KR20030096224A - Composition and method for stable injectable liquids - Google Patents

Abstract

A composition for delivering a stable bioactive compound to a subject consisting of a first component and a second component consisting of particulates of sugar glass or phosphate glass containing a bioactive agent. The sugar glass or the phosphate glass optionally comprises a glass formation accelerator compound, and the second component is composed of at least one biocompatible liquid perfluorocarbon in which the first component is insoluble and dispersed. Liquid perfluorocarbons optionally include surfactants.

Description

Compositions and methods for stable injectable liquids

Vaccines or drugs in solutions prepared for injection are inherently unstable and require refrigeration. Traditionally, the pharmaceutical industry has addressed the instability problem by freeze-drying drugs. This is expensive, inconvenient, and inherently dangerous because incorrect reconstitution of the dried drug can lead to incorrect dosages or contaminated solutions. Many attempts have been made over the last 100 years to develop successful, stable, liquid formulations ready for injection. Only small molecule drugs that are inherently hard can survive in aqueous solutions with useful storage periods.

This problem is particularly acute in the vaccine industry. It is estimated that by 2005, 3.6 billion doses of the vaccine will be administered worldwide. It was stated by the World Health Organization (WHO) that it would not be possible to use a standard vaccine format that should be refrigerated at all times ("Revolutionizing Immunizations" Jodar L., Aguado T., Lloyd J. and Lambert PH. Genetic). Engineering News Feb 15 1998). Refrigerator "cold chains" are currently being used, which are expanding from vaccine production to local cities in developing countries. The cost of cold chains for vaccine campaigns by the vaccine industry and non-governmental health organizations is enormous. The WHO only estimates that the cost of maintaining the cold chain is more than $ 200 million annually. Moreover, the vaccination campaign only extends to people closest to the coldest link in the cold chain.

Immunization campaign Requires medically trained personnel to be sure that the dose is injected correctly and does not show any signs of degeneration. The need for reconstitution of some vaccines, such as measles, yellow fever and BCG in the field, is also an important concern. This must be done precisely to ensure correct dosing, which also introduces potential contaminants and often results in clinical disasters. Moreover, it is necessary to provide one or more vaccines in a combination injection session because certain mixtures or "multiple" vaccines are not useful due to the chemical incompatibility of some components, which requires multiple injections. WHO highlighted these issues by actively encouraging the study of next-generation vaccines that do not require refrigeration and do not require reconstitution ("Pre-Filled Monodose Injection Devices: A safety standard for new vaccines, or a revolution in the delivery of immunization? "Publication of Lloyd J. and Aguado MT WHO May 1998;" General policy issues: injectable solid vaccines: a role in future immunization? "Publication Aguado MT, Jodar L., Lloyd J., Lamber PH WHO Publication No. A59781 ).

An ideal solution to this problem would be a completely stable, scan-ready formulation. Such stable vaccines may be packaged in individual dosages within the injection device itself or may be aboard a large volume for mass Yeva injection campaigns and administered by a needle-free jet syringe. Dry solid transdermal delivery by gas jet injection has been described (Sarphie DF, Burkoth TL. Method for providing dense particle compositions for use in transdermal particle delivery. PCT Publication WO 9748485 (1996)). Vaccination is clearly very effective ("PowderJect's Hepatitis B DNA Vaccine First to Successfully Elicit Protective Immune Response In Humans" at http://www.powderject.com/pressreleases.htm (1998)).

The hypersonic shock waves of helium gas used to adjust such powder syringes have a limited powder and cannot carry a dose of fine particles into the muscle. This is because low-mass particles are unable to achieve a driving force that is suitable for deep penetration. Intradermal delivery of DNA vaccines coated with colloidal gold particles is suitable for good immunogens while conventional vaccines adjuvanted with insoluble aluminum or calcium salts induce skin inflammation. They must be provided intramuscularly. What is needed is a flexible system capable of delivering a depth range from intradermal to deep muscles, similar to that achieved by existing needle and syringe technology. For large-scale vaccination campaigns, this is addressed by the development of a liquid jet syringe that allows a narrow (~ 0.15 mm diameter) stream to accelerate the liquid into a "liquid nail" using a pressure of about 3,000 psi. It became. Such a device delivers doses through the skin painlessly into deep subcutaneous or muscle tissue by puncturing micropores through the epithelium. The high propulsion imparted to the liquid stream ensures deep penetration. Drugs and vaccines injected to date have been water-based, but the range of stable aqueous products that are readily accessible to these techniques is very limited because of the instability issues discussed above.

It has been recognized that a wide range of bioactive molecules are stabilized by drying in sugar glass (Roser B. "Production of proteins and the like" UK Patent No. 2,187,191. Roser B. and Colaco C. "Stabilization of biological macromolecular substance and other organic compounds "PCT publication WO 91/18901. Roser B and Sen S." New stabilizing glasses ". PCT patent application no. 9805699.7 1998). These dried and stabilized actives are not suitable for adverse environments such as high temperature and ionizing radiation. Not affected by

The fundamental stabilizing mechanism of molecules by sugars is the free-conversion. When the sugar solution containing the active molecule reaches the solubility limit of the sugar when it is dried, it may become a crystallized or supersaturated syrup. The ability of sugars to resist crystallization is an important property as good stabilizers. Trehalose is good in this respect (Gree JL. & Angel CA. Phase relations and vitrification in saccharide water solutions and the trehalose anomaly J. Phys. Chem. 93: 2880-2882 (1989)). Further drying of the gradually solidified syrup turns to glass at low residual moisture content. Slightly the active molecules change from a liquid solution in water to a solid solution in dry sugar glass. The chemical dispersion is insignificant in the glass and thus the actual chemical reaction stops. Denaturation cannot occur in glass because it is a chemical change, and the molecules are stabilized. In this form the molecule can remain unchanged, providing another condition. This chemically inert, non-reactive nature is the second important property of good stabilizers. Many glasses fail because they react with the product on storage. The obvious problem arises with reducing sugars and forms a good physical glass, but their aldehyde groups attack the amino groups on the product in a typical Maillard reaction. This is why many freeze-dried pharmaceutical products require refrigerated storage. Non-reactive sugars provide a stable product and require no refrigeration at all.

Biomolecules immobilized in sugar glass are also stable in non-aqueous industrial solvents in which both themselves and sugars are insoluble (Cleland JL and Jones AJS. "Excipient stabilization of polypetides treated with organic solvents" US Pat. No. 5,589,167 (1994). )). Because sugar glass acts as an impermeable barrier in non-solvent liquids, biomolecules in solid solutions in the glass are protected from both the chemical reactivity of the solvent and the environment. The sensitive product in the suspended glass particles by providing a stable liquid itself consists of a stable two phase liquid formulation. Industrial solvents of the kind described by Cleland and Jones (1994) have limited utility in processing. Substituting bio-compatible non-aqueous liquids makes it possible to formulate even the most unstable drug, vaccine and diagnostic stable liquid formulations.

The first generation of stable non-aqueous liquids is designed for use in drug or vaccine delivery (B.J. Roser and S.D. Sen "Stable particle in liquid formulations"). PCT patent application GB98 / 00817 discloses a formulation of stabilized glass powders containing an active substance suspended in an injectable oil such as sesame oil, arachis oil or soybean oil or a simple ester such as ethyl oleate. Is described. Suspended sugar glass particles are strong hydrophilic while oils are hydrophobic. Because of the strong tendency to separate the hydrophilic and hydrophobic phases, the sugar glass particles tend to agglomerate with each other. The use of oil-soluble surfactants dissolved in continuous oils is often required to stabilize such "water in oil" type suspensions.

These low HLB (hydrophilic / lipophilic equilibrium) surfactants accumulate at the interface between the hydrophilic particles and the oil and coat them with an amphiphilic layer that is more compatible with the continuous oil phase. No chemical reaction can occur between the particles because each sugar glass particle is separated from its neighbors by dry oil. It is therefore possible to have some different particle populations, each containing different potential interacting molecules in the same oil group without interaction. Multiple multivalent vaccines can be produced in this way.

However, this approach has been found to have some drawbacks in preventing bulk solution. This involves the inevitable sedimentation of suspended particles having a typical density of about 1.5 g / cm 3 in less concentrated oil vehicles. The patent recognizes this problem and attempts to solve it by reducing the particle size to less than 1 μm in diameter in order to remain suspended by thermodynamic energy such as Brownian motion. The need for all particles to be less than 1 μm in diameter is a disadvantage of the proposed formulation. The achievement of such small particle powders is never an easy task. Enhanced spray dryer designs can achieve this, but small particle sizes prevent the use of cyclone type collectors and require a filtration system for product recovery.

The reduction of particles to sub-micron size in theory is also achieved after the particles are suspended in oil with high-pressure micro-homogenization equipment such as Microfluidizer (Constant Systems Inc.). This involves an extra step in the process and is not very effective at breaking spray-dried sugar glass microspheres with very mechanical strength because of their spherical shape. This indicates a number of passes through the equipment. This tends to leave a lot of large particles which are not in contact and thus require a filtration or settling step to remove them afterwards. Also the high viscosity of the suspension in common oily excipients makes it difficult to pull them up into the syringe and requires slow injection. This impedes rapid flow through the fine nozzles as experienced in liquid jet syringe systems.

It has also been found that particles suspended in oils are difficult to extract into an aqueous environment, especially when they contain low HLB surfactants, because they retain surprisingly tight, water-resistant coatings of oil around them even after washing in aqueous buffers. Therefore, the particles require mixing with strong shaking and the addition of more water-soluble detergents (for high HLB) to leave the oil phase and enter the water phase. This is a further problem that particle size should be reduced. The end result is often a mixed emulsion that is disheveled rather than two cleanly separated phases. This problem in the body can lead to the release of slow and unpredictable activators rather than fast and predictable delivery. In vitro extraction into the aqueous environment results in an oil drifting over the top of the aqueous phase containing the dissolved active agent. It is not acceptable for certain in vitro applications such as diagnostic kits or automated assay systems. As a result, most of the natural FDA-approved oils that can be used clinically are vulnerable to photolysis, oxidation or other forms of damage and require careful storage at relatively low temperatures. Moreover, they are not chemically completely inert and can react slowly with suspended particles.

Alliance Pharmaceutical Company has investigated the use of water-soluble substance powders in a distinct new non-aqueous perfluorocarbon liquid (Kirkland WD Composition and method for delivering active agents. US Pat. No. 5,770,181 (1995)). This patent mainly relates to the function of PFCs as oral contrast enhancers for diagnostic images of the intestines. The water-soluble powders exemplified therein have been added to enhance the taste and strengthening of the contrasting effect in the gastrointestinal tract of PFCs. Kirland, however, recognized that these liquids could be used for drug delivery, although no examples are given. Only particularly stable, stable and commercially available powders are exemplified in this patent. We have found that brittle actives stabilized in sugar glass can be designed to produce extremely stable two-phase PFC liquid formulations for both oral and parenteral delivery. This extends the utility of Kirland patents to parenteral drugs and vaccines in injection-prepared formulations, eliminating the need for any kind of refrigeration. Of particular value is the discovery that the low viscosity, high density and low surface tension of PFCs mean that these stable suspensions can be delivered by automatic devices such as liquid jet syringes. This allows the technology to develop two additional areas of importance: large scale vaccination campaigns and self-injection.

Perfluorocarbons (PFCs) are new and extremely stable liquids produced by the complete fluorination of organic compounds. They cannot be categorized as lipophilic or lipophilic because they can not be substantially mixed with both oil and water other than PFCs or with other solvents that are polar or nonpolar (Reviewed in Kraff MP & Riess JG. "Highly fluorinated amphiphiles and colloidal systems, and their applications in the biomedical field.A contribution. "Biochimie 80: 489-514 1998). Moreover, no hydrophobic interaction with oil or hydrophilic interaction with water or hydrophilic substances precipitates. As a result, turbid phase separation tends not to occur in PFCs, as it appears when hydrophilic particles clump together strongly in oil. They do not require surfactants to produce stable suspensions, but fluorohydrocarbon (FHC) surfactants are useful (Kraff & Riess 1998) and are active at small concentrations in PFC liquids. At these very low concentrations, FHC surfactants can ensure a complete monodisperse system of certain particles that tends to aggregate in their absence. The PFC liquid itself is chemically completely non-reactive, and low molecular weight types do not accumulate in the body but are actually released into the breath if volatile.

PFCs have been used in large amounts for many special clinical applications because they are good solvents as gases. The ability to exchange carbon dioxide with dissolved oxygen is better than hemoglobin. This was first discussed in "bloodless rats" by RP Geyer in 1968 (Geyer RP, Monroe RG & Taylor K. "Survival of rats totally perfused with perfluorocarbon-detergent preparation." In: Organ Perfusion and Preservation , JV Norman, J Folkman , LE Hardison, LE Ridolf and FJ Veith eds.Appleton-Century-Crofts, New York .. 85-95 (1968). Perfluorooctyl bromide, in the form of a PFC-in-water emulsion, trade name of Oxygent ^™ (Alliance Pharmaceutical Corp.), is currently being evaluated in the body as an alternative to blood transfusions for certain surgical procedures. PFCs have also been used for inhalation into the lungs as a liquid for the treatment of respiratory distress syndrome in premature infants.

Their high density associated with chemical inertness is known to be valuable. Perfluorophenan (trade name) Vitreon ^TM (Vitrophage Inc)

threne) is used to prevent the collapse of the eye capsule during surgical procedures and to enable repositioning of the detached retina. PFCs have also been used as contrast media for magnetic resonance imaging (MRI), and hydrophilic powders have been suspended in them for this purpose to enhance their imaging properties or to make them more hobby (Kirkland WD “Composition and method). for delivering active agents. "US Patent No. 5,770,181 1998). The patent also proposes the use of PFCs as a continuous phase for delivering particulate water-soluble drugs. Since many parenteral drugs that are stable as dry powders at room temperature are limited, this patent has no applicability to many injectable drugs. However, the drug stabilization combination of sugar free microsphere powder and injectable PFCs as described in Roser and Garcia de Castro (1998) makes this technique practically applicable to all parenteral drugs and vaccines.

Summary of the Invention

The present invention utilizes a two-phase system with PFC as a continuous phase containing a discontinuous free phase in suspension as a drug delivery aid. Preparations based on perfluorocarbons provide a major advantage in that different PFCs are mixed to obtain a final mixture with a density in the range of about 1.5 to 2.5 g / cm 3. This allows the particles to be formulated to a density that matches the suspension fluid to form a stable suspension without drifting or sinking to the bottom of the container. Thus, the particles do not have to be the submicron sites required in oil based production to prevent sedimentation and vary widely in size. The final particle diameter is determined only by the purpose of manufacture. Preparation for needle injection or jet injection may contain particles in the range of 0.1 to 100 micrometers, preferably in the range of 1 to 10 micrometers. This allows for a lot of simplicity on many particle production methods and avoids the need for excessively small particle size generation by milling. The particles can be prepared by conventional spray drying or freeze-drying by simple dry or wet milling. If a high solids content in the suspension is desired, the particles are preferably spherical in shape. Irregularly shaped particles tend to "bond" with each other much more, thus inhibiting free-flow, while spherical particles have an inherent "lubricity" to allow at least 20% solids to be achieved. Such particles are readily prepared by spray-drying, spray-freezing-drying or emulsion condensation.

Suspended powders do not require any surfactant when properly formulated and produce a stable suspension in which sugar glass particles are dissolved almost immediately when shaken with water. If a small set is recognized as a problem, a small amount of FHC surfactant is added as described in Kraff and Riess (1998) and added into the PFC fluid before or after mixing of the stable powder. Like PFCs, these FHCs are inherently very inert and non-reactive. Thus there is no solvation and no chemical reaction of the particles between the suspended particles of the particles and the PFC phase. Since both sugar glass particles and PFC liquids are environmentally stable, there is no decomposition due to light, high temperature, oxygen, or the like. It is negligible for toxicity in vivo or in vitro and has been extensively tested and approved by regulatory agencies as it is injected into both animals and humans in large volumes for blood replacement purposes. While high molecular weight PFCs have been reported to accumulate in the liver, examples of low molecular weights used in this application are substantially removed from the body with exhaled breath.

Their low surface tension and low viscosity make it very easy to flow through narrow internal diameters encountered in hypodermic needles, automated systems or liquid jet syringes. PFCs are good electrical insulators and are therefore easy to achieve monodisperse suspensions with the same small surface electrostatic charge. These are dry and completely non-hygroscopic liquids. Their very low moisture content maintains the dryness of suspended powders to prevent separation and / or degradation of the integrated actives. Their unique solvent free nature makes them ideal for suspending hydrophilic or hydrophobic particles, meaning that the final suspension is substantially compatible with any material used in the container or delivery device. This is in contrast to oil-based preparations, which can cause excessive propagation of the syringe, for example by inflating the rubber seal on the plunger. PFCs can be obtained with density, vapor pressure and volatility in the range (Table 1). Their high densities allow them to settle in most conventional buffers, allowing for easy separation from product particles dissolved in the normal drifting aqueous phase. Thus their use in in vitro applications such as diagnostics Promote

The present invention relates to a subject comprising a first component consisting of microparticles of sugar glass or phosphate glass containing a bioactive agent and a second component consisting of at least one biocompatible liquid perfluorocarbon in which the first component is insoluble and dispersed. A composition for delivering a bioactive compound that is stable to

Alkaline phosphatase (Sigma Aldrich Ltd.) was stabilized in a glass consisting of mannitol 33.3%, calcium lactate 33.3% and degenerated gelatin 33.3% (Byco C, Croda Colloids Ltd.), spray dried as microspheres, It was stored at 55 ° C. as a stable suspension in dry powder or perfluorodecalin. Activity remained around the 100% mark (103% at 20d, 94% at 30d). There was more loss in dry powder not suspended in PFC (around 80% of remaining activity).

Figure 2. A commercial tetanus toxin vaccine (# T022 supplied by Evans Medeva plc) was formulated as a density-matched powder with calcium phosphate added in 20% trehalose solution. This was freeze-dried by spraying with liquid nitrogen using two fluid nozzles and lyophilizing the frozen microsphere powder in a Labconco freeze dryer to an initial storage temperature of -40 ° C throughout the initial drying. Six groups of antibody responses of 10 guinea pigs were measured 4, 8 and 12 weeks after injection with the same dose of reconstituted ASSIST stabilized tetanus toxin vaccine or anhydrous preparation in oil or PFC.

The response to all dried formulations was lower than the fresh vaccine control (not shown), indicating significant loss of immunogenicity in spray drying. As determined by the capture ELISA, the antigenicity of the toxin was not changed by the drying process. This suggested that more work is needed to perfect the preservation of aluminum hydroxide upon drying.

The response of the density-matched STASIS vaccine (group 3) with calcium phosphate was substantially the same as the control vaccine (group 1) and powder in oil vaccine (group 2) reconstituted in aqueous buffer, while non-aqueous Control animals injected with excipients alone (groups 4 and 5) did not show any response.

Properties of PFCs Perfluoro- MW Density (Kg / L) Viscosity (mPas) Surface tension (mN / m) Vapor pressure (mbar) Hexane 338 1.682 0.656 11.1 294 -n-octane 438 1.75 1.27 16.98 52 Decalin 462 1.917 5.10 17.6 8.8 Phenanthrene 624 2.03 28.4 19 <1

The use of PFCs as excipients for the delivery of pharmaceutical and bioactive agents was first proposed in Kirkland (1995). This patent only exemplifies inherently stable commercially available seasonings or boiling powders and the like. It does not include examples of any stabilized bioactive agent, such as a vaccine or medicament. Moreover, the use of PFCs as suspension excipients for active particles did not take into account the possibility of preparing injectable (parenteral) preparations. In order to achieve a stable formulation of inherently brittle biomolecules with a long shelf life using PFCs as non-aqueous excipients, glass-forming agents preferably capable of formulating particles to stabilize the integrated activator It will contain. This can be a variety of sugars, including trehalose, lactitol, palatinit, etc., as described in PCT WO 91/18091, or more preferably other more effective as described in British Patent Application No. 9820689.9. From monosaccharide sugar alcohols or glass forming agents.

It is advantageous to incorporate a density-controlling agent in the particles to prevent the particles from drifting in the dense PFC phase. It is a soluble salt such as chloride or sodium sulfate or potassium or more preferably an insoluble substance such as barium sulfate, calcium phosphate, titanium dioxide or aluminum hydroxide. Insoluble, non-toxic substances are preferred because the release of large amounts of ionic salts in the body causes significant local pain and inflammation. In some cases, such as vaccine preparations, insoluble matter becomes part of the active preparation as an adjuvant. The density adjuster is in a solid solution in sugar glass particles or insoluble particulate matter in a suspension in sugar glass. When formulated correctly, the sugar glass particles are nearly dense, buoyant, neutral, drifting or settling, and remain a stable suspension without aggregation.

Since PFC liquids with typical resistivity of 10 ¹³ ohm cm or more are good electrical insulators, small surface charges on suspended particles can have a significant effect on suspension stability. In order to prevent suspended particles from aggregation due to weak short-range forces, they are preferably prepared to contain additives such as lysine or aspartic acid which are capable of providing a weak residual electrostatic charge to the dry particles. This prevents aggregation by securing the charge repulsion of the particles, similar to those seen in stable colloids. A small amount of FHC surfactant, such as perfluorodecanoic acid, is also advantageously dissolved and dispersed into the PFCs, preferably providing a monodisperse suspension.

These particles are prepared by many methods of air, spraying or freeze-drying, and are not particularly small but result in a release mixture of sizes ranging between 0.1 μm and 100 μm in diameter. Millimeter-sized particles are also suitable for some applications.

The use of these stable suspensions is not limited to the parenteral use illustrated above, as well as the oral use illustrated by Kirkland (1995). Because PFC liquid excipients are non-toxic and non-reactive, they are ideal excipients for mucous membranes including intrapulmonary, intranasal, intraocular, rectal and vaginal delivery. The ability to produce stable sterile and non-irritating formulations for mucosal delivery, even the highly unstable drugs or vaccines provided in this patent, is a significant advance. In addition, the very dry and completely non-hygroscopic nature of PFC liquids greatly assists in maintaining the sterility of these preparations during extended storage, and the hepatic use as microorganisms cannot grow in the absence of water.

Since volatile perfluorofluorocarbons and chloroflurocarbons have long been used as propellants in inhalers designed to achieve drug delivery to deep lungs, the stable PFC formulations described herein provide a liquid STASIS drawlet for intrapulmonary delivery. Ideal for creating fine mists of droplets. For this application the size of the particles making up the discontinuous suspended particles in the PFC drawlet is important and should not exceed 1-5 μm in diameter, preferably 0.1-1 μm. Particle size is less important for delivery to mucosal surfaces in other noses or eyes, and diameters of 100 μm or even several mm are possible.

Example 1 Spray-Dried Particles in PFCs

Particles using sugars and other additives were produced by spray drying from an aqueous solution using a Labplant model SD 1 spray dryer. A typical formulation is:

A. within water

Mannitol 15% w / v

Calcium Lactate15% w / v

B. within water

Trehalose 15% w / v

Calcium Phosphate 15% w / v

It was created using two fluid nozzles with liquid holes of 0.5 mm inner diameter. Half-maximum nozzle airflow was found in an optimal drying chamber operated at an inlet temperature of 135 ° C and an outlet temperature of 70-75 ° C. The particles were collected in a glass cyclone and secondary dried in a vacuum oven using a temperature ramp at 80 ° C. for 4 hours. Upon cooling they were suspended in PFC using ultrasound. A 30 second burst of ultrasonic energy from the titanium probe in the MSE MK 2 ultrasonic cabinet operating at about 75% power or immersion in a Decon FS200 frequency sweep ultrasonic bath up to 10 minutes was shown to be sufficient.

The resulting suspension was monodisperse and consisted of spherical glass particles ranging in size from 0.5 to 30 microns, averaged 10 microns when examined under a microscope. The mannitol / calcium sulfate particles rose to the top of the PFC layer after a few minutes but could be easily resuspended by gentle shaking. Trehalose / calcium phosphate particles nearly matched the density of PFC and formed a stable suspension.

Spray dried powders of sugar glass particles were suspended in perfluorohexane, felfluorodecalin and polyfluorophenanthrene at 10, 20 and 40% w / v. These have been found to provide monodisperse suspensions with low tendency to aggregate. The addition of 0.1% perfluorodecanoic acid to PFC suppressed the tendency of weak aggregation on the surface. These suspensions were found to pass easily through the 25 g needle by aspiration or eruption.

Example 2 Stability of Suspension of Free Stabilized Enzyme in PFC

Alkaline phosphatase (Sigma Aldrich Ltd.) was spray dried on a Labplant machine as above. The formulation contained 33.3% mannitol, 33.3% calcium phosphate and 33.3% degenerated gelatin (Byco C, Croda colloids Ltd.). The dried enzyme was stored at 55 ° C. as a suspension in dry powder or perfluorodecalin. Enzymes formulated in these microspheres consisting of mannitol-based glass suspended in perfluorofluoroline exhibit near 100% enzymatic activity at 55 ° C. for at least 30 days (FIG. 1).

Example 3 Efficiency in vivo

A preliminary clinical trial of a similar formulation containing a clinical tetanus toxin vaccine (supplied by Medeva plc) was undertaken in collaboration with the National Institute of Biological Standard and Control. The results from this trial showed that a stable STASIS formulation was completely identical to a water-based liquid vaccine in its ability to immunize guinea pigs to develop protective serum antibody responses (FIG. 2). This confirmed that the suspension in PFC consisted of an injection-prepared formulation with the same bioavailability in vivo as a conventional water-based liquid formulation.

Example 4 Spray-Freeze-Dried Particles

The particles were prepared by spraying the liquid droplet with liquid nitrogen and vacuum-drying the frozen powder. These particles were less concentrated than spray dried powders and formed pastes in PFCs at concentrations of 20% w / v or higher. At lower concentrations they formed a monodisperse suspension after sonication.

The general formulation used is

matter Final concentration w / w

A. Trehalose 100%

B. Trehalose 50%

Calcium Phosphate 49.5%

Aluminum hydroxide 0.5%

Example 5 Milled Hydrophobic Particles

The hydrophobic sugar derivatives octaacetic acid sucrose and octaacetic acid trehalose form a glass when cooled from dissolved or rapidly dried from chloroform or dichloromethane solution. Their use is described as a controlled release matrix for drug delivery (Roser et al "Solid delivery systems for controlled release of molecules incorporated therein and methods of making same" PCT publication WO 96/03978 1994).

Octaacetic trehalose powder was prepared by dissolving in an indirect muffle furnace and cooling the melt on stainless steel plates. The resulting glass disks went to the mortar and pestle and produced fine powder in a high-speed grinding homogenizer. It was suspended at 1 and 10% w / v in perfluorohexane, perfluorodecalin and perfluorophenanthrene. This turned out to be a well dispersed suspension. These suspensions appeared to pass easily through the 23 g needle.

Example 6 Reconstitution in an Aqueous Environment

Due to the nature of the soluble sugar glass particles and the nature of the PFCs, the activators in these suspensions were expected to be released rapidly in the body. To demonstrate complete release of the active substance, the particles are:

Trehalose 20% w / v

Calcium Lactate20% w / v

Lysine0.5% w / v

Modant Blue 9 dye 1% w / v

It was formulated to contain.

The formulation was spray dried as above and added into perfluorophenanthrene and perfluorodecalin to yield a 20% w / v dark blue opaque suspension. After adding and shaking water to the same volume of the suspension, all of the blue dye was released into the water phase which formed a clear blue layer drifting on a nearly colorless PFC with a clean interface between them.

Example 7 Non-Reactivity Between Particles in Suspension

Since the individual microspheres in the PFC suspension are physically separated from all other particles, potentially reactive materials can coexist in the same suspension in the individual particles without the risk of any interaction between them. The reaction occurs when the sugar glass is dissolved and the molecules can come together.

To demonstrate this, the suspension was prepared to contain two types of particles: (a) with an alkaline phosphatase enzyme, and (b) with paranitrophenyl phosphate, a colorless substance.

The formulation is:

a) in 5 mM Tris / HCl buffer pH 7.6

Trehalose 10% w / v

Sodium sulfate 10% w / v

Alkaline phosphatase 20 U / ml

b) Zn ⁺⁺ and a 1mM chloride 100mM glycine buffer pH 10.2 in a composition containing a chloride of Mg ⁺⁺

Trehalose 10% w / v

Sodium sulfate 10% w / v

Paranitrophenyl phosphate0.44% w / v

The powder suspension in perfluorodecalin containing 10% w / v of powder "a" and 10% w / v of powder "b" does not show any color reaction and remains as a white suspension for 3 weeks at 37 ° C. appear.

After addition of water and shaking, the powder was dissolved in the covered water phase. The enzymatic reaction occurred within a few minutes and showed dark yellow p-nitrophenol in both the freshly prepared sample and the sample stored at 37 ° C. for 3 weeks.

(Example 8) Product Release in "Tissue Space" Model

To demonstrate the possible behavior of the PFC suspension when injected in vivo, a model, a transparent hydrated tissue space was prepared by casting 0.2% agarose gel in a polystyrene bijoux bottle. 0.1 ml of perfluorodecalin suspension from Example 5 was injected into the agarose gel through a 25 g needle. This produced a flattened white sphere of suspension. After 5-10 minutes white was removed from the bottom of the upper sphere leaving a clear sphere behind the PFC. When the enzyme and substrate were released by the dissolution of the glass particles, they reacted with each other to produce a yellow color of p-nitrophenol and after 1 hour dispersed throughout the agarose.

(Example 9)

Density matching

Sugar glass particles (ie trehalose) obtained by conventional drying methods have a density in the range of about 1.5 g / cm 3 (Table 1). For this reason, sugar glass particles tend to drift on the PFC layer when formulated into a suspension, so that the actives are not homogeneously distributed. However, the powder is modified to produce a stable suspension in PFC that is neutral buoyant and neither settles nor drifts. This is accomplished through the addition of high-density materials prior to particle formation. They are water soluble or insoluble.

Water-insoluble material

Tircalcium orthophosphate has a density of 3.14 g / cm 3 and is approved as an adjuvant and is substantially insoluble in water. Powders prepared to contain about 50% calcium phosphate exhibit an increased about 2 g / cm 3 density and a solid form of 20% stable suspension in perfluorophenanthrene.

Examples of powders that form a stable suspension in PFC at 20% solids are:

One In perfluorodecalin

temperament Final concentration w / w

A. Trehalose 50%

Calcium Phosphate 50%

B. trehalose 47.5%

Calcium Lactate10.0%

Calcium Phosphate 42.5%

2 In Perfluorophenanthrene

temperament Final concentration w / w

Mannitol18.2%

Inositol18.2%

Calcium Lactate18.2%

Calcium Phosphate18.2%

It includes.

Other density increasing non-water soluble materials used include barium sulfate and titanium dioxide. Any non-toxic and insoluble material of suitable density may be used.

Water-soluble substance

Soluble salts such as sodium sulfate at a density of 2.7 g / cm 3 are used as the density-increasing agent. The following powder formed a stable suspension in perfluorodecalin:

temperament Final concentration w / w

Trehalose 50%

Sodium sulfate 50%

Other non-toxic high-density water soluble materials may also be used. These formulations have been found to cause discomfort after subcutaneous injection in guinea pigs due to the rapid dissolution of ionic salts.

Example 10 Effect of Density Matching on Active Agents in Suspension

Certain vaccines are formulated to be adsorbed onto insoluble gels or particles that act as adjuvants. Aluminum hydroxide and calcium phosphate are widely used for this purpose. These insoluble adjuvants are themselves used to increase the density of suspended particles. It is necessary to prove that such adsorption does not denature the active. To test this alkaline phosphatase was used as model activator / vaccine.

The following solutions were prepared.

Within 5 mM Tris HCl buffer pH 7.6

Supplement Grade Calcium Phosphate 10% w / v (Superphos Kemi a / s)

Trehalose 10% w / v

ZnCl ₂ 1 mM

MgCl ₂ 1 mM

Alkaline phosphatase 20 U / ml

The solution was well mixed at 37 ° C. for 10 minutes before the alkaline phosphatase was adsorbed by calcium phosphate. This change in adsorption per minute was measured by centrifuging the calcium phosphate, taking the supernatant and measuring the enzyme kinetics with p-nitrophenyl phosphate as the substrate at a wavelength of 405 nm. The solution was spray-dried to produce a fine powder. Desorption of enzymes after rehydration of the powder was measured in the supernatant as above. The powder was suspended at 20% w / v in perfluorophenanthrene and appeared to produce a stable suspension.

Tested sample d ^Absorbance Per minute (405 nm)

Stock solution (25 μl)

Supernatant from above (25 μl) 0.034

Rehydrated powder (25 μl of 20% w / v in water) 0.425

Supernatant from above (25 μl) 0.004

20% w / v powder (25 μl) in perfluorodecalin 0.430

The experiment is:

The density of the particles is matched with the PFC excipients by the inclusion of the auxiliary calcium phosphate.

No significant desorption or loss of enzyme occurs during the formulation process

Prove that.

(Example 11)

As in Example 1, the STASIS formulation of mannitol based glass was suspended in perfluorodecalin and was surgically clean commonly used to clinically deliver an oxymetazoline nasal decongestant (Sudafed, Warner Lambert). And loaded into a pump-operated polypropylene nebulizer. Two sprays of suspension were delivered into the human volunteer's nostrils, instructed to account for the degree of unpleasant experience. The volunteer reported no discomfort. There were no noticeable side effects of administration.

Claims (18)

Consisting of a first component and a second component, said first component optionally comprising a glass formation promoter compound and composed of particulates of sugar glass, metal carboxylated glass or phosphoric acid glass containing a bioactive agent and Wherein the second component is a composition that delivers a stable bioactive compound, wherein the first component is composed of at least one biocompatible liquid perfluorocarbon that is insoluble and dispersed and optionally comprises an interfacial stabilizer. The sugar or octaacetic acid sucrose selected from the group consisting of trehalose, sucrose, raffinose, stachiose, glucopyranosylsorbitol, glucopyranosylmannitol, palatinate, lactitol, monosaccharide alcohol. Or from a sugar molecule modified by the addition of a hydrophobic side chain selected from the group consisting of octaacetate trehalose. The composition of claim 1, wherein the phosphate glass or carboxylated glass is produced from a mixture of divalent metal or carboxylated metal. The composition of claim 1, wherein said selective glass forming promoter is selected from the group consisting of peptides, proteins, dextran, polyvinylpyrrolidine, borate ions, calcium lactate, sodium polyphosphate and silicates or acetates. The composition of claim 1, wherein the sugar glass particles are about 0.1-100 micrometers in diameter. 6. A composition according to claim 5 wherein the diameter is 1-10 micrometers. 2. A composition according to claim 1, wherein the microparticles have a water content of 4% or less, preferably 2% or less, ideally 1% or less. The composition of claim 1, wherein said first component is monodisperse in said second component The composition of claim 1, wherein the concentration of the first component in the second component is about 1-40 wt%. 10. The composition of claim 9, wherein the concentration range is 10-15%. The composition of claim 1 wherein the surfactant concentration in the second component is 0.01-10%. The composition of claim 11, wherein said concentration is about 1%. The composition of claim 1 further comprising a first component in which the inorganic salt is added in an amount effective to produce a density match with said second component liquid phase in said particulate. The composition of claim 1 further configured by incorporation of an additive into the microparticles that imparts a weak residual electrostatic charge to the microparticles and causes the microparticles to repel one another. 15. The composition of claim 14, wherein said additive is an amino acid. The composition of claim 1, wherein the perfluorocarbon is selected from the group consisting of perfluorohexane, perfluorodecalin and perfluorophenanthrene. The composition of claim 1, wherein the bioactive compound is a vaccine, drug, enzyme or diagnostic agent. Iii) producing the first component particulate according to claim 1; Ii) suspending said microparticles in said second component perfluorocarbon according to claim 1; And Iii) administering the mixture to a patient How to Deliver Bioactive Materials to Patients in a Stage