porous, vibrating membranes is intended, must by the manufacturing process u. a. ensure that the size of the active ingredient particles - if present - are actually below the limit above which an undesirable sieving effect occurs.

If the preparation is an aqueous solution, which includes colloidal, e.g. B. micellar or mixed micellar solutions are to be understood, and if heat sterilization in the final container is not possible due to the physical or chemical thermolability of the preparation or individual components thereof, sterile filtration is a suitable sterilization process. Even if the preparation is an aqueous suspension, such as a microsuspension, final sterilization can be critical, since it can change the particle size distribution of the suspension particles considerably and thereby influence important properties of the preparation. In the case of solutions and colloidal solutions, one of the preferred manufacturing processes can include the following process steps:

(a) the provision of the intended ingredients;

(b) the production of a liquid, aqueous preparation from the intended ingredients;

(c) sterile filtration of the preparation prepared in step (a); and

(d) filling the sterile-filtered preparation in step (b) into sterile containers under aseptic conditions.

In a variant of the manufacturing process, the ingredients in process step (a) are provided in a sterile state in order to limit the initial germ load of the preparation. If not all of the starting materials can be provided in a sterile state, at least those should be pre-sterilized for which this is possible without compromising quality.

The aqueous preparation from the intended ingredients or starting materials after step (b) can be produced in several substeps. So z. B. first of all, the preparation of an aqueous solution (possibly colloidal solution) of the nonionic surfactant and the phospholipid and possibly other auxiliary substances. To form a homogeneous colloidal solution, it can be advantageous to use a process step with a relatively high energy input, e.g. B. a homogenization step under increased pressure (high pressure homogenization), sonication or heating to about 45 ° C, to about 50-70 ° C or even higher temperatures. To reduce the bacterial load and to increase the effectiveness of subsequent germ reduction measures, sterilized or low-germ starting materials should be used, if possible, and if possible under aseptic conditions. Furthermore, it might be appropriate to subject this colloidal auxiliary solution produced in a first sub-step of process step (b) to a heat sterilization process.

In a further sub-step, the active ingredient would then have to be dissolved in the colloidal solution thus produced, if possible again under aseptic conditions. This is preferably done without any application of comminution processes in which solid active ingredient particles are mechanically broken up. Rather, it is preferred that energy input at this process stage - if necessary - be carried out by supplying heat or possibly by ultrasound. In many cases, however, the active ingredients can be incorporated solely by stirring, even the colloidal distribution of poorly soluble active substances into micelles or mixed micelles.

In a directly or indirectly following process step, the previously prepared, active ingredient-containing solution or colloidal solution is sterile filtered, i. H. through a filter - e.g. B. a membrane filter - filtered with a pore size of about 0.22 microns, possibly using pressure to remove the germs and particles contained in the solution. Suitable sterile filtration methods are known in principle to the person skilled in the art in various variants together with the devices that can be used for them.

In a further process step, directly or indirectly, the previously sterile-filtered solution or colloidal solution is placed under aseptic conditions in the

Primary packaging, d. H. filled into the final containers, which are then sealed. The suitable design variants and devices are also known per se for this method step.

The primary packaging can be glass containers (e.g. vials) with sealing devices made of elastomers and metal safety caps, alternatively plastic ials or blister-like primary packaging systems. A single primary packaging can contain a single dose or multiple of them. In all cases, however, in which heat sterilization of the preparation is possible and does not lead to a significant loss in quality, a method is preferred which, instead of sterile filtration, includes the final sterilization of the preparation by a medication-compliant heat sterilization process after it has been filled into the primary packaging.

Suitable primary packaging made of plastic are e.g. B. polypropylene or polyethylene vials (PP / PE vials) and cycloolefin copolymer blister (COC blister). Sealed plastic containers such as PP or PE vials can, for example, be advantageously molded, filled and sealed using the blow-fill-seal process in an integrated process. The containers produced in this way are particularly suitable for liquid filling goods with a volume of approximately 0.2 ml or more. Particularly patient-friendly, they can be formed with a closure that can be removed by twisting or kinking. The opening thereby created, through which the liquid content can be removed, can be designed in such a way that it fits onto a Luer connection or Luer lock connection. For example, the opening can be round and have a diameter that largely corresponds to the outside diameter of a male Luer connector. In this way, a conventional syringe with a Luer connection could be connected to the container in a coherent manner, for example around the contents of the container and transfer to a nebulizer, or to mix the contents of the container with the contents of the syringe and then add them to a nebulizer. As a further alternative, it can be provided that the plastic container is designed in such a way that after removal of the closure element, it can be largely conclusively connected to a connector provided for the supply of liquid of a correspondingly adapted nebulizer, which enables the preparation to be filled directly into the reservoir of the inhaler is.

Plastic containers of this type are also advantageous because they can be easily embossed. On the one hand, this means that paper labels can be dispensed with, which is desirable in order to avoid the migration of constituents of the adhesive, the paper or the printing ink through the container wall into the preparation. On the other hand, important information can also be made accessible to visually impaired patients through such an imprint. The embossing can contain various information, e.g. B. a batch name, an expiry date, a product name, instructions for use, or one or more volume or dose brands. Particularly for pediatric patients, for whom flexible dosing according to age or height is often desirable, a plurality of volume marks can be used to facilitate the removal of the desired dose without further aids, which can reduce the risk of dosing errors.

To increase the storage stability, it may be advantageous to subject the preparations according to the invention described above to freeze drying in order to store them in the solid state. The liquid form required for atomization can be restored from it shortly before use by mixing with sterile water. According to the invention there is therefore also provided a solid composition which can be obtained by freeze-drying the preparations according to the invention described above. The methods of freeze drying are known per se to those skilled in the art.

Examples

The following exemplary embodiments serve to illustrate the invention; however, they are not to be understood as exclusive design variants. Example 1: Solubilization of budesonide with tyloxapol and DMPC

Buffered aqueous solutions of Tyloxapol, DMPC, and Tyloxapol mixed with DMPC were prepared. In these, the saturation solubility of budesonide was measured by adding an excess of budesonide and treating the respective batch with heat and ultrasound and then allowing it to stand for equilibration. The equilibrated batches were filtered through a membrane filter with a pore size of 0.22 μm and the budesonide content in the filtrate was determined. Selected results from these experiments are shown in Table 1. The saturation concentration of budesonide in DMPC solution could also not be increased by a further increase in the DMPC content.

Table 1

Tyloxapol [wt%] DMPC [wt%] budesonide [μg / ml] 0 1 20 1, 5 0 204 1 0.5 268

Example 2: Preparation of a sterile, colloidal solution of budesonide

Budesonide is an example of a poorly water-soluble active ingredient which can advantageously be formulated as a colloidal aqueous solution by the combination of surfactants according to the invention.

The starting materials designated in Table 2 were provided in the amounts indicated. In the water for injection purposes, the specified starting materials apart from budesonide were first dissolved or dispersed by stirring with a magnetic stirrer. The mixture was then homogenized with a high-pressure homogenizer over 10 min at 1500 bar. This gave an opalescent, colloidal solution with a pH of about 4.5.

200 mg of budesonide previously provided were added to this solution. This approach was heated to about 60-70 ° C and sonicated for about 30 minutes. The mixture was then cooled to room temperature with stirring using a magnetic stirrer. Evaporated water was replaced with an appropriate amount of water for injections. An opalescent, colloidal solution was thus obtained. This was subsequently manually sterile filtered under a laminar flow box with sterile devices through a membrane filter with a pore size of 0.22 μm and filled into provided sterile glass vials. The vials were sealed germ-tight, stored at different temperature conditions and checked for decomposition products and physical parameters at different time intervals.

Table 2

The characterization of the filled preparation showed a budesonide content of 202.34 μg / ml, a surface tension of 38.8 mN / m, a dynamic viscosity of 1.07 mPas, an osmolality of 0.282 osmol / kg and a pH value of 4. 25 at 21.8 ° C. The mean size of the colloidal particles, measured by photon correlation spectroscopy at an angle of 90 °, was 13.1 nm (expressed as z-average) and indicates micellar structures.

The advantages of such a colloidal solution of the active ingredient budesonide become particularly clear when compared with the commercial product Pulmicort ^® Suspension, which has an average particle size of approximately 4 μm. In contrast to the suspension, the colloidal solution shows typical behavior and can be nebulized far better. The advantages and advantages of the colloidal budesonide solution according to the invention are particularly evident in the treatment of asthma and chronic obstructive bronchitis in children and infants.

Figure 1 shows a significantly improved lung deposition for the colloidal budesonide solution (here referred to as "BUDeFlow ™") in vitro using an airway replica of a 9-month-old baby (Sophia Anatomical Infant Nose Throat = SAINT model) and less undesirable nasal or oropharyngeal deposition than the Pulmcort ^® suspension ("Pulmicort"), as can be seen from the percentage ratio of the lung dose to the "guest deposition". Two different nebulizers were used in these investigations, namely the nozzle nebulizer PARI LC PLUS ^® and the piezoelectric nebulizer PARI eFlow ™ baby. The legend also shows the active ingredient doses used for the nebulization. Percentage deposition information can be found in Table 3. In-vivo examinations with radiolabelled budesonide confirmed the better deposition of the colloidal budesonide solution according to the invention compared to the suspension.

Table 3

The colloidal solution obtained can also be in the form of a preservative-free nasal spray or with other application devices, such as, for example, a nozzle nebulizer working with a pulsating compressor, such as, for. B. the PARI SINUS ™, are used therapeutically and also for nasal treatment of sinus and / or sinus infections or allergic rhinitis.

Example 3: Preparation of a budesonide formulation for nasal use 3.75 g of tyloxapol were weighed into a 1000 ml beaker. For this purpose, 486.0 g of water were added for injection purposes and the mixture was stirred at room temperature (20 ° C. stirred) until the tyloxapole had completely dissolved. 4.23 g of sodium chloride, 0.2 g of citric acid and 0.25 g of sodium citrate were added to the resulting solution. After all components had dissolved, the pH of the solution was adjusted to 4.3 by adding sodium citrate. 7.5 g of Lipoid PC 14:14 (dimyristoylphosphatidylcholine) were added to the solution and homogenized using an Ultra-Turrax at 11,000 rpm (5 minutes). The formulation was then homogenized by means of high pressure homogenization (Microfluidies M100EH) at 1500 bar for 20 minutes. The resulting solution showed slight opalescence, which almost disappeared after 12 hours on a magnetic stirrer.

After adding 400μg / ml budesonide, the formulation was homogenized again (Ultra Turrax followed by high pressure homogenization). After standing for a further 12 hours on a magnetic stirrer, the now slightly opalescent preparation could be sterile filtered through a 0.22μm membrane filter under aseptic conditions and placed in pump atomizer bottles (100μl / Stroke).

The finished budesonide-containing formulation showed the following physicochemical properties: pH value of 4.3 at 22.7 ° C, a dynamic viscosity of 1.16 mPas, a surface tension of 40.6 mN / m and an osmolality of 0.262 osmol / kg.

Example 4: Preparation of a sterile solution of tobramycin

Tobramycin is an example of a bad taste ingredient that can cause cough and bronchoconstriction.

An opalescent, colloidal solution of 0.45 g of DMPC, 0.91 g of tyloxapol, 0.225 g of sodium chloride in 89.59 g of water for injections was prepared from the amounts provided. The procedure was analogous to Example 2, ie the batch was first homogenized at high pressure without the active ingredient at 1500 bar. 5.41 g of 96% sulfuric acid and 10.88 g of tobramycin were added to this solution. Initially, precipitation occurred. The mixture was then stirred for 24 hours at room temperature with a magnetic stirrer, as a result of which a clear, possibly colloidal solution was formed which was sterile filtered and filled as described in Example 2. _ The characterization of the filled preparation showed a pH value of 6.23 at 21.8 ° C, a dynamic viscosity of 2.07 mPas, a surface tension of 36.5 mN / m and an osmolality of 0.229 osmol / kg.

Example 5: Preparation of a sterile solution of lidocaine 0.55% (w / v) lidocaine base was incorporated into a solution of the components listed in Table 2 (without budesonide). After sterile filtration, the colloidal solution was filled into pre-sterilized single-dose containers (0.5-3 ml) made of glass and polypropylene. Inhalation experiments showed that the undesirable local anesthetic effect of lidocaine was reduced. Example 6: Preparation of a sterile solution of cyclosporin

This example describes the possibility of solubilizing the water-insoluble immunomodulator cyclosporin according to the invention.

The starting materials identified in Table 4 were provided in the amounts indicated. Cyclosporin is first suspended or dissolved in propylene glycol. This mixture is mixed with aqueous buffer solution, which contains the amounts of tyloxapol, DMPC and NaCl mentioned in Table 4, and made up to 100 ml with water for injections. High pressure homogenization, as described above, creates a colloidal solution, which after sterile filtration through a 0.22 μm filter is filled into pre-sterilized 0.5 - 3 ml single-dose containers made of glass or polypropylene. The cyclosporin content of the formulation obtained is 570 μg / ml.

Table 4

The mean particle size (z-average) of this colloidal dispersion determined by photocorrelation spectroscopy is 9.7 nm.

Example 7: Production of combination products

Combinations of steroids, such as B. budesonide with water-insoluble or water-soluble substances from the group of betamimetics (such as salbutamol, formoterol) and / or anticholinergics (such as ipratropium, thiotropium) are therapeutically preferred due to a synergistic effect and improved patient compliance. Formoterol (20 μ / ml) was incorporated in a first batch and ipratropium bromide (100 μg / ml) in a colloidal budesonide solution (200 μg / ml) prepared according to Example 2. The resulting colloidal solutions were sterile filtered and filled into pre-sterilized 0.5 - 5 ml single dose containers made of glass or polypropylene.

Example 8: Preparation of a freeze-dried combination product with vitamin E acetate and reduced glutation

Antioxidants such as B. reduced glutathione and tocopherols (vitamin E derivatives) can reduce inflammation processes induced by radical oxygen. The following example illustrates the possibility of solubilizing the water-insoluble tocopherol acetate with the water-soluble but storage-unstable glutanate with the aid of the surfactant combination according to the invention and stabilizing it by a subsequent freeze-drying process. , 2 g of Tyloxapol, 2 g of DMPC, and 20 mg of tocopherol acetate are mixed in 200 ml of water for injection and pre-homogenized with an Ultra-Turrax. The dispersion is homogenized in a high-pressure homogenizer at 1500 bar for about 15 minutes. 2.5 g of reduced glutation are quickly dissolved in 50 ml of the resulting colloidal solution with stirring and a pH of 6 is established by adding lysine monohydrate. The resulting colloidal glutation vitamin E acetate solution is immediately sterile filtered in glass vials and then freeze-dried. The osmolality of the resulting solution was 0.342 osmol / kg.

After adding water for injection, the lyophilisate dissolves completely within 10 seconds with shaking.

Claims

P A T E N T A N S P R Ü C H E

1. Sterile aqueous preparation for application as an aerosol, characterized in that it contains an active ingredient, a nonionic surfactant and a phospholipid, the active ingredient being no surfactant.

2. Preparation according to claim 1, characterized in that it is a single-phase liquid system which optionally contains colloidal particles with an average particle size of not more than about 1 micron and preferably of not more than about 0.2 microns.

3. Preparation according to one of the preceding claims, characterized in that the nonionic surfactant is tyloxapol.

4. Preparation according to one of the preceding claims, characterized in that the phospholipid is a zwitterionic and / or saturated compound, or a mixture of such compounds, and preferably from the group consisting of lecithin, dimyristoylphosphatidylcholine (DMPC), dipalmitoylphosphatidylcholine (DPPC) or distearoylphosphatidylcholine ( DSPC) is selected.

5. Preparation according to one of the preceding claims, characterized in that the weight ratio between the content of nonionic surfactant and the content of phospholipid is between about 5: 1 and about 1: 2.

6. Preparation according to one of the preceding claims, characterized in that it contains at least one further surfactant or a cosolvent such. B. contains propylene glycol.

7. Preparation according to one of the preceding claims, characterized in that it has a surfactant content of about 0.01 to about 5.0 wt .-%.

8. Preparation according to one of the preceding claims, characterized in that the weight ratio between the total content of surfactant and phospholipid on the one hand and the active ingredient content on the other hand is at least about 1: 1, and preferably at least about 5: 1.

9. Preparation according to one of the preceding claims, characterized in that it has a surface tension of about 30 to about 75 mN / m.

10. Preparation according to one of the preceding claims, characterized in that it has a dynamic viscosity of about 1.0 to about 3.0 mPas, preferably from about 1.0 to about 2.5 mPas.

11. Preparation according to one of the preceding claims, characterized in that it has a pH of about 4 to about 8, preferably from about 4.5 to about 7.5.

12. Preparation according to one of the preceding claims, characterized in that it has an osmolality of about 200 to about 550 mOsmol / kg.

13. Preparation according to one of the preceding claims, characterized in that it contains an antioxidant, which is preferably vitamin E acetate, sodium EDTA or a mixture thereof.

14. Preparation according to one of the preceding claims, characterized in that it is free of propylene glycol, glycerol, and polyethylene glycol.

15. Preparation according to one of the preceding claims, characterized in that the active ingredient is a poorly water-soluble active ingredient.

16. Preparation according to claim 15, characterized in that the content of the sparingly water-soluble active ingredient is between approximately 0.001% by weight and approximately 1% by weight.

17. Preparation according to claim 15 or 16, characterized in that the active ingredient is budesonide.

18. Preparation according to claim 17, characterized in that budesonide is present in colloidally dissolved form with a content of about 0.15 to 0.35 mg / ml.

19. Preparation according to one of the preceding claims, characterized in that the active substance has an unpleasant taste and / or mucous membrane irritant, bronchoconstrictive and / or cough-inducing properties.

20. Preparation according to one of the preceding claims, characterized in that the active ingredient is selected from the group consisting of corticosteroids, beta sympathomimetics, anticholinergics, immunomodulators, anti-infectives, cytostatics, local anesthetics and ACE inhibitors.

21. Preparation according to one of the preceding claims, characterized in that the active ingredient is selected from the group consisting of budesonide, ciclesonide, fluticasone, mometasone, beclomethasone, flunisolide; Formoterol, salmeterol, levalbuterol; Thiotropium, oxitropium, ipratropium; Ciclosporin, tacrolimus, methotrexate, azathioprine, tretinoin; Ciprofloxacin, moxifloxacin, azithromycin, clarithromycin, erythromycin, metronidazole, ketoconazole, itraconazole, clotrimazole, bifonazole, fluconazole, amphotericin B, natamycin, nystatin, pentoxyifylline, acicloviravin, acicloviravin, acicloviravin, acicloviravin , Lomustine, taxol, etopside, cisplatin, lidocaine, gluthation; Acetylcysteine, N-acetylcysteine, reduced glutathione and TNF-alpha antibodies as well as the pharmaceutically acceptable derivatives, such as. B. the salts, conjugates, enantiomers, racemates, epimers, diastereomers or complexes of these substances.

22. Preparation according to one of the preceding claims, characterized in that it contains more than one active ingredient.

23. Preparation according to one of the preceding claims, characterized in that it is suitable for administration for therapeutic, prophylactic or diagnostic purposes.

24. Preparation according to one of the preceding claims, characterized in that it is suitable for administration for local therapy of the mucous membrane of the upper or lower respiratory tract or for systemic therapy.

25. Solid composition obtainable by freeze-drying a preparation according to one of the preceding claims.

26. Preparation according to one of claims 1 to 24 or a solid composition according to claim 25, characterized in that it is in the form of a measured single dose within a primary packaging.

27. Preparation according to claim 26, characterized in that the primary packaging is formed by a plastic container which comprises a removable closure element.

28. Preparation according to claim 27, characterized in that the removal of the closure element creates a round opening in the plastic container, the diameter of which corresponds approximately to the inside diameter of a female Luer connector. _^ 29. A preparation according to claim 27 or 28, characterized in that the plastic container, after removal of the closure element is substantially positively connected with an intended for the supply of fluid connector of a nebuliser. 30. Preparation according to one of claims 27 to 29, characterized in that the plastic container is provided with at least one embossing, which represents a product name, a batch code, a best before date and / or a volume or dose brand.

31. Use of a preparation according to one of claims 1 to 24 or a composition according to claim 25 for the preparation of a diagnostic, therapeutic or prophylactic medicament.

32. Use according to claim 31, wherein the medicament is intended for the prophylaxis and / or treatment of one or more diseases, symptoms or conditions relating to the lungs or bronchi, e.g. B. Bronchial asthma or chronic obstructive bronchitis.

33. Use according to claim 32, wherein the medicament for nebulization with the aid of a nebulizer of the ultrasonic, jet, electrohydrodynamic and / or with a vibrating membrane or with pores of defined size nebulizer (eg eFlow ™, eFlow ™) Baby, AeroNeb ™, AeroDose ™ or AERx ™). 34. Use according to claim 31, wherein the medicament is intended for the prophylaxis and / or treatment of one or more diseases, symptoms or conditions relating to the mucous membrane of the nasal and / or oral cavity, e.g. B. stomatitis, aphthae, allergic rhinitis, vasomotor rhinitis, chronic rhinitis, or nasal polyps. 35. Use according to claim 34, wherein the medicament is intended for nebulization using a mechanical atomizer or a nebuliser and for spraying into the nose or mouth or for inhalation.

36. Use according to claim 31, wherein the medicament is intended for the prophylaxis and / or treatment of one or more of the mucous membranes of the forehead, jaws and / or paranasal sinuses, e.g. B. chronic or allergic sinusitis or polyps.

37. Use according to claim 36, wherein the medicament is intended for nebulization with the aid of a nozzle nebuliser and for inhalation through the nose, the nebuliser containing a nosepiece for delivering aerosol into one or both of the nostrils of a patient and an aerosol outflow with pulsating pressure fluctuations generated (e.g. PARI sine).

38. Use according to any one of claims 31 to 37, wherein the medicament is intended for use on infants, young children, children and adolescents.

39. A method for producing a preparation according to one of claims 1 to 24, characterized by the method steps: (a) providing the intended ingredients; (b) production of a liquid, aqueous preparation from the intended ingredients; (c) sterile filtration of the preparation prepared in step (b); and (d) filling the preparation sterilized in step (c) into sterile containers under aseptic conditions.

40. The method according to claim 39, characterized in that at least one of the ingredients provided in method step (a) are sterile.

41. The method according to claim 39 or 40, characterized in that the process step (b) comprises a sub-step of homogenization under increased pressure, ultrasonication and / or heating to at least 45 ° C.

42. The method according to any one of claims 39 to 41, characterized in that it is free of process steps or partial steps in which a poorly soluble, solid substance, which is preferably an active ingredient, is mechanically comminuted.