JPH11514979A - Bioavailable system for virtually insoluble bioactive agents - Google Patents

Abstract

  (57) [Summary] The present invention is a method of preparing a system for delivering a bioactive agent and a composition prepared thereby. The present invention involves forming a solid dispersion of the bioactive agent in an increased energy state in a water-soluble polymer miscible with the bioactive agent. The bioactive agent is converted to an increased energy state and immobilized in such a state in a water-soluble polymer, so that the bioactive agent becomes bioavailable upon dissolution of the polymer. The methods and compositions have been shown to be extremely effective in delivering drugs and other bioactive ingredients that are otherwise substantially insoluble.

Description

DETAILED DESCRIPTION OF THE INVENTION    Bioavailable system for virtually insoluble bioactive agents   This invention is related to co-pending application Ser. No. 08 / 524,531, filed Sep. 7, 1995. It is a continuation-in-part application, the entire disclosure of which is incorporated herein.                                Background of the Invention   The present invention relates to a technology for administering bio-affecting agents to a biological system. In particular, drugs that are substantially insoluble in aqueous environments are Systems to allow interaction with humans and animals, for example.   Biological systems such as humans, plants, insects, fish, birds, and mammals are primarily aqueous . To effectively administer a bioactive agent to such a biological system, the agent must be It is necessary to be able to interact with physiological activities in the system. This specification This is referred to in the book as "bioavailability." Insoluble in aqueous environment In the case of a bioactive drug or a drug that is only slightly soluble in water, Due to poor availability and consequently low pharmacological activity, Effective administration of drugs is difficult.   This solubility problem can be caused by the number of doses, such as the mode of administration, the rate of Affects parameters.   The dissolution rate of drug particles reduces the surface area of the solid, i.e., reduces the particle size. It is known that shrinkage increases. Therefore, the subdivided drug Methods for producing the drug have been studied, and the size and size of the drug particles in the pharmaceutical composition have been studied. Efforts have been made to control the range of For example, to reduce the particle size Dry milling techniques have been used to affect drug absorption. You. However, with conventional dry milling, the Theory and Practice of Industr ial Pharmacy, Chapter 2, "Crushing", p. 45 (1986), by Lachman et al. As discussed, the fineness limit reaches the region of about 100 μm (100,000 nm) However, in this area, the comminuted material begins to solidify on the surface of the grinding chamber. Lachman et al. States that wet grinding is advantageous for further reducing particle size However, due to this aggregation, the lower limit of the particle size is limited to about 10 μm (= 10,000 nm). You. Prejudice against wet milling in pharmaceutical technology due to concerns about contaminants Tend to have. Commercial air jet milling technology has an average particle size of about 1μm A particle size of 50 μm (= 1,000 nm to 50,000 nm) is supplied.   Other techniques for preparing pharmaceutical compositions with increased water solubility properties include drugs. Liposomes or polymers, for example, during emulsion polymerization. I will. However, there are problems and limitations with such technologies. For example, a suitable liposo In most cases, fat-soluble drugs are needed to adjust the system. In addition, drug In order to adjust the dosage, unacceptably large amounts of liposomes and polymers are often used. Often needed. Furthermore, the techniques for preparing such pharmaceutical compositions are complex. It tends to be. The major technical difficulty encountered during emulsion polymerization is at the end of the manufacturing process. Of contaminants such as unreacted monomers and initiators (which may be toxic) Elimination.   U.S. Pat. No. 4,540,602 (Motoyama et al.) Was finely ground using a wet mill. A solid drug contained in an aqueous solution of a water-soluble polymer substance is disclosed. But Motoyama Have shown that as a result of such wet grinding, the drug has a diameter of 0.5 μm (500 nm) to 5 μm. m (5,000 nm).   EPO 275,796 contains colloids containing substances in the form of spherical particles smaller than 500 nm. The preparation of a disperse system is described. However, this method involves the use of a substrate solution and its substrate. Includes a precipitation process by mixing with a miscible non-solvent, resulting in an amorphous nanoparticulate. A vehicle is formed. In addition, precipitation techniques to condition the particles require solvent contamination. Particles. Such solvents are usually toxic and if not possible If not, it is difficult to remove them sufficiently to a pharmaceutically acceptable level. Obedience Thus, the precipitation method is usually impractical.   U.S. Pat.No. 4,107,288 discloses biologically or pharmacologically active substances. Particles of 10 to 1,000 nm in size are described. However, this grain A molecule contains a cross-linked matrix of macromolecules, where the active substance is Is retained above or in a matrix.   U.S. Pat.No. 5,145,684 includes drug particles having an effective average particle size of less than about 400 nm. A method for supplying a child is described. This method involves the use of grinding media with the surface preparation. Wet grinding the drug in the presence. As in the previous method, Tocol requires grinding or grinding to reduce its size. This method is Furthermore, the use of additives in the form of surface preparations is necessary.   In addition, even if wet grinding as described in the '684 specification, Drugs prepared by crushing are subject to heat, physical and chemical damage associated with crushing. Easy to get solutions. Milling can also be a "hot spot", that is, the melting point or This produces local hot spots above the decomposition temperature. This process also takes a long time And require friction for several days. This type of The process involves exposing the drug to a virtually prolonged "heat history", The increase in temperature is significant and reduces the purity and potency of the drug to a significant extent. In addition, the particles that have been finely ground by grinding often contain residues from the grinding operation. In particular, ball mill grinding is used, and the grinding balls are worn by friction Sometimes it is.   Also, in drug delivery technology, soluble substances such as water-soluble beads are used. Bioavailability by aggregating substantially insoluble active ingredients on the surface It is known to improve abilities. Sprinkle the active ingredient solution on a fluidized bed and Washing out the solvent used for the active ingredient allows the active ingredient to be Can be deposited. This method provides an available delivery system In that it takes several hours to deposit a sufficient amount of active ingredient to And inefficient. In addition, unnecessary components that are unnecessary for this system, namely , The solvents necessary to dissolve the active ingredient must be used. I mentioned earlier As such, this solvent must be washed away when flocculated. Therefore, this The system is a long and cumbersome process that offers the efficiency of dose delivery. There is no.   Solubilization techniques for poorly water soluble drugs require organic dissolution for processing in solution. Requires the use of a medium. This means that expensive recovery systems can be used to handle the solvent. You need to use a stem. General melters to form dispersions When techniques are used, bulk melting and mixing processes often lengthen the drug. Exposure to heat history.   A sub-type that can be easily prepared without size reduction by grinding or grinding It is desirable to supply micrometer-sized, stable and dispersible drug particles. New In addition, supply pharmaceutical compositions with enhanced bioavailability It is highly desirable to do so.   Accordingly, it is an object of the present invention to deliver biologically active components, especially components that are substantially insoluble. Overcoming the inconveniences associated with how to build a Lee system.   Overcoming this shortcoming known in the prior art has resulted in improved delivery technology It is clear that other and further objects to be recognized as a result of the present invention became.                                Summary of the Invention   The present invention is a composition for delivering a bioactive agent to a biological system, comprising It is a method of constructing and using a delivery system including a drug for medical use. The composition The method includes the use of:   That is, it has a glass transition temperature (Tg) in the range of about 0 ° C. to about 200 ° C. In miscible water-soluble (or water-dispersible) polymers, the drug has increased energy The drug is bioavailable in its aqueous environment. A solid dispersion of the bioactive agent.   Preferably, the water-soluble polymer has a glass transition temperature of about 25 ° C to about 150 ° C, and more preferably Any polymer, such as from about 40 ° C to about 100 ° C, is preferred.   Preferred water-soluble polymers include polymethacrylic acid polymers. Preferably the The polymethacrylic acid polymer has the following structure. Where R¹, R^Two, R^Three, R^FourHas a glass transition temperature of the polymer in the desired range As long as it is an optional substituent. Therefore, preferably, R¹, R^Two, R^Three, R^FourIndependently Hydrogen (H), or any alkyl, aryl, alkaryl, aralkyl, Aminoalkyl, alkyl-substituted aminoalkyl, ammonioalkyl, or It is a alkyl substituted ammonium alkyl group. More preferably, R in structure (1)¹ , R^Two, R^Three, R^FourIs independently H, C₁-C₆Alkyl, aminoalkyl, methyl or Is dimethylaminoalkyl, or methyl, dimethyl, or trimethylammonio Alkyl. Still more preferably, in structure (1):       R¹Is H, CH^ThreeAnd       R^TwoIs H, CH_Three, C_TwoH_Five, CH_TwoCH_TwoN (CH_Three)_TwoAnd       R^ThreeIs H, CH_Three, And       R^FourIs CH_Three, C_TwoH_Five, C_ThreeH₇, C_FourH₉,            CH_TwoCH_TwoN (CH_Three)_Three ⁺X^-And X^-Is any monovalent anion is there.   Highly preferred water-soluble polymers are butyl methacrylate, (2-dimethyl alcohol) Minoethyl) methacrylate, and the relative proportion of methyl methacrylate     1: 2: 1 terpolymer.   Water-soluble polymers are polymers that have pH-sensitive solubility in aqueous media Is preferred. The water-soluble polymer is converted to an aqueous medium having a pH of about 1 to about 11. Preferably have solubility. The water-soluble polymer is acidic, that is, It is further soluble in an aqueous medium having a pH of about 7 or lower. preferable.   A bioactive agent is any agent known to have an effect in a biological system. good. Preferably, the bioactive agent is substantially insoluble in an aqueous environment. This Bioactive agents in the USP may be defined as effectively insoluble or insoluble Is more preferable. The bioactive agent is preferably an antifungal, anti-inflammatory, Hypertensives, antibacterials, steroids, hormones, prostaglandins, interf Heron and mixtures thereof.   Further, the composition comprises a bioactive agent and a water-soluble polymer, preferably the agent. The above polymers meet or exceed the USP solubility criteria.   The composition of this embodiment is a flash flow of a raw material containing a bioactive agent and a polymer. -May contain solid dispersions supplied by flash-flow processing . The above flash flow processing is a flash heat processing. ) Or flash shear processing. Hula Flash heat treatment is particularly useful when the bioactive agent being treated is heat sensitive. Preferred when doing. Another is a solid dispersion, where the solid dispersion is formed The mixture is supplied by extrusion mixing for a time sufficient for Preferably, the time for extrusion mixing is less than about 2 minutes, and less than about 30 seconds. More preferred. When the solid dispersion is supplied by extrusion mixing, Most preferably, the drug is an antifungal, anti-inflammatory or anti-hypertensive agent.   The compositions of the present invention provide a bioactive agent with at least a substantially uniform or amorphous form. Included as solid dispersion. In the form of nanoparticles dispersed throughout the solid dispersion Preferably, a bioactive agent is present. The nanoparticles are smaller than about 1000nm More preferably, it has a low average particle size. Flat of that nanoparticle Even more preferably, the average particle size is less than about 400 nm. The above bioactive agent Can be dispersed at the molecular level in a water-soluble polymer.   The compositions are controlled release microparticles (co) by mechanically reducing the solid dispersion. ntrolled-release particulate). Preferably on The fine particles are unit doses selected from the group consisting of capsules, tablets, and rapidly dissolving tablets. Part of the dose. Or, the solid dispersion may be intravenous (or other parenteral) It is sized and shaped to fit the delivery system equipment. In addition, solid content Dispersions are in the form of slowly dissolving structures, such as suppositories, drops and the like. Can be supplied at   The method converts the bioactive agent to an increased energy state and fixes the agent to that state. Including performing the same at the same time. This method uses flash flow processing. Includes occasional conversion and fixation. This method can be used for flash heat treatment or flash heating. Including the use of ash shear treatment. Heat sensitive drugs are processed by flash heat treatment Is advantageous. On the other hand, simultaneous conversion and fixation occur when sufficient to form a solid dispersion. Extrusion, preferably for less than about 2 minutes, more preferably for less than about 30 seconds. It can be caused by mixing. In the latter approach, the bioactive agent is an anti- Most preferably, they are fungicides, anti-inflammatory agents and anti-hypertensive agents.   Methods for converting a bioactive agent to an increased energy state include, without mechanical friction, Dispersed nanoparticles with average particle size less than 1000 nm for bioactive substances May be included. Mechanical milling is used for nano-particles with an average particle size less than about 400 nm. It is even more preferred to create a particle. In addition, the present method uses a biological It can be dispersed in a bell and used to create a solid solution.   The method may further include mechanically turning the solid dispersion into fine particles. You. Thus, the method may be used in dosage units such as capsules or rapidly dissolving tablets. Includes methods to get children. The method may also be used for intravenous flow (or other Parenteral) Size and shape the solid dispersion to be compatible with the delivery device Including. Drops, suppositories, and other slow-release deliveries The structure can also be used for delivery of a bioactive agent.   The invention further includes methods and compositions for delivery of a bioactive agent. Book The composition produced by the method includes: That is,   a) a carrier comprising a water-soluble polymer having a glass transition temperature of about 0 ° C. to about 200 ° C. When,   b) It contains a bioactive agent microscopically dispersed in the water-soluble polymer. The water-soluble polymer preferably has a pH-sensitive solubility in an aqueous medium .   In particular, this water-soluble polymer is substantially insoluble in saliva but soluble in gastric juice. It is desirable to have.   As noted above, the present invention also provides for delivering a composition of a bioactive agent to a biological system. Including methods to do. The method comprises treating water having a glass transition temperature of about 0 ° C to about 200 ° C. Solids containing bioactive agents fixed in an increased energy state in a soluble polymer Dispersion, whereby the solid dispersion allows the bioactive agent to be bio- Administering the solid dispersion, which is rendered irrable, to a biological system.   The methods and compositions of the present invention have many advantages over the prior art. For example, The present invention treats a bioactive agent with a water-soluble polymer to form a solid dispersion. The method used is the use of solvents, mechanical friction and grinding, which are the various disadvantages described in detail above. This is a beneficial method, but it can be avoided. In addition, this method Substantially reduces the thermal history of the drug, causing the drug to degrade substantially less throughout the process. There is an advantage that it remains without. The methods and compositions of the present invention also provide bioactive agent biologics. ・ Dramatically increase availability. Those drugs are otherwise aqueous Substantially insoluble in the environment, this method makes these drugs very easy and simple And deliver it to biological systems in more ways than was previously possible. it can.   These and further advantages are described in the detailed description of the invention below and in the description below. It will be understood by those skilled in the art in view of the drawings. Also, the scope of the present invention is to It will be clear in the claims.                             BRIEF DESCRIPTION OF THE FIGURES   FIG. 1 shows the solution of the solid dispersion prepared by the flash heat treatment according to the present invention. 5 is a graph showing the effect of the present invention by drawing an outline of the resolution characteristic.   Figure 2 shows an overview of the solubility of bulk nifedipine without the solubility enhancement treatment FIG.   FIG. 3 is prepared by extrusion processing in accordance with the present invention. The present invention provides an overview of the solubility properties of the prepared nifedipine solid dispersion. 3 is a graph showing the effect of the above.   FIG. 4 shows an overview of the dissolution of the antifungal solid dispersion prepared according to the present invention. Drawn in contrast to the lysis overview of known delivery systems for fungicides, In addition, we will outline the dissolution of bulk antifungal agents that have not been treated for solubility enhancement. Therefore, it is a graph showing the effect of the present invention.                             Detailed description of the invention   The present invention provides compositions for delivery of bioactive agents and preparing the compositions. Composition and method for making the bioactive agent bioavailable in an aqueous environment Is the law. The composition of the present invention comprises a solid dispersion of a bioactive agent in a water-soluble polymer. Can be called.   The present invention relates to a composition for delivering a bioactive agent to a substantially aqueous biological environment. Both things and methods. The present invention makes bioactive agents more bioaqueous in aqueous environments. ・ Make it available. The method of preparing the specific composition of the present invention comprises: 1) convert the bioactive agent to an “increased energy” state, 2) in a water-soluble polymer And fixing the bioactive agent to "increased energy". "Increasing energy The term “-” or “high-energy” state means that the bioactive agent is at the molecular or average level. Microscopic particles having a particle size of less than 1000 nm, preferably less than about 400 nm Stable distribution of the bioactive agent in a solid matrix, such as Refers to dispersion. The increased energy state is due to size reduction through grinding or friction Rather than by modifying the particle formation. Generally speaking, the present invention To convert bioactive agents into solution form or nanoparticle form. This morphology is, for example, compared to natural crystals that can have an average size of 10 μm or more. High surface energy or free energy.   The composition of the present invention is herein a solid dispersion of a bioactive agent in a water-soluble polymer. It is described as When this polymer dissolves in biological systems, the bioactive agent Be bio-available for the host. As used herein, "Bio Abe "Irability" refers to a biological effect on a host biological system to interact with a bioactive agent. It means that the drug is taken up. The mechanism of “incorporation” is absorption, adsorption, and conversion. Transfer, adhesion, adhesion, chemical, biological, biochemical reactions, etc., but not limited to these It is not something to be done.   The present invention has been modified because bioactive agents are relatively difficult to dissolve, especially in aqueous media. Bioavailability of drugs with limited or otherwise lost activity Improve The term "substantially insoluble" means that it is substantially insoluble in water or Applies to any substance that is not water-soluble to the extent permitted. Therefore, substantially Non-soluble bioactive agents include biological fluids such as blood, lymph, gastrointestinal fluid, cerebrospinal cord Bioactive agents that are insoluble or only slightly soluble in liquids, plant sap, etc. Including this. Bioactive agents are typically not soluble in the intestine as defined below. No.   10 mg of a substance in water (or other aqueous medium) with a pH of about 1 to about 8 A substance is said to be "substantially insoluble" if it has a solubility of less than / mL Sometimes. The solubility of any substance in an aqueous medium can easily be determined by those skilled in the art. This is a characteristic that can be used. In fact, the solubility of many substances, including drugs, is known and Published as a summary such as the Index 12th edition (The Merck Index, 12th) (1996) Has been versioned. A bioactive agent is a drug that is defined in the USP as “effectively insoluble. Most preferably, the solubility is low enough to be referred to as "or insoluble." This By definition, the bioactive agent is at least per part of solute (bioactive agent) Practically insoluble when 10,000 parts of solvent (aqueous medium) has the required solubility is there.   While it is contemplated that any bioactive agent can be used in the present invention, the present invention, in particular, Combination of a substantially insoluble bioactive agent and a water-soluble polymer in a unique way Making the insoluble drug bioavailable.   A substance that can be bioactive as defined elsewhere herein, wherein the substance is substantially Substances which are said to be insoluble in are preferred for delivery according to the invention. Also, Substantially insoluble bioactive agents can be used in aqueous media, including other bioactive agents. It is contemplated that it can be used with other materials that are substantially more soluble.   Polymers that can be used as the “water-soluble polymer” in the present invention include polymers , Copolymers, terpolymers, interpolymers, polymerizable amalgams (polymeri amalgams), which are molecules ranging from oligomers to high molecular weight polymeric substances. It is a polymer that has a quantity and pH-dependent dissolution properties.   As used herein, “water-soluble” refers to a surfactant, a dissolution promoting substance such as an emulsifier, etc. With or without the help of quality, water or other aqueous medium at any or all pH values Used for easily soluble or dispersed polymers. However, if the polymer is aqueous The fact that no mediator is required to dissolve in the environment is provided by the present invention. It does not mean that the delivery system does not contain such agents. To design a suitable delivery system, bioavailable bioactive agents Uses any additives needed to control, promote, mediate and regulate the ability Can be. These substances are referred to herein as “bioavailability Lomotor ". Furthermore, in this delivery system, Combinations of availability promoters can also be used.   According to the present invention, the bioavailability of a bioactive agent is increased It is enhanced by changing the physicochemical conditions. This allows bioactive agents to be Processing with a limmer carrier to form a solid dispersion of a bioactive agent in a polymer Achieved by “Solid dispersion” refers to a bioactive agent and a water-soluble polymer (such as A microscopically heterogeneous mixture of (and other substances defined elsewhere herein) Means a solid material that is homogeneous. In conventional terminology, a bioactive agent is a "dispersed phase" , While the water-soluble polymer constitutes the “dispersion medium” or continuous phase.   The method of the present invention can be used to produce any of the following solid dispersion compositions: Can be.   That is,   a) at least part, preferably all, of the bioactive agent is in solution phase with the polymer Solution systems that are at or dispersed at the molecular level (ie, “molecular dispersions”); Is   b) a somewhat discontinuous supramolecular region in which the bioactive agent is evenly dispersed in the polymer ( Nanoparticles), which may be molecular aggregates, but exist in that area It is a heterogeneous composition. In addition, the quenching of the water-soluble polymer according to the invention g) results in the bioactive agent having macroscopically separated phases or large areas in the final product. The formation of zones is prevented.   Thus, the solid dispersion is a substantially uniform dispersion throughout the polymer medium. It may include a discontinuous region of a body agent. These discontinuities, if any, Here, it is generally called “nanoparticle”. Crystallizable bioactive drug field If so, this region of the biopharmaceutical may be referred to as a "nanocrystal." These terms Implies that the dimension of the dispersed phase of the solid dispersion of the present invention is abnormally small. You. Specifically, the particles of the dispersed phase of the solid dispersion are typically of the order of nanometers (〜1 × 10^-9m) to 100 nanometers (~ 100 x 10^-9m). Therefore The scale of such particles has traditionally been “nanometer scale” or “na No Scale ". These characteristics of the production method of the present invention Is expected to greatly contribute to the increase in bioavailability of the drug .   Other solid dispersions according to the present invention are dispersed at the molecular level throughout the water-soluble polymer Bioactive agents are included. These solid dispersions of the present invention use the customary solutions May be characterized as a solid solution because it meets certain criteria. Scripture Formally, there is little or no supramolecular composition in such a solution. I However, the solid dispersions according to the invention can be converted from molecular dispersions to amorphous or molecular From pre-crystalline associations to the nanoparticle region Understand that bioactive agents can be in a range of physical conditions Must.   Accordingly, the solid dispersion of the present invention may comprise two or more constituents constituting a continuum. Of the bioactive agent, wherein substantially all domains of the bioactive agent are It has higher entropy than the entropy of the active state. The present invention As a result of forming a solid dispersion of Fixed or frozen in a hydrophilic polymer. "Enhanced energy state" as used herein Means that the bioactive agent has a higher entropy than when in its native state. Having a physicochemical state of a bioactive agent. For example, a preferred embodiment In, the bioactive agent is converted to a substantially amorphous form and is water soluble in the molten state Disperses throughout the polymer, so the drug crystallizes (if it crystallizes) When the average crystal size is nanoscale particles, that is, nanoparticles Constitute. The bioactive agent is thereby highly disordered compared to its native form It is captured in the state where it was done. The increased energy state of the present invention enhances drug delivery in aqueous environments. Enough to make it bioavailable. As discussed herein above, In addition, bioavailable means that the active ingredient is the target biological system, Interacts with the human patient's body, meaning it becomes available .   The compositions of the present invention, referred to herein as solid dispersions, are formed in a number of ways. Can be made. In one preferred embodiment, the solid dispersion comprises a drug and Formed by subjecting a raw material containing both limers to flashflow processing . Flash flow processing is defined herein below as Includes both processing and flash shear processing. On the other hand, the solid dispersion of the present invention Presses the drug and polymer during quenching for a time sufficient to convert and fix the drug. It has been found that they can be supplied by mixing out. Good In a preferred embodiment, the time required for extrusion mixing of the components is less than about 2 minutes (2 minutes). Short, preferably less than about 30 seconds (30 seconds).   As a result of the present invention, bioactive agents are often largely soluble in in vitro data. It can be supplied in a solid dosage form as perceived to have a dissolution rate. Dissolution Increasing speed has multiple effects, most importantly, beyond the level of traditional crushing methods. Is to reduce the particle size each time, but it is achieved by their combination It is theorized. Smaller sized particles (ie, nanoparticulates of the invention) Vehicle) to bioactive agents when they are higher than in their native or native state. Clear surface energy and free energy, increasing solubility in water. And usually corresponds to an increase in bioavailability in biological systems. Previous As mentioned, techniques known hitherto in the prior art typically involve aqueous Solubilize or melt using a carrier that easily dissolves in (low viscosity) state, Requires subsequent treatment to settle or condense the substance into a solid form .   The methods and compositions of the present invention are unique in making solid dispersions of bioactive agents. Has advantages. As a result of the present invention, the bioactive agent and the carrier polymer are mixed and melted. It can be put together in the dissolving and forming steps, and solidified in a continuous step. Bioactive agent as a solid solution or dispersion having an increased energy state as defined in The agent is supplied. The resulting composition can be used as a tablet or other, otherwise raw, formulation. A variety of deliveries that may not be able to deliver a body acting drug effectively It can be used immediately for system construction.   Another important advantage of the present invention is that bioactive agents can be made bioavailable. Less exposure to thermal history during processing. Required by the process of the present invention The thermal history is very short compared to conventional techniques used to form solidified material. Therefore The method of the present invention includes low degradation or degradation of the bioactive agent, It means improved purity and efficacy over prior art systems. This is heat It is particularly beneficial for sensitive bioactive agents.   The system of the present invention comprises a bioactive agent and a water-soluble polymer that are "miscible" with each other. Performed by the use of As used herein, the term "miscible" is used according to the present invention. Used to mean that the polymer has physical properties that make it processable. You. Specifically, the water-soluble polymer may be at or below the melting point (Tm) of the bioactive agent. Above the decomposition temperature (Td) of the bioactive agent and polymer. It must be able to process at low temperatures. Therefore, the melting point of the bioactive agent Above or above the decomposition temperature of the drug and polymer itself It is preferred to use a polymer which is also fluid at low temperatures (usually thermoplastic).   In addition, the bioactive agent and the polymer can interact with each other in a fluid / non-degraded state. Anything that can be dissolved or dispersed is called "miscible". For example, bioactive drugs Visualization of the agent / water-soluble polymer composition immediately after solidification often results in substantially Looks like transparent or translucent glass. That is, any non-uniformity Of the bioactive agent solubilized from the water-soluble polymer It is.   The miscibility referred to here also means that the polymer and the bioactive agent are " Trapped in an `` increased energy '' state, and then remain stable until solidification is complete It means to solidify to be maintained. The bioactive agent may subsequently crystallize. Any crystals that form may be the size of a nanoparticle. That is, the crystals are significantly higher than the native crystals of the drug. And the crystals will typically have an average of about 10 μm to about 50 μm. Has a particle size. The polymer and the bioactive agent are Lower forms of ropies, such as those that bring the drug closer to its native state Solidifies at a rate that allows it to form regions that substantially return to crystal size If so, the combination is not considered miscible as defined here. More important What is important is that bioavailability depends on such a combination of incompatibility. Is little or no improvement. Therefore, miscibility is not In addition, the polymer may cause the bioactive agent to return to a lower energy state or Bioactive drugs to prevent them from returning to the particle state with a larger average size Means that it can be quenched or solid formed with the agent.   The polymer has physical properties that facilitate the formation of the solid dispersion described herein. It is naturally preferable to do so. We determined that the glass transition temperature (Tg) Unexpectedly that the properties of the polymer correlated well with the usefulness of the polymer in I found it. In particular, polymers having a Tg of about 0 ° C to about 200 ° C are preferred. We have found. Further, the polymer has a Tg of about 25 ° C to 150 ° C. preferable. Even more preferably, the polymer has a Tg of about 40 ° C to about 100 ° C. New   Low Tg is usually correlated with low viscosity at the above temperature, and Tg is Or we found something related to processing. Has a Tg outside the above range Polymers are less preferred. On the other hand, if the Tg is too high, the polymer becomes viscous Tend to be too high, making processing of the polymer difficult. On the other hand If the Tg is too low, the polymer will cause the bioactive agent to May not be sufficiently viscous to be effectively captured or coagulated. Sa Furthermore, we have identified that the polymers characterized in the Tg range are non-soluble bioactive agents. Aqueous enough to have the effect of increasing bioavailability It has been found that it tends to be soluble in the environment.   The polymers useful according to the invention generally also fulfill other physicochemical properties. example For example, polymers useful in the present invention typically have an average molecular weight greater than 500 Daltons (Da). It has a molecular weight, preferably 1500 Da or more. For certain applications, 100,000 Da May have a higher molecular weight. In addition, The clear water-soluble polymer is preferably from about 1,000 centipoise (cP) to several million cP solids. It has a viscosity and a melt viscosity of about 50 cP to about 100,000 cP. Polymeric Viscosity can be measured with a Brookfield Viscometer. In addition, a port that does not crystallize Remers are probably preferred over those that crystallize, but this property is I don't know.   Polymethacrylic acid polymer (also referred to herein as "polymethacrylate") ) Is one of the preferred water-soluble polymers for use in the present invention. For example, preferred Polymethacrylates have the general formula: Where R¹, R^Two, R^Three, R^FourIs independently hydrogen (H) or any alkyl, aryl , Alkaryl, aralkyl, aminoalkyl, alkyl-substituted aminoalkyl , Ammonioalkyl, or an alkyl-substituted ammonioalkyl group.   Preferably, R¹, R^Two, R^Three, R^FourAre independently H and C₁-C₆Alkyl, amino (C₁ -C₆) -Alkyl, methyl- or dimethyl-aminoalkyl, or methyl -, Dimethyl- or trimethyl-ammonioalkyl.   More preferably, the polymethacrylate of structure (1) has the following substituents . Ie   R¹Is H, CH_ThreeAnd   R^TwoIs H, CH_Three, C_TwoH_Five, CH_TwoCH_TwoN (CH_Three)_TwoAnd   R^ThreeIs H, CH_ThreeAnd, and   R^FourIs CH_Three, C_TwoH_Five, C_ThreeH₇, C_FourH₉,        CH_TwoCH_TwoN (CH_Three)_Three ⁺X^-And X^-Is any monovalent anion , Preferably Cl^-It is.   Examples of polymethacrylic acid polymers can be found in the Handbook of Pharmaceutical Excipients 2nd edition pp362-366, Ainley Wade and Paul J. Weller, eds (1994), A.J. ShuRla, “P olymethacrylates ". Many of these polymers are EUDRAG Available as a coating from Roehm GmbH under the trade name of IT. Especially effective The polymers found were butyl methacrylate, (2-dimethylaminoethyl) meth Methacrylate and methyl methacrylate in a ratio of 1: 2: 1 Terter polymer product sold as EUDRAGIT E.   The water-soluble polymer is preferably a polymer whose solubility is pH-sensitive. Specifically, when solubility in an aqueous medium is affected by pH, the polymer has a pH Called sensitivity. The water-soluble polymer used in the methods and compositions of the present invention has a pH of 1 It is preferable to have a higher solubility at pH from pH 10 than outside this range. Good. More preferred polymers are more acidic than at neutral or alkaline pH It is a polymer that is substantially soluble at neutral pH. Therefore, the water-soluble polymer has a pH of 7 Desirably it is soluble below. pH-sensitive solubility, specifically acid-sensitive solubility By selecting a water-soluble polymer having a solubility, the solubility of the solid dispersion of the present invention is The material is minimized until it is exposed to acidic conditions. Therefore, saliva has substantial The substance can be made to be physically insoluble but soluble in gastric juice, More selective control over bioavailability of bioactive agents . (In certain applications, ie, delivery of bioactive agents to the intestine, water-soluble Preferably, the polymer has alkali-sensitive solubility. ) All such poly The mer is called "enteric".   Preferred enteric polymers are defined according to the comonomer of the group from which they are prepared. You can also. For example, methacrylic acid and methyl acrylate and / or Methyl methacrylate copolymers and terpolymers are highly preferred and have a pH of about Dissolves in the range of 5.5 to about pH 7.2. Such polymers are used for tablet preparation. It can be used as an enteric coating by Huls America Inc. AAPS T published by enh Annual Meeting (1995), Lehmann et al., “New methacrylic acid copo lymers for improved coating technology ".   EUDRAGIT polymer has a pH-sensitive solubility, which is its solubility It means high at pH and low at other pH. Depending on the pH, these The solubility of the limer can vary by an order of magnitude or more. Some poly meta Crylic acid is highly water-soluble under acidic conditions, and is the active drug in the gastric region of the digestive tract. Used to promote rapid release. EUDRAGIT E products have such an acid sensation Soluble soluble in gastric juices and weakly acidic (ie below pH 5) buffers It is. Others are easily soluble in weak alkalis (eg, pH 6-7), Suitable for delivering bioactive substances to the intestine by passing through the stomach region. Only However, these polymethacrylic acids are used as solid solution carrier materials for bioactive drugs. Not used and new applications, these polymers are very We have unexpectedly found it suitable.   Bioactive agents suitable for use in the methods and compositions of the present invention include humans and other mammals. Preferably a drug that has the potential to be bioactive to animals, including milk . A non-limiting list of these bioactive agents includes, for example, antitussives, Medicines, anti-inflammatory drugs, alkaloids, mineral supplements, laxatives, vitamins, antacids, Ion exchange resins, anticholesterolemia drugs, antilipid drugs, antiarrhythmic drugs, antipyretics, Pain medicine, appetite suppressant, sputum medicine, anxiolytic, anti-ulcer, anti-inflammatory, coronary vasodilator, cerebral blood Cerebral dilators, peripheral vasodilators, anti-infectives, antifungals, Viral drugs, psychotropic drugs, antimanic drugs, stimulants, gastrointestinal drugs, sedatives, antidiarrheal preparations, anti-angina Cardiology drugs, vasodilators, antihypertensives, vasoconstrictors, migraines, antibiotics, psychiatric Stabilizers, antipsychotics, antitumor agents, anticoagulants, antithrombotics, hypnotics, antiemetic drugs, antiprovocation Vomiting, antiepileptic, neuromuscular drugs, hyperglycemia and hypoglycemia Drugs, thyroid and antithyroid preparations, diuretics, antispasmodics, uterine relaxants, minerals and nutrition Additives, anti-obesity drugs, anabolic drugs, erythropoiesis drugs, anti-asthmatic drugs, Cough suppressants, mucolytics, anti-uricemic drugs , Prostaglandins, interferons, cytokines, steroids and drugs Includes peptide hormones, proteins, and mixtures thereof.   Other bioactive agents used in the present invention include antidiarrheals such as IMODIUMU AD, Contains histamine, antitussives, decongestants, vitamins, and breath fresheners. Ma Also, in this specification, anxiolytics such as XANAX and antipsychotics such as CLOZARIL and HALDOL Disease drugs, non-steroidal anti-inflammatory drugs (NSAID's) such as VOLTAREN and LODINE, SELDANE Antihistamines, such as KYTRIL, Sesameme, HISMANAL, RELAFEN and TAVIST Anti-emetic drugs like cesamet, like bentolin and PROVENTIL Antidepressants such as PROBAC, ZOLOFT and PAXIL, imigran (im igran) and ACE inhibitors such as VASOTEC, CAPOTEN and AESTRIL Anti-Alzheimer's drug, PROCARDIA, like Nicex, nicergoline Ca such as ADALAT and CALAN^HThe use of antagonists is also conceivable.   Well-known H_TwoAntagonists can also be used, including cimetidine, ranitidi Hydrochloride, famotidine, nizatidine, ebrotidine, mifen Tidine, roxatidine, pisatidine, and aceroxatidine ( aceroxatidine).   The invention is particularly useful for the following compounds which are substantially insoluble: That Compounds are vasodilators like nicergoline and anti-inflammatory like indomethacin Drugs, antipyretics, analgesics, antiarthritic drugs such as diacerin, megestro Progestogens, palliative treatments for breast and endometrial cancer, such as And estrus regulators, tranquilizers such as barbital, hypnotics, carbamazepine Nasal analgesics, anticonvulsants, antihypertensives like nifedipine, probenecid Uric acid excretion drugs, antianginal drugs such as felodipine, fenalamide )), Plant antifungals such as fenarimol and fendendazo It is an antihelminthic drug such as fendendazole.   In a preferred embodiment, the bioactive agent is an antifungal, anti-inflammatory, anti-hypertensive, anti-hypertensive, Microbial drugs, steroids, hormones, prostaglandins, interferons, And mixtures thereof.   In one preferred embodiment, the agent is a substantially insoluble bioactive agent. Ibuprofen and Nifedipine are sold by Roehm GmbH as EUDRAGIT E Known cimethylaminoethyl methacrylate and other neutral methacrylic acid Each found to be miscible with ester-based copolymers I have. This polymer consists of solvent-free particles (EUDRAGIT E 100) and propane-2 -Available as a 12.5% solution of all / acetone (60:40) (EUDRAGIT E 12.5) . EUDRAGIT E has a particularly high solubility in water under acidic conditions (below pH 5) , Causing rapid release of the drug in the stomach region of the gastrointestinal tract. This polymer is exclusively Amorph However, a new polymer can identify the microcrystalline regions of the polymer. Wear.   In a preferred embodiment, the process of the present invention is performed by a flash flow process. Can be The flash flow process has sufficient heat to convert the form of the material. And shear force at the same time. Flash flow processing Create, which means that the source material can move and separate at the sub-particle level I do. In this embodiment, the raw material is a water-soluble polymer and a substantially insoluble bioactive Will contain drugs.   Flash flow processing is used for flash heat processing or flash shear processing Therefore, it can be performed. In a preferred embodiment, the present invention provides a flash flow process. The process is described in commonly known U.S. Patent No. 5,380,473 to Bogue et al. It is intended to be based on the flash shear method described. The contents of the above patents Shall be included in the present specification. The process reported in the '473 patent by Bogue et al. , The temperature of the carrier of the insoluble raw material is raised to a temperature at which an internal stream is generated, Forces the fluid to extrude or expel it, subjecting the stream to destructive fluid shear forces, It is characterized in that the flow of the raw material is divided into separated masses having a form converted by force. You.   In another embodiment for the flash shear method, the components of the present invention comprise: Mixed and processed in a mixed extrusion process and ground as in the flash shear method The benefit of forming a clump is not obtained. Most of the operation of this alternative embodiment In a preferred embodiment, the starting materials, such as a water-soluble polymer and a substantially insoluble The bioactive agent (without solubilizing additives) can be used for a very short time, preferably no more than 2 minutes, It is also preferably subjected to mixing extrusion for less than about 30 seconds.   Other possible embodiments create conditions as found in cotton candy machines Treating the components in a flash heat process is included. This method uses raw materials The material is guided to the spinner head, where it is heated and the centrifugal force of the spinning head The shear force created by is applied. Method and apparatus suitable for substrate spinning The disclosure includes: No. 4,855,326, U.S. Pat. No. 4,873,085, U.S. Pat. No. 5,034,421, U.S. Pat. There is a patent No. 5,028,632.   Examples of the above-listed U.S. patents include applying heat supplied by a heating wire to the raw material. Describes how to process raw materials by rotating the raw materials at high speed on a spinning head. It is listed. The temperature change is very large and this The spinning head is fast and effective against the surrounding heating wire. rate It is thought that this is caused by the sprinkling of raw materials. Therefore, heating wire Extensive surface contact of the raw material to the surface occurs. Nevertheless, spinning The process is fast enough and the thermal history of the bioactive agent is not protracted.   As described herein above, the carrier used in the system of the present invention may be any of the carriers described herein. It is a water-soluble polymer that is miscible with the bioactive agent selected in (1). These carriers are Sufficient thermal stability to flash flow treatment, low molecular weight crystals or It can range from rufus materials to high molecular thermoplastic polymers. Thermoplastic polymer Can be treated in a temperature range that does not have a definite melting point but exceeds the glass transition temperature. Where the polymer elasticity is sufficient and can be extended, in which The active ingredient can be dissolved.   The present invention melts an active ingredient-miscible polymer (and other excipients) Active components can be trapped in an increased energy state during quenching Including doing. As such, the bioactive agent can be incorporated into the substrate or polymer. It is solubilized and does not separate into its own crystalline region. The drug is suddenly in an increased energy state Formation of very fine crystals (nanoparticles) in the carrier as a result of cooling And such crystals have greatly increased solubility and / or dispersibility I have. In the present invention, the carrier itself has excellent water solubility. As described in this specification As a result of the system described, when the carrier dissolves, the poorly soluble drug will be solid solution or Released as nanoparticles from the dispersion. Bioavailability in vivo It is the microparticle dispersion that enhances the tee.   The invention can be used to provide a product from the composition obtained here. It is also possible that it can be done. Design a delivery system for bioactive drugs Delivery proficiency to make patients available at the speed and intensity needed to treat patients Can be provided. For example, fibers resulting from processing according to the invention Can be crushed to provide small particles of the drug-loaded polymer. (Bearing Substantially uniform distribution of bioactive agents throughout the body is not due to fiber crushing That requires attention. Rather, unlike the prior art, the dispersion of the bioactive agent is Achieved in a pre-forming step. ) Then, the particles holding the drug are It can be coated by a technique. For example, filed on November 4, 1994 Simultaneous cooperative application entitled “Delivery of Controllled-Release System”, US The particles can be coated by the method described in patent application No. 08 / 334,729. Yes, and the entire disclosure of the above application is incorporated herein. Once covered The particles can be used as controlled release particles for capsules.   On the other hand, drug-bearing particles resulting from the milled product created according to the present invention are known in the art. Techniques can be used to produce tablets, preferably fast dissolving tablets. Like A new tablet manufacturing technique is described in the simultaneous co-pending application filed on June 14, 1994, US Patent Application No. No. 08 / 259,496, filed on June 6, 1995, PCT / US95 / 07194, both of which are referred to as “Proc. ess and Apparatus for Making Rapidly-Dissolving Dosage Units and Product  The method described in the application entitled “Therefrom” It shall be included in the description.   The present invention relates to a controlled release produced by grinding fibers made according to the invention. Includes both capsules and rapidly dissolving tablets containing exit and controlled release particles. This For these products, the brittle fibers that hold the bioactive agent are subject to physical stress. It must be noted that it is easily crushed when given, During the milling to reduce the particle size of the polymer that holds the drug, the bioactive drug It means that it is only exposed to minimal heat. This is usually a problem in forced friction This is a very significant improvement over the milling of raw material active ingredients that generate heat. Law The heat generated by the direct grinding of certain drugs is sufficient to cause recrystallization. This will serve to increase the average particle size. Therefore, the present invention To deliver to ecosystems by using fragile fibers produced by the law Can reach the smallest average particle size of This can maximize the bioavailability of the bioactive agent.   Tablets produced according to the present invention are processed to have further desirable properties be able to. For example, a tablet of the present invention may be coated with a semi-permeable membrane to provide controlled release of the active. Can be Further, the tablets of the present invention may increase or control the disintegration of the tablet. Tableting or dissolving agents (Bio-Availability Promo ) Can be formulated. Such bio availability Typical examples of promoters include hydroxyethyl cellulose and hydroxypro. And celluloses such as pillmethylcellulose and others.   Furthermore, in one embodiment, the composition produced by the method according to the present invention also comprises Can be further processed to make a lump or pulverized and tabletable mass it can. This may be necessary if additional excipients are required before tableting or It is particularly useful when the product itself cannot be tableted directly.   Further uses of the invention include intravascular (eg, intravenous, intraarterial) delivery of drugs. Lee included. Substantially insoluble drugs should be reduced in size prior to intravascular delivery. It is known that it must always be small. In fact, some drugs are blood Delivery in the tube is not possible. However, as a result of the present invention, a water-soluble poly The mass of mer is combined with the fluid supplied into the blood vessel for delivery to the patient. Can be The mass can be placed directly in the fluid stream. Another Stores the mass in the compartment and the drug is delivered by the flow Blood flow passes through it as described. Bioactive drugs for intravascular dosing In an embodiment used, the colloidal stabilizer is used to keep the bioactive drug particles dispersed. Excipients are generally used.   The compositions and methods of the present invention provide a drug delivery system as a commercial product. It is a very efficient system for providing. The composition of the present invention can be used for intramuscular injection, non- Oral administration, intranasal, osmotic pump, corrosive system Stem, inhalant, patch, subcutaneous injection, vaginal suppository, suppository, powder, intravenous (IV) administration, Can be used for roach or other oral delivery systems, and topical treatments Wear. A particularly preferred use is to dissolve polymers, such as sweat and internal bodily fluids, The composition is exposed to a bodily fluid that releases the drug for use.   The present invention is described in the following examples, in which, for example, ibuprofen Commercially available co-processed compositions of substantially insoluble bioactive agents, such as and nifedipine Prepared in combination with a water-soluble polymethacrylate polymer. Orally administered The solubility of low water soluble drugs is very low. Low solubility from non-dispersed state This is due to the slow rate of escape of the drug molecule. According to the present invention, Formulation techniques are provided that provide a solid dispersion (or solid solution) of the drug. This formulation The system formed by the technology bioinjects the insoluble drug into the patient's biological system. It has proven to be useful for making it bayable.   The examples, described below, provide the compositions, methods, and downstream routes derived therefrom. The product will be described. The examples are provided to meet legal obligations. And is not intended to limit the scope of protection afforded by this specification. Absent.                                  Example   Ibuprofen is an excellent nonsteroidal anti-inflammatory drug. Nifedipine is powerful Antianginals and antihypertensives. Both of these drugs are USP definitions, It is substantially insoluble in water and other aqueous media. Thus, it illustrates the potential of the present invention. Therefore, these two compounds were selected as model drugs.   EUDRAG, a polymethacrylate aqueous polymer used for pharmaceutical film coating ITE should be miscible with imbrofen or nifedipine in the molten flow state It's been found. The specific polymer used was dimethylaminoethyl methacrylate And methacrylate-based copolymers from Roehm GmbH, EUDRAGIT E Sold as. This polymer is listed in the USP / NF table.                      Example 1-Flash heat treatment   In this example, the polymethacrylate obtained from Roehm GmbH, Darmstadt, Germany was used. Powder polymer EUDRAGIT E (EUDRAGIT E 100, pellet type) is crushed into powder, The size was adjusted through a 60 mesh screen sieve. BHC HBMC Advance d Ibuprofen obtained from Materials Group, Bishop, Texas (product code IB 1D427, Grade 25) was added to the EUDRAGIT powder produced above and blended, and 80% by weight To form a formulation comprising 20% by weight ibuprofen in EUDRAGIT polymer Was blended in. Process this powder formulation with 36 5 "spinning heads with heater did. As parameters of the device, rotation speed 3,600rpm, power setting 20.5%, maximum temperature The temperature of 150 ° C is included. Thin, transparent and colorless yarns are flash-flow processed Produced.   Microscopic examination of the above substances in hypothetical gastric fluid (no pepsin) revealed that the polymer was soluble. It was revealed that countless nanoparticles were released when the sample was removed. Nano party The size of the circle could not be measured by optical means, but was much smaller than 1 μm. Was. Nanoparticle sizes range from 100 nm to 600 nm (ie, 0.1 μm to 0.6 nm). μm).   1 g (1 g) of a solid dispersion containing ibuprofen (= 200 mg ibuprofen Was added to 900 mL of 0.1N HCl and stirred at 100 rpm for 0.5 h. Take a sample and H Ibuprofen concentration was measured by PLC UV. This solid dispersion had a 0.066 μg / mL Buprofen concentration was indicated. This is the solubility of the drug substance tested by a similar analytical method. (0.030 μg / mL).                           Example 2-Extrusion mixing   The water-soluble polymer, EUDRAGIT E 100, is pulverized from a pellet form to a fine powder, The size was adjusted through a 60 mesh sieve. Eve the resulting uniform-sized powder 20% by weight ibuprof in 80% by weight EUDRAGIT polymer mixed with profen The compound was formulated to form a formulation containing the ene.   The resulting powder formulation was combined with a 1 cm nozzle, AP with multi-heater zone V-Baker MP2015 was processed on a twin screw extruder. The temperature of each of the four heat zones The temperature was set at 100 ° C. and the temperature was recorded thereafter. Zone 1 = 98 ° C, Zone 2 = 10 2 ° C., zone 3 = 100 ° C., zone 4 = 105 ° C. Twin screw speed Was set to 120 rpm. The extruded product is made of ibuprofen in polymethacrylate. The solid dispersion had a continuous rod-like structure.   1 g (1 g) of a solid dispersion containing ibuprofen (= 200 mg of ibuprofen ) Was added to 900 mL of 0.1N HCl and stirred at 100 rpm for 0.5 h. Take a sample and HPL The ibuprofen concentration was measured by C UV. This solid dispersion has a 0.067 μg / mL The profen concentration was indicated. This is the solubility of the drug substance tested in a similar assay ( (0.030 μg / mL).                      Example 3-Flash heat treatment   Pulverize the water-soluble polymer EUDRAGIT E 100 again from the pellet size to fine powder The powder was made uniform through a 60 mesh sieve. InterChem Corp Nifedipine (product code 15620, lot 55) from., Paramus, New Jersy , Sanofi) were added to the EUDRAGIT powder produced above and 80% by weight of EUDRAGIT polymer Formulated together to form a formulation with 20% by weight ibuprofen therein.   The powder formulation was processed with 36 heated 5 "formulation spinning heads. Was. As parameters of equipment, rotation speed 3,600 rpm, power setting 30%, maximum temperature 1 83 ° C is included. The extruded product is a polymethacrylate polymer -A solid dispersion of nifedipine in the form of yellowish thread.   The dissolution test of this substance was performed using virtual gastric juice (no pepsin), ie USP Method II. Using 900 mL of 0.1 N HCl, 1% TWEEN20. Samples at 37 ° C for 50r The mixture was stirred at pm for 30 minutes and then at 200 rpm for 15 minutes. The solid dispersion dissolves 78% in 5 minutes. 80% dissolved in 45 minutes. See FIG. This is the bulk (Raw) Only 1% dissolves in 5 minutes when drug tested, less than 16% dissolution in 45 minutes Compared to the degree. See FIG.                           Example 4-Extrusion mixing   The water-soluble polymer EUDRAGIT E 100 is pulverized from a pellet form to a fine powder, and Was sized through a 60 mesh sieve. The resulting powder of uniform size The powder is mixed with nifedipine and 20 wt% nifedipine in 80 wt% EUDRAGIT polymer. Formulated to form a formulation containing the pins.   The resulting powder formulation was combined with a 1 cm nozzle, AP with multi-heater zone V-Baker MP2015 was processed on a twin screw extruder. The temperature of each of the four heat zones The temperature was set at 175 ° C. and the temperature was recorded thereafter. Zone 1 = 172 ° C, Zone 2 = 177 ° C, zone 3 = 175 ° C, zone 4 = 180 ° C. The shaft speed is 120 rpm Was. The extruded product has a transparent, yellow, polymethacrylic A solid dispersion of nifedipine in a sheet.   Dissolution testing of the extruded material was performed using virtual gastric fluid (no pepsin), ie, 900 mL Performed using 0.1 NHCl, 1% TWEEN 20, USP Method II. Samples at 37 ° C for 50r The mixture was stirred at pm for 30 minutes and then at 200 rpm for 15 minutes. This solid dispersion dissolves 76% in 5 minutes. Was found to dissolve 81% in 45 minutes. See FIG. This is the bulk ) When the drug is tested, it dissolves only 1% in 5 minutes and less than 16% in 45 minutes Compared to that. See FIG.                      Example 5 Flash Heat Treatment   In this example, the polymer EUDRAGIT E 100 (pellet type) is ground into a powder. , Through a 60 mesh screen sieve. The resulting EUDRAGIT The fungicide was added to the powder and blended together. Combine the two components in a 1: 1 ratio That the resulting formulation is 50% by weight of the antifungal and 50% EUDRAGIT E With rimmers.   This powder formulation is processed with a spinning head and subjected to 60 Hz and 50% power cycling. Operated with a ring. Therefore, the head speed is about 3,500-3,700 pm, The temperature around the pad was maintained on average at approximately 218 ° C.   A thin, transparent thread was created from the flash heat treatment. Virtual gastric juice Microscopic observation of this substance in Psin) revealed that when the polymer dissolved, Release of the particles. The size of the nanoparticles is light It could not be measured by biological means, but was much smaller than 1 μm. Nano party The size of the particles is on the order of 100 nm to 600 nm (ie 0.1 μm to 0.6 μm) Is believed to be.   The dissolution test of this substance is as follows: virtual gastric fluid (no pepsin) 900 mL, 1% TWEEN 20, USP Method II, using 100 rpm, showed 88% solubility in 10 minutes . This was compared to the low solubility of 3.7% when bulk drug substance was tested. See FIG.                     Example 6 Flash Shear Processing   Again, the water-soluble polymer EUDRAGIT E 100 is pulverized from a pellet form to a fine powder. Then, the powder was sized through a 60-mesh sieve. The resulting EUDRAGIT powder The powder was mixed with an antifungal agent and compounded in a grinding mill. Then extrude the powder formulation Machine barrel temperature gradient from 164 ° C to 185 ° C, nozzle temperature 185 ° C, and extrusion air pressure Flash sheared using a 10 psi extruder.   The flash shear nozzle at the end of the extruder was installed at the same time as filed on September 6, 1994. Type described in pending co-pending application Ser. No. 08 / 269,679, in which air is heated to 170 ° C. Heated, pressure is 1.5 to 3 psi.   Thick fibrous material was made in this way. Above in virtual gastric juice (no pepsin) Microscopic observation of the substance showed that when the polymer melted, It was found to be released from the water-soluble polymer. Nanoparticle size Was much smaller than 1 μm. Nanoparticles produced as a result of this method Is of the order of 100 nm to 600 nm (ie 0.1 μm to 0.6 μm) It is believed that. This material disappears completely, leaving behind a milky white dispersion.   Dissolution testing of this material was performed using 90 mL of virtual gastric fluid (no pepsin) and 1% Tween20. USP Method II, run at 100 rpm, showed 77% solubility in only 10 minutes. Already Once this was achieved, with a rather low solubility of 3,7% when the bulk drug substance was tested Compared. See FIG.                           Example 7-Extrusion mixing   Water soluble polymer, EUDRAGIT E 100 The size was adjusted through the sieve. 1: 1 ratio of the resulting uniform size powder And mixed with an antifungal agent in a grinding mill.   The resulting powder formulation was processed in a twin screw extruder equipped with a 1 cm nozzle. Was. This method produced a transparent extrudate. The appearance of this material quickly becomes opaque It became a light, hard and brittle rope. The resulting extrudate is converted to virtual gastric juice (no pepsin). Microscopic observation in) shows a considerable number of very fine cells with a size smaller than 1 μm. It was found that paddle particles were released. This extrudate produces a milky dispersion Completely disappeared, leaving behind.   A dissolution test of this substance was performed using 900 mL of virtual gastric juice (no pepsin), 1% Tween20, U SP Method II, run at 100 rpm, showed 94% solubility in 10 minutes. This The drug substance was compared with a considerably lower solubility of 3.7% when tested. FIG. checking ...                        Example 8-Capsule Formulation   10 grams (10 g) of the 50/50 antifungal / EUDRAGIT E solid dispersion of Example 7 Crushed using a rotating blade and sieved on a 20 mesh screen. O size Capsules can be filled with 400mg of solid dispersion and contain 200mg of antifungal agent Capsules could be made. The above substance is free flowing, and the capsule filling It had ideal properties.                           Example 9-Formulation of tablets   The acid-soluble polymer, EUDRAGIT E100, is pulverized from pellet form to fine powder. , U.S. standard 60 mesh sieve. 1: 1 ratio of the resulting powder And mixed with an antifungal agent in a grinding mill.   The above powder formulation was processed in a twin screw extruder equipped with a 1 cm nozzle. The extruded product is cooled and milled in a high shear grinding mill. Crushed to reduce particle size. Microcrystalline cellulose NF (AVICEL PH101) and cloth Mix croscarmellose sodium NF with the above solid dispersion And 15.0% and 3.00% of the formulation, respectively. Antifungal and EUDRAGIT E To 41% of the formulation.   The tablet premix was prepared using a Specac hydraulic press using an 11 mm tablet die. Compressed at 2,000 psi to give 236 milligram tablets. These tablets are antifungal Provides a target dosage unit of 100 mg of the agent. This tablet is virtual gastric juice (no pepsin) It had a disintegration time of 13 minutes at 37 ° C in medium.                         Example 10-particle size distribution   Antifungal solid prepared by flash heat treatment according to Example 6 above The dispersion was classified by particle size. Add 200 milligrams (200 mg) of the solid dispersion to 900 mL of 0 Dissolved in 1N HCl. After 9 minutes, take out a certain amount and use standard photon correlation method Tested. Computer analysis shows that the average particle size in the sample is 196.8n m, indicating a monomodal distribution of particle size. ) Was found to be from about 155 nm to about 255 nm. As described herein above , These particles are clearly qualified as "nanoparticles".   The compositions of all of the above examples are of the opposite roller die type or regular die type. Using a metal mold followed by a co-processing (flash flow or co-extrusion) process Thereby, it can be easily formed into a tablet. By experiment, the composition was 80,0 Easily at pressures less than 00 psi, preferably from about 500 psi to about 40,000 psi It is shown to be a tablet.   The above examples show that the dissolution of the solid dispersion of the invention in an aqueous environment is very efficient It is clear that it is. In addition, tablets or tablets made according to the invention Capsules Provide Convenient Delivery of Substantially Insoluble Bioactive Drugs . Thus, the compositions and methods of the present invention provide a biodegradable bioactive agent that is substantially insoluble. Greatly improve availability.   Thus, what has been described as a preferred embodiment of the present invention has been described. Other and further embodiments will be apparent to those skilled in the art and It is intended to cover other modifications and changes that fall within the scope of the present invention as set forth in the appended claims. It is intended.

────────────────────────────────────────────────── ─── Continuation of front page    (72) Inventor Huys Richard Sea             United States Virginia 22066             Great Falls Cornwell             Arm Load 9320 (72) Inventor Blake Andrea             United States Virginia 22033             Fairfax Rugby Road             3748 (72) Inventor Young Robert Kay             United States of America New York 11355               Flushing Franklin Avenue             ー # 2 Sea 138-10

Claims (1)

[Claims] 1. A composition for delivering a bioactive agent to a biological system, wherein the composition is in an increased energy state in a water-soluble polymer miscible with the agent and having a glass transition temperature of about 0 ° C to about 200 ° C. A composition comprising a solid dispersion of the bioactive agent, wherein the agent is bioavailable in an aqueous environment. 2. The composition of claim 1, wherein said water-soluble polymer is a polymethacrylic acid polymer. 3. 3. The composition of claim 2, wherein said polymethacrylic acid polymer has the following structure: Here, R ¹ , R ² , R ³ , and R ⁴ are each independently hydrogen (H) or any alkyl, aryl, alkaryl, aralkyl, aminoalkyl, alkyl-substituted aminoalkyl, ammonium alkyl, or alkyl It is a substituted ammonium alkyl group. 4. ^{R 1, R 2, R 3} , R 4 are independently H, C ₁ -C _6, alkyl, aminoalkyl, methyl or dimethylamino alkyl, or a methyl, dimethyl, or trimethylammonio alkyl, claim 3 Composition. 5. R ¹ is H, CH ₃ , R ² is H, CH ₃ , C ₂ H ₅ , CH ₂ CH ₂ N (CH ₃ ) ₂ , R ³ is H, CH ₃ , and R ⁴ is _{CH 3, C 2 H 5,} C 3 H 7, C 4 H 9, CH 2 CH 2 N (CH 3) 3 X - a is, X ^- is an anion of any monovalent, according to claim 4 Composition. 6. 3. The composition of claim 2, wherein the water-soluble polymer is a terpolymer of butyl methacrylate, (2-dimethylaminoethyl) methacrylate, and methyl methacrylate in a relative ratio of 1: 2: 1. 7. The composition of claim 1, wherein said water-soluble polymer has a pH-sensitive solubility in an aqueous medium. 8. The composition of claim 7, wherein the water-soluble polymer is soluble in an aqueous medium having a pH of about 1 to about 10. 9. 9. The composition of claim 8, wherein said water-soluble polymer is soluble in an aqueous medium at acidic pH. Ten. 2. The composition of claim 1, wherein said bioactive agent is selected from an antifungal, an anti-inflammatory, an anti-hypertensive, an antimicrobial, a steroid, a hormone, a prostaglandin, an interferon, and mixtures thereof. 11． 2. The composition of claim 1, wherein said bioactive agent is substantially insoluble in an aqueous environment. 12． 2. The composition of claim 1, wherein said composition meets or exceeds USP dissolution criteria for a bioactive agent. 13. The composition of claim 1, wherein the solid dispersion is provided by flash-flowing a raw material comprising the bioactive agent and the polymer. 14. 14. The composition of claim 13, wherein said flash flow treatment is a flash heat treatment. 15. The composition of claim 14, wherein said bioactive agent is heat sensitive. 16． 14. The composition of claim 13, wherein said flash flow treatment is a flash shear treatment. 17． The composition of claim 1, wherein the dispersion is provided by extruding and mixing for a time sufficient to produce the solid dispersion. 18． 18. The composition of claim 17, wherein said time is less than about 2 minutes. 19. 19. The composition of claim 18, wherein said time is less than about 30 seconds. 20. 18. The composition of claim 17, wherein said bioactive agent is an antifungal, anti-inflammatory, or anti-hypertensive agent. twenty one. The composition of claim 1, wherein the bioactive agent is dispersed in the water-soluble polymer as nanoparticles with an average particle size of less than about 1000 nm. twenty two. 22. The composition of claim 21, wherein said average particle size is less than about 400 nm. twenty three. 2. The composition of claim 1, wherein said bioactive agent is dispersed at a molecular level in said water-soluble polymer. twenty four. 2. The composition of claim 1, wherein the composition is controlled release microparticles prepared by mechanically grinding the solid dispersion. twenty five. 25. The composition of claim 24, wherein said microparticle is part of a dosage unit. 26. 26. The composition of claim 25, wherein said dosage unit is selected from the group consisting of a capsule, a tablet and a rapidly dissolving tablet. 27. The composition of claim 1, wherein the solid dispersion is processed for fixation to an intravascular delivery device. 28. 2. The composition of claim 1, wherein the solid dispersion is engineered to provide a suppository, troche, or other slowly dissolving delivery structure. 29. 2. The composition of claim 1, wherein said solid dispersed phase has been processed to provide a tablet. 30. The bioactive agent is transformed into an increased energy state in a water-soluble polymer having a glass transition temperature of about 0 ° C. to about 200 ° C., fixing the drug in the state, thereby solid dispersion of the drug in the polymer. A method of conditioning a system for delivering a bioactive agent to a biological system, comprising forming a body and making the agent bioavailable in an aqueous environment. 31. 31. The composition of claim 30, wherein said water-soluble polymer is a polymethacrylic acid polymer. 32. 32. The method of claim 31, wherein said polymethacrylic acid polymer has the following structure: Here, R ¹ , R ² , R ³ , and R ⁴ are each independently hydrogen (H) or any alkyl, aryl, alkaryl, aralkyl, aminoalkyl, alkyl-substituted aminoalkyl, ammonium alkyl, or alkyl A substituted ammonioalkyl group. 33. ^{R 1, R 2, R 3} , R 4 are independently H, C ₁ -C ₆ alkyl, amino alkyl, methyl or dimethylamino alkyl, or methyl, dimethyl, or trimethylammonio alkyl, The method of claim 32 . 34. R ¹ is H, CH ₃ , R ² is H, CH ₃ , C ₂ H ₅ , CH ₂ CH ₂ N (CH ₃ ) ₂ , R ³ is H, CH ₃ , and R ⁴ is _{CH 3, C 2 H 5,} C 3 H 7, C 4 H 9, CH 2 CH 2 N (CH 3) 3 + X - a is, X ^- is an anion of any monovalent, claim 33 the method of. 35. 32. The method of claim 31, wherein the water-soluble polymer is a terpolymer of butyl methacrylate (2-dimethylaminoethyl) methacrylate and methyl methacrylate in a relative ratio of 1: 2: 1. 36. The method of claim 31, wherein the water-soluble polymer has a pH-sensitive solubility in an aqueous medium. 37. 37. The method of claim 36, wherein said water-soluble polymer is soluble in an aqueous medium having a pH of about 1 to 10. 38. 38. The method of claim 37, wherein said water-soluble polymer is soluble in aqueous media at acidic pH. 39. 31. The method of claim 30, wherein the non-soluble agent is selected from the group consisting of antifungal agents, anti-inflammatory agents, anti-hypertensive agents, antibacterial agents, steroids, hormones, prostaglandins or interferons, and mixtures thereof. Method. 40. 31. The method of claim 30, wherein said bioactive agent is substantially insoluble in an aqueous medium. 41. 31. The method of claim 30, wherein said simultaneous conversion fixation is performed by a flash flow process. 42. 42. The method of claim 41, wherein said flash flow process is a flash heat process. 43. 43. The method of claim 42, wherein said bioactive agent is heat sensitive. 44. 42. The method of claim 41, wherein said flash flow process is a flash shear process. 45. 31. The method of claim 30, wherein said co-conversion fixation is performed by extrusion mixing for a time sufficient to form said solid dispersion. 46. 46. The method of claim 45, wherein said time is less than about 2 minutes. 47. 47. The method of claim 46, wherein said time is less than about 30 seconds. 48. 46. The method of claim 45, wherein said bioactive agent is an antifungal, anti-inflammatory, or anti-hypertensive agent. 49. Wherein the conversion to the increased energy state comprises milling the bioactive agent into nanoparticles that are dispersed in the water-soluble polymer without mechanical friction, wherein the average particle size of the nanoparticles is less than 1000 nm. The method of claim 30. 50. 49. The method of claim 48, wherein said average particle size is less than 400 nm. 51. 31. The method of claim 30, wherein said converting to the increased energy state comprises, without mechanical friction, converting the bioactive agent into a molecule that is dispersed in the water-soluble polymer. 52. 31. The method of claim 30, further comprising mechanically micronising said solid dispersion. 53. 53. The method of claim 52, further comprising incorporating the microparticle into a dosage unit. 54. 53. The method of claim 52, wherein said entrapment comprises entrapping said microparticles in a capsule. 55. 55. The method of claim 54, wherein said incorporation comprises forming a fast dissolving tablet. 56. 31. The method of claim 30, further comprising sizing and molding to secure the solid dispersion to an intravascular fluid delivery device. 57. a) a carrier comprising a water-soluble polymer having a glass transition temperature of about 0 ° C. to about 200 ° C .; and b) a bioactive agent microscopically dispersed in said water-soluble polymer. Composition. 58. 58. The composition of claim 57, wherein the water-soluble polymer has a pH-sensitive solubility in an aqueous medium. 59. 59. The composition of claim 58, wherein said water-soluble polymer is substantially insoluble in saliva but soluble in gastric juice. 60. 58. The composition of claim 57, wherein said bioactive agent is dispersed in said water-soluble polymer as nanoparticles having an average particle size of less than 1000 nm. 61. 61. The composition of claim 60, wherein said bioactive agent is dispersed in said water-soluble polymer as nanoparticles having an average particle size of less than 400 nm. 62. 58. The composition of claim 57, wherein said bioactive agent is dispersed in said water soluble polymer. 63. A method for delivering a bioactive agent to a biological system, the method comprising fixing the solid dispersion to an increased energy state in a water-soluble polymer having a glass transition temperature of about 0 ° C. to about 200 ° C. Administering the bioactive agent to the biological system, wherein the bioactive agent is bioavailable to the biological system.