In Vitro Characterization of a Novel Polymeric System for Preparation of Amorphous Solid Drug Dispersions

Preparation of amorphous solid dispersions using polymers is a commonly used formulation strategy for enhancing the solubility of poorly water-soluble drugs. However, often a single polymer may not bring about a significant enhancement in solubility or amorphous stability of a poorly water-soluble drug. This study describes application of a unique and novel binary polymeric blend in preparation of solid dispersions. The objective of this study was to investigate amorphous solid dispersions of glipizide, a BCS class II model drug, in a binary polymeric system of polyvinyl acetate phthalate (PVAP) and hypromellose (hydroxypropyl methylcellulose, HPMC). The solid dispersions were prepared using two different solvent methods: rotary evaporation (rotavap) and fluid bed drug layering on sugar spheres. The performance and physical stability of the dispersions were evaluated with non-sink dissolution testing, powder X-ray diffraction (PXRD), and modulated differential scanning calorimetry (mDSC). PXRD analysis demonstrated an amorphous state for glipizide, and mDSC showed no evidence of phase separation. Non-sink dissolution testing in pH 7.5 phosphate buffer indicated more than twofold increase in apparent solubility of the drug with PVAP–HPMC system. The glipizide solid dispersions demonstrated a high glass transition temperature (T _g) and acceptable chemical and physical stability during the stability period irrespective of the manufacturing process. In conclusion, the polymeric blend of PVAP–HPMC offers a unique formulation approach for developing amorphous solid dispersions with the flexibility towards the use of these polymers in different ratios and combined quantities depending on drug properties.     

Preparation and characterization of emulsified solid dispersions containing docetaxel

An emulsified solid dispersion of docetaxel was prepared and characterized in vitro. In contrast to conventional solid dispersions, emulsifying pharmaceutical excipients and hydroxypropyl methylcellulose (HPMC) as a supersaturation promoter were introduced into the PEG6000-based solid dispersion to further improve its solubilizing capability. The solubility, dissolution in vitro and stability of the prepared emulsified solid dispersions were studied taking into consideration of the effects of different emulsifying excipients, preparation methods and the media. Results of the emulsified solid dispersion of docetaxel showed that the solubility and dissolution at 2 h were 34.2- and 12.7-fold higher than the crude powder. The type of emulsifying excipient used had a significant influence on the dissolution of the emulsified solid dispersion. The dissolution of the emulsified solid dispersion prepared by the solvent-melting method or the solvent method was higher than the melting method. There were no apparent differences among the dissolution media utilized. The status of the drug in the emulsified solid dispersion was observed in an amorphous or a molecular dispersion state by differential thermal analysis and powder Xray diffraction. In conclusion, the incorporation of emulsifying pharmaceutical excipients and HPMC with polymers into a solid dispersion could be a new and useful tool to greatly increase the solubility and dissolution of poorly water-soluble drugs.     

Development and Characterization of a Scalable Controlled Precipitation Process to Enhance the Dissolution of Poorly Water-Soluble Drugs

PURPOSE: Poorly water-soluble compounds are being found with increasing frequency among pharmacologically active new chemical entities, which is a major concern to the pharmaceutical industry. Some particle engineering technologies have been shown to enhance the dissolution of many promising new compounds that perform poorly in formulation and clinical studies (Rogers et. al., Drug Dev Ind Pharm 27:1003-1015). One novel technology, controlled precipitation, shows significant potential for enhancing the dissolution of poorly soluble compounds. In this study, controlled precipitation is introduced; and process variables, such as mixing zone temperature, are investigated. Finally, scale-up of controlled precipitation from milligram or gram to kilogram quantities is demonstrated. METHODS: Dissolution enhancement capabilities were established using two poorly water-soluble model drugs, danazol and naproxen. Stabilized drug particles from controlled precipitation were compared to milled, physical blend, and bulk drug controls using particle size analysis (Coulter), X-ray powder diffraction (XRD), scanning electron microscopy (SEM), dissolution testing (USP Apparatus 2), and residual solvent analysis. RESULTS: Stabilized nano- and microparticles were produced from controlled precipitation. XRD and SEM analyses confirmed that the drug particles were crystalline. Furthermore, the stabilized particles from controlled precipitation exhibited significantly enhanced dissolution properties. Residual solvent levels were below FDA limits. CONCLUSIONS: Controlled precipitation is a viable and scalable technology that can be used to enhance the dissolution of poorly water-soluble pharmaceutical compounds.     

Effect of biocompatible polymers on the physicochemical and dissolution properties of fenofibrate in nanoparticle system

This study aimed to evaluate the effect of biocompatible polymers on the physicochemical and dissolution properties of poorly water-soluble drugs in nanoparticle systems. Four types of nanoparticles containing poorly water-soluble fenofibrate were prepared using solvent evaporation technique with different biocompatible polymers such as polyvinylpyrrolidone (PVP), hydroxypropylmethyl cellulose (HPMC), carbopol and ethylcellulose. Their physicochemical properties were investigated using scanning electron microscopy, differential scanning calorimetry, and powder X-ray diffraction. The solubility and dissolution of nanoparticle-entrapped fenofibrate were compared with those of free drug powder. Biocompatible polymers affected the morphology and sizes of fenofibrate nanoparticles. PVP or carbopol-based nanoparticles showed spherical appearance, whereas HPMC or ethylcellulose-based nanoparticles formed aggregates with irregular shape. The particle sizes increased in the order of the nanoparticle prepared with carbopol ≤ PVP < HPMC < ethylcellulose. The size of PVP-based nanoparticles did not significantly differ from that of carbopol-based nanoparticles, showing the mean sizes of ca. 10 μm. As compared to free drug powder, the solubility and dissolution of the drug in nanoparticles increased in the order of PVP > HPMC > carbopol > ethylcellulose. The enhanced solubility and dissolution of poorly water-soluble fenofibrate via nanoparticle system did not depend on particle size but on crystallinity. In conclusion, in nanoparticle development of poorly water-soluble drugs such as fenofibrate, the nature of biocompatible polymers plays an important role in the physicochemical and dissolution of poorly water-soluble drugs in the nanoparticles.     

Reducing dust and improving granule and tablet quality in the roller compaction process

The dramatic reduction of non-compacted material during roller compaction and an important improvement of the granule and tablet qualities were obtained by a controlled wetting process before the roller compaction. The continuity of the roller compaction process was maintained by using a continuous fluid bed system. Due to a controlled water addition, a better binder distribution was obtained than when using micronised dry binders. When dry compacting poorly water soluble hydrochlorothiazide mixtures, the resultant dissolution rate was not influenced by the HPMC binder viscosity. When moistened blends were compacted, the resultant dissolution rate decreased with increasing HPMC binder viscosity. The roller compaction pressure had almost no influence on the drug dissolution rate. The addition of disintegrants did not improve the dissolution rate. When a fraction of the filler α-lactose monohydrate was replaced by microcrystalline cellulose, the dissolution rate increased with an increasing microcrystalline cellulose fraction. With the addition of 0.5% Tween® 80 to a formulation containing 25% microcrystalline cellulose and 50% α-lactose monohydrate, the dissolution rate increased and an immediate release tablet formulation was obtained. The presence of microcrystalline cellulose also improved the processing and avoided lump formation.     

Effect of the melt granulation technique on the dissolution characteristics of griseofulvin

This work describes a melt granulation technique to improve the dissolution characteristics of a poorly water-soluble drug, griseofulvin. Melt granulation technique is a process by which pharmaceutical powders are efficiently agglomerated by a meltable binder. The advantage of this technique compared to a conventional granulation is that no water or organic solvents is needed. Because there is no drying step, the process is less time consuming and uses less energy than wet granulation. Granules were prepared in a lab scale high shear mixer, using a jacket temperature of 60 degrees C and an impeller speed of approximately 20,000 rpm. The effect of drug loading (2.5/5%), binder (PEG 3350/Gelucire 44/14), filler (starch/lactose), and HPMC on the dissolution of griseofulvin was investigated using a half two level-four factor factorial design. The granules were characterized using powder XRD, DSC and SEM techniques. A significant enhancement in the in vitro dissolution profiles of the granules was observed compared to the pure drug and drug excipient physical mixtures. The factorial design results indicated that higher drug loading and the presence of HPMC reduced the extent of dissolution of the drug, whereas, the presence of starch enhanced the dissolution rate. XRD data confirmed crystalline drug in formulation matrices. DSC results indicated monotectic mixtures of griseofulvin with PEG in the granulated formulations. In conclusion, the results of this work suggest that melt granulation is a useful technique to enhance the dissolution rate of poorly water-soluble drugs, such as, griseofulvin.     

Incorporation of surface-modified dry micronized poorly water-soluble drug powders into polymer strip films

Recent work has established polymer strip films as a robust platform for delivery of poorly water-soluble drugs via slurry casting, in particular using stable drug nanosuspensions. Here, a simpler, robust method to directly incorporate dry micronized poorly water-soluble drug, fenofibrate (FNB), is introduced. As a major novelty, simultaneous surface modification using hydrophilic silica along with micronization was done using fluid energy mill (FEM) in order to reduce FNB hydrophobicity and powder agglomeration. It is hypothesized that silica coating promotes easy, uniform dispersion of micronized and coated FNB (MC-FNB) during direct mixing with aqueous hydroxypropyl methylcellulose (HPMC-E15LV) and glycerin solutions. Uniform dispersion leads to improved film critical quality attributes (CQAs) such as appearance, drug content uniformity and drug dissolution. The impact of polymer solution viscosity (low and high), mixer type (low versus high shear), and FNB surface modification on film CQAs were also assessed. Films with as-received FNB (AR-FNB) and micronized uncoated FNB (MU-FNB) were prepared as control. When MC-FNB powders were used, films exhibited improved appearance (thickness uniformity, visible lumps/agglomerates), better drug content uniformity (expressed as relative standard deviation), fast and immediate drug release, and enhanced mechanical properties (tensile strength, elongation percentage), regardless of the polymer solution viscosity or mixer type. These results compare favorably with those reported using nanosuspensions of FNB, establishing the feasibility of directly incorporating surface modified-micronized poorly water-soluble drug powders in film manufacturing.     

Controlled and complete release of a model poorly water-soluble drug, prednisolone, from hydroxypropyl methylcellulose matrix tablets using (SBE)(7m)-beta-cyclodextrin as a solubilizing agent.

Sustained-release formulations such as hydroxypropyl methylcellulose (HPMC)-based hydrophilic matrix tablets of poorly water-soluble drugs often result in incomplete release because of the poor solubility and dissolution rate of the drug in the hydrophilic matrix. Sulfobutylether-beta-cyclodextrins ((SBE)(7M)-beta-CDs) have been known to improve the solubility of such drugs by forming inclusion complexes. The present paper deals with the modification of drug release from an HPMC-based matrix tablet of a sparingly water-soluble drug, prednisolone (PDL), using (SBE)(7M)-beta-CD as a solubilizing agent. Tablets were prepared by direct compression of a physically mixed PDL, (SBE)(7M)-beta-CD, and polymer. On exposure to water, an in situ PDL:(SBE)(7M)-beta-CD complex was formed in the gel layer, and enhanced drug release relative to a control formulation was observed (lactose used as the excipient instead of (SBE)(7M)-beta-CD ). Other possible changes due to the incorporation of (SBE)(7M)-beta-CD in the formulation were also probed. Incorporation of (SBE)(7M)-beta-CD lead to a higher water uptake relative to the control (lactose) formulation. For a fixed total tablet weight, polymer type, and loading, the drug release rate appeared to depend on the molar ratio of (SBE)(7M)-beta-CD to PDL and not the absolute amount of (SBE)(7M)-beta-CD present in the matrix tablet. This work shows that incorporation of (SBE)(7M)-beta-CD into the matrix tablets could be considered in designing a sustained-release tablet of poorly water-soluble drugs.     

Counter-intuitive enhancement in the dissolution of indomethacin with the incorporation of cohesive poorly water-soluble inorganic salt additives

The objective of this work was to investigate the influence of various micronized poorly water-soluble inorganic materials on the dissolution and de-agglomeration behaviour of a micronized, poorly water-soluble model drug, indomethacin, from lactose interactive mixtures. Dissolution of indomethacin was studied using the USP paddle method and the data were modelled with multi-exponential equations using a nonlinear least squares algorithm in order to obtain key parameter estimates. The dispersion of indomethacin mixtures was measured by laser diffraction. The addition of aluminium hydroxide and calcium phosphate to binary mixtures of indomethacin counter-intuitively improved the dissolution rate of indomethacin due to significant increases in both the estimated initial concentration and dissolution rate constant of dispersed particles of indomethacin. While some enhancement was due to pH changes in the dissolution medium, the presence of these poorly water-soluble inorganic salts caused de-agglomeration. Average particle size distributions indicated that the presence of aluminium hydroxide within the matrix of indomethacin had reduced the agglomerate concentration whilst increasing the dispersed particle concentration. These findings provide the first evidence of the ability of poorly water-soluble inorganic salts to enhance the de-agglomeration and dissolution of micronized powders, potentially translating to improved bioavailability of poorly water-soluble drugs.     

Dissolution of poorly water-soluble drugs in biphasic media using USP 4 and fiber optic system

A novel in-vitro dissolution system based on the principle of flow-through technique has been designed to evaluate the in-vitro release rate of poorly water-soluble compounds. The flow through apparatus (USP 4) has been coupled with the compendial dissolution apparatus (USP apparatus 2). A bi-phasic dissolution medium is used to achieve sink conditions. The dissolved drug is continuously removed from the aqueous phase into the organic phase of the dissolution medium, mimicking the process of absorption in the systemic circulation. The in vitro release profiles obtained from this dissolution model was able to distinguish the formulation changes of several poorly water-soluble drugs from their dosage forms. For AMG 517, the model drug, excellent rank order correlation has been obtained between the in-vitro release and the in-vivo absorption of the drug from several different dosage forms and their formulations. In addition, for several commercial formulations, the model successfully discriminated between the bioequivalent and non-bioequivalent formulations.     

Incorporation of Fenofibrate Nanoparticles Prepared by Melt Emulsification into Polymeric Films

The aims of this study are to develop polymeric films loaded with nanoparticles of fenofibrate (FNB), a poorly water-soluble drug, prepared via melt emulsification (ME) and study the short-term physical stability of the ME-based suspensions, with the ultimate goal of enhancing FNB dissolution. FNB particles in water were heated above the melting point to form an oil-in-water emulsion, whose cooling turned FNB droplets into solidified FNB nanoparticles. The resulting FNB suspensions, along with a suspension of as-received FNB, were mixed with hydroxypropyl methylcellulose (HPMC)–glycerin solution to prepare film precursor suspensions, which were then casted and dried into films. The effects of the presence of Pluronic F68 (PF68) as stabilizer and the sonication during the cooling step on the physical stability of the suspensions were investigated. For films, drug content, redispersibility, and drug release in a USP IV dissolution test were studied. The results show that cooling the FNB–PF68 emulsion in the presence of sonication produced suspensions with acceptable 7-day physical stability, whereas cooling the same without sonication led to severe particle aggregation within 20 min. The film redispersion in water led to effective recovery of FNB nanoparticles only when PF68 and sonication during the cooling step were used. Good drug content uniformity and enhanced FNB dissolution were obtained from the films containing FNB nanoparticles stabilized with PF68, but the impact of sonication on the FNB dissolution was not discernible. Overall, feasibility of films carrying ME-based drug nanoparticles for enhanced dissolution has been demonstrated.     

Release of poorly soluble drugs from HPMC tablets studied by FTIR imaging and flow-through dissolution tests

Spectroscopic imaging and a flow-through dissolution test have been combined to improve the possibilities of investigating the release of a poorly soluble drug (diclofenac) from pharmaceutical tablets. The presented methods aim to overcome the limitations that impede the conventional dissolution test because of its inability to observe precipitates of poorly soluble drug during tablet dissolution. The proposed flow-through set-up allows small drug particles that are being carried along in the water-flow to be analyzed, by adding a dissolution agent to the medium after it left the tablet cell. Fourier transform infrared-attenuated total reflection (FTIR-ATR) spectroscopic imaging provides an insight into the processes inside the tablet and is not hindered by insoluble or recrystallising drug. The techniques have been hyphenated and used to study tablets containing diclofenac sodium and HPMC (hydroxypropyl methylcellulose) in different dissolution media that influence the solubility of the drug. The release profiles obtained by flow-through dissolution test suggest the presence of particles (or precipitates) in the dissolution medium. This is consistent with the results obtained by FTIR imaging, which confirms that both proposed techniques are superior to the ordinary dissolution test when applied to poorly soluble drugs. FTIR imaging data have been analyzed by a classical least squares analysis, corrected for the parts of the tablet outside the field of view, and used to calculate the release profile. The infrared spectra of diclofenac at varying relative humidity were acquired to study the interactions of diclofenac and water, including identification of dissociated diclofenac, thus the chemical specificity of FTIR imaging was fully utilized.     

Enhanced Drug Dissolution and Bulk Properties of Solid Dispersions Granulated with a Surface Adsorbent

A combination of solid dispersion and surface adsorption techniques was used to enhance the dissolution of a poorly water-soluble drug, BAY 12-9566. In addition to dissolution enhancement, this method allows compression of the granulated dispersion into tablets. Gelucire 50/13 (polyglycolized glycerides) was used as the solid dispersion carrier. Hot-melt granulation was performed to adsorb the melt of the drug and Gelucire 50/13 onto the surface of Neusilin US2 (magnesium alumino silicate), the surface adsorbent. Dispersion granules using various ratios of drug–Gelucire 50/13–Neusilin US2 were thus prepared. The dissolution profiles of BAY 12-9566 from the dispersion granules and corresponding physical mixtures were evaluated using USP Type II apparatus at 75 rpm. The dissolution medium consisted of 0.1 N hydrochloric acid (HCl) with 1% w/v sodium lauryl sulfate (SLS). Dissolution of BAY 12-9566 from the dispersion granules was enhanced compared to the physical mixture. The dissolution of BAY 12-9566 increased as a function of increased Gelucire 50/13 and Neusilin US2 loading and decreased with increased drug loading. In contrast to the usually observed decrease in dissolution on storage, an enhancement in dissolution was observed for the dispersion granules stored at 40°C/75% relative humidity (RH) for 2 and 4 weeks. Additionally, the flow and compressibility properties of dispersion granules were improved significantly when compared to the drug alone or the corresponding physical mixture. The ternary dispersion granules were compressed easily into tablets with up to 30% w/w drug loading. The extent of dissolution of drug from these tablets was greater than that from the uncompressed dispersion granules.     

Enhanced drug dissolution and bulk properties of solid dispersions granulated with a surface adsorbent.

A combination of solid dispersion and surface adsorption techniques was used to enhance the dissolution of a poorly water-soluble drug, BAY 12-9566. In addition to dissolution enhancement, this method allows compression of the granulated dispersion into tablets. Gelucire 50/13 (polyglycolized glycerides) was used as the solid dispersion carrier. Hot-melt granulation was performed to adsorb the melt of the drug and Gelucire 50/13 onto the surface of Neusilin US2 (magnesium alumino silicate), the surface adsorbent. Dispersion granules using various ratios of drug-Gelucire 50/13-Neusilin US2 were thus prepared. The dissolution profiles of BAY 12-9566 from the dispersion granules and corresponding physical mixtures were evaluated using USP Type II apparatus at 75 rpm. The dissolution medium consisted of 0.1 N hydrochloric acid (HCl) with 1% w/v sodium lauryl sulfate (SLS). Dissolution of BAY 12-9566 from the dispersion granules was enhanced compared to the physical mixture. The dissolution of BAY 12-9566 increased as a function of increased Gelucire 50/13 and Neusilin US2 loading and decreased with increased drug loading. In contrast to the usually observed decrease in dissolution on storage, an enhancement in dissolution was observed for the dispersion granules stored at 40 degrees C/75% relative humidity (RH) for 2 and 4 weeks. Additionally, the flow and compressibility properties of dispersion granules were improved significantly when compared to the drug alone or the corresponding physical mixture. The ternary dispersion granules were compressed easily into tablets with up to 30% w/w drug loading. The extent of dissolution of drug from these tablets was greater than that from the uncompressed dispersion granules.     

Effect of varying the restriction degree of 4-aminopyridine release from HPMC matrices on the mechanism controlling the process

Among different technological variables that influence drug release from hydrophilic matrices, different proportions of the polymer and a water-soluble excipient have been used to control the drug release properties. These variables were used to modify the drug release rate and to examine its effect on the mechanism controlling the process. Tablets of the model drug 4-aminopyridine (4-AP) were prepared varying the matrix proportion of hydroxypropyl methylcellulose (HPMC) and citric acid (CA). The matrices release behavior (USP apparatus 2, paddle, at 50 rpm) was examined using 0.1N HCl and 0.2M phosphate buffer as dissolution media. Dissolution curves were described by M(t)/M(inf)=kt(n), applied separately for each dissolution medium. The increase of the HPMC matrix content reduced the release rate of the drug. The release mechanism showed a linear trend toward higher n values with a continuous reduction of drug release. The addition of increasing proportions of CA produced the opposite. An increasing drug release rate produced logarithmic decreasing n values. The results demonstrate, as a general rule, that every restriction of the drug release rate is associated with increasing values of the mechanism-indicating exponent n. This relationship means a logarithmic movement away from a release mechanism controlled by diffusion toward a mechanism controlled by relaxation, erosion and dissolution of the polymeric matrix as the drug release rate is restricted. These results are attributed to an increasing hydration and dissolution of the polymeric matrix, as the drug release is subject to limitation.     

Understanding and Managing the Impact of HPMC Variability on Drug Release from Controlled Release Formulations

The purpose of this study is to identify critical physicochemical properties of hydroxypropyl methylcellulose (HPMC) that impact the dissolution of a controlled release tablet and develop a strategy to mitigate the HPMC lot-to-lot and vendor-to-vendor variability. A screening experiment was performed to evaluate the impacts of methoxy/hydroxypropyl substitutions, and viscosity on drug release. The chemical diversity of HPMC was explored by nuclear magnetic resonance (NMR), and the erosion rate of HPMC was investigated using various dissolution apparatuses. Statistical evaluation suggested that the hydroxypropyl content was the primary factor impacting the drug release. However, the statistical model prediction was not robust. NMR experiments suggested the existence of structural diversity of HPMC between lots and more significantly between vendors. Review of drug release from hydrophilic matrices indicated that erosion is a key aspect for both poorly soluble and soluble drugs. An erosion rate method was then developed, which enabled the establishment of a robust model and a meaningful HPMC specification. The study revealed that the overall substitution level is not the unique parameter that dictates its release-controlling properties. Fundamental principles of polymer chemistry and dissolution mechanisms are important in the development and manufacturing of hydrophilic matrices with consistent dissolution performance. © 2014 Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 103:1664–1672, 2014     

In vivo evaluation of tablets and capsules containing spray-dried o/w-emulsions for oral delivery of poorly soluble drugs

It is recognised that poorly soluble drugs may show an increased oral bioavailability when incorporated in o/w-emulsions. Encapsulating the emulsion lipid droplets in hydroxypropyl methylcellulose (HPMC) by spray drying has been demonstrated to preserve an improved bioavailability releasing lipid droplets from the powder in vivo. However, the spray-dried powder is cohesive and bulky requiring additional processing to improve handling. This was resolved in previous work where a directly compressible dry emulsion formulation was described. The purpose of the present study is to investigate the oral bioavailability resulting from administration of a directly compressible dry emulsion as a tablet and compare it with a HPMC dry emulsion powder and a simple lipid solution. Four female Beagle dogs received a single dose of each formulation containing the same amount of medium-chain triglycerides (MCT) and a model drug, Lu 28-179. Cyclodextrin solutions administered orally and intravenously were used as references. The absolute bioavailability decreased in the order cyclodextrin solution (0.14), HPMC dry emulsion (0.11), technically improved dry emulsion (0.10) and MCT solution (0.06). The directly compressible dry emulsion tablets were concluded to be comparable to a HPMC dry emulsion powder in terms of bioavailability. The lack of statistically significant differences relative to a MCT solution was ascribed to a low and variable absolute oral bioavailability of the model drug.     

Development of a single unit extended release formulation for ZK 811 752, a weakly basic drug.

ZK 811 752, a potent candidate for the treatment of autoimmune diseases, demonstrated pH-dependent solubility. The resulting release from conventional matrix tablets decreased with increasing pH-values of the dissolution medium. The aim of this study was to overcome this problem and to achieve pH-independent drug release. Three different polymers were used as matrix formers, the partly water-soluble and poorly swellable mixture of polyvinylacetate/polyvinylpyrrolidone, the water-insoluble and almost unswellable ethylcellulose (EC) and the water-soluble and highly swellable hydroxypropyl methylcellulose (HPMC). To solve the problem of pH-dependent solubility different organic acids, such as fumaric, tartaric, adipic, glutaric and sorbic acid were added to the drug-polymer system. The addition of organic acids to all three matrix formers was found to maintain low pH-values within the tablets during release of ZK 811 752 in phosphate buffer pH 6.8. Thus, the micro-environmental conditions for the dissolution of the weakly basic drug were kept almost constant. An extended release matrix tablet for ZK 811 752 consisting of drug, polymer and organic acid providing the desired pH-independent drug release has been developed.     

干法制粒中黏合剂的比较

目的 比较干法制粒压片工艺中粘合剂的表现。方法 以盐酸二甲双胍和扑热息痛为模型药,分别以羟丙纤维素(hydroxypropylScellulose,HPC),共聚维酮(copovidone,PVP/VA),羟丙甲纤维素(hypromellose,HPMC),聚维酮(povidone,PVP)和乙基纤维素(ethyl cellulose,EC)为粘合剂干法制粒并压片,测定颗粒密度,流动性和粒径分布,片剂硬度、脆碎度和体外溶出度等。结果 对于盐酸二甲双胍和扑热息痛这两种药物,羟丙纤维素均能制得机械性能最佳的片剂,共聚维酮也表现较好。结论 羟丙纤维素是较适合干法制粒压片工艺的优异粘合剂。     

Inhibition of Crystal Nucleation and Growth by Water-Soluble Polymers and its Impact on the Supersaturation Profiles of Amorphous Drugs

The impact of water-soluble polymers on drug supersaturation behavior was investigated to elucidate the role of water-soluble polymers in enhancing the supersaturation levels of amorphous pharmaceuticals. Hydroxypropyl methylcellulose (HPMC), polyvinylpyrrolidone (PVP), and Eudragit L-100 (Eudragit) were used as representative polymers, and griseofulvin and danazol were used as model drugs. Supersaturation profiles of amorphous drugs were measured in biorelevant dissolution tests. Crystal growth rate was measured from the decrease in dissolved drug concentration in the presence of seed crystals. Nucleation kinetics was evaluated by measuring the induction time for nucleation. All experiments were performed in the presence and absence of polymers. The degree of supersaturation of the amorphous model drugs increased with an increase in the inhibitory efficiency of polymers against crystal nucleation and growth (HPMC > PVP > Eudragit). In the presence of HPMC, the addition of seed crystals diminished the supersaturation ratio dramatically for griseofulvin and moderately for danazol. The results demonstrated that the polymers contributed to drug supersaturation by inhibiting both nucleation and growth. The effect of the polymers was drug dependent. The detailed characterization of polymers would allow selection of appropriate crystallization inhibitors and a planned quality control strategy for the development of supersaturable formulations. © 2013 Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 102:2273–2281, 2013