Compression of Indomethacin Coprecipitates with Polymer Mixtures: Effect of Preparation Methodology

The objective of this study was to prepare, characterize, formulate and compare coprecipitates, solid dispersions and physical mixtures of indomethacin with Eudragit polymer mixtures, RS100 and L100. Coprecipitates, solid dispersions (melting-solvent method) and physical mixtures were prepared with a drug : polymer ratio of 12.6: 1.0 respectively. Biconvex tablets of 7 mm diameter were compressed. Response variables studied were cumulative percent released and T₅₀. Dissolution was performed by exposing the tablets to SGF (PH 1.2) for 1 hour followed by pH 7.2 phosphate buffer for 24 hours. T₅₀ values obtained were 7.5 hours for coprecipitates, 4.5 hours for solid dispersions and 17 hours for physical mixtures. The drug loading for all the three formulations did not show significant difference. The formulations were characterized by X-ray diffraction (qualitative and quantitative) and IR. IR data did not indicate any significant difference between the pure drug and the formulations. However, significant differences were seen in X-ray diffractograms. The crystallinity did not change for physical mixtures, was reduced for coprecipitates and solid dispersions. Also the diffraction patterns for solid dispersions and coprecipitates were similar. The coprecipitates and physical mixture followed the Higuchi's square-root-of-time equation suggesting a matrix effect. These results suggest that compression of coprecipitates offer most efficient release as compared to solid dispersions and physical mixtures.     

Properties of Solid Dispersions of Naproxen in Various Polyethylene Glycols

Abstract

Solid dispersions of naproxen in polyethylene glycol 4000, 6000, and 20000, aimed at improving the drug dissolution characteristics, were prepared by both the solvent and melting methods. The drug-polymer interaction in the solid state was investigated using differential scanning calorimetry, hot-stage microscopy, Fourier-transform infrared spectroscopy, and x-ray diffraction analysis. Interaction in solution was studied by phase solubility analysis and dissolution experiments. Computer-aided molecular modeling was used to supplement the results from phase solubility studies. No important chemical interaction was found between naproxen and polyethylene glycol, either in solution or in the solid state, apart from the formation of weak drug-polymer hydrogen bonds. The increase of naproxen dissolution rate from its binary systems with polyethylene glycol could be attributed to several factors such as improved wettability, local solubilization, and drug particle size reduction. No influence of polymer molecular weight or of the solid dispersion preparation method on drug dissolution properties was found.     

Properties of Solid Dispersions of Naproxen in Various Polyethylene Glycols

Solid dispersions of naproxen in polyethylene glycol 4000, 6000, and 20000, aimed at improving the drug dissolution characteristics, were prepared by both the solvent and melting methods. The drug-polymer interaction in the solid state was investigated using differential scanning calorimetry, hot-stage microscopy, Fourier-transform infrared spectroscopy, and x-ray diffraction analysis. Interaction in solution was studied by phase solubility analysis and dissolution experiments. Computer-aided molecular modeling was used to supplement the results from phase solubility studies. No important chemical interaction was found between naproxen and polyethylene glycol, either in solution or in the solid state, apart from the formation of weak drug-polymer hydrogen bonds. The increase of naproxen dissolution rate from its binary systems with polyethylene glycol could be attributed to several factors such as improved wettability, local solubilization, and drug particle size reduction. No influence of polymer molecular weight or of the solid dispersion preparation method on drug dissolution properties was found.     

The Preparation and Stability of Fast Release Furosemide – PVP Solid Dispersion

Abstract

Furosemide-PVP solid dispersion systems were prepared by co-evaporation and freeze-drying methods. The X-ray diffraction patterns indicated that furosemide in the coprecipitates was in amorphous form. The dissolution rate of furosemide was markedly increased in these solid dispersion systems. The increase in dissolution was a function of the ratio of drug to PVP used. With 1:7 ratio the best result was obtained. The 49000 mol. wt. PVP yielded the most rapid furosemide dissolution. Dissolution studies have shown that coprecipitate of furosemide-PVP (1:7) is the best combination. Factors contributing to the enhancement of furosemide' dissolution from the dispersion in PVP were discussed. The increase in release rates was attributed to the increased wettability, coacervate formation and the complexation.

The effect of aging on furosemide-PVP solid dispersions has been investigated. After storage, under the different humidities (55%, 70% and 85% RH) coprecipitates showed no change in either dissolution rate or X-ray diffraction patterns.     

Evaluation of solid dispersions of Clofazimine

Clofazimine (CLF) was formulated with polyethylene glycol (PEG) and polyvinyl pyrrolidone (PVP) as a solid solid dispersion (SSD) to increase the aqueous solubility and dissolution rate of the drug. Different molecular weights of PEG (1500, 4000, 6000, and 9000 Da) and PVP (14,000 and 44,000 Da) were used in different drug:carrier weight ratios (1:1, 1:5, and 1:9) and their effect on the dissolution performance of the drug was evaluated in USP Type 2 apparatus using 0.1 N HCl medium. The dissolution rate was compared with corresponding physical mixtures, a currently marketed soft gelatin capsule product, and free CLF. The effect of different methods of preparation (solvent/melt) on the dissolution rate of CLF was evaluated for PEG solid dispersions. Saturation solubility and phase solubility studies were carried out to indicate drug:carrier interactions in liquid state. Infrared (IR) spectroscopy and X-ray diffraction (XRD) were used to indicate drug:carrier interactions in solid state. Improvement in the drug dissolution rate was observed in solid dispersion formulations as compared to the physical mixtures. The dissolution rate improved with the decreasing weight fraction of the drug in the formulation. Polyvinyl pyrrolidone solid dispersion systems gave a better drug release profile as compared to the corresponding PEG solid dispersions. The effect of molecular weight of the PEG polymers did not follow a definite trend, while PVP 14,000 gave a better dissolution profile as compared to PVP 44,000. Improvement in saturation solubility of the drug in the solid dispersion systems was noted in all cases. Further, IR spectroscopy indicated drug:carrier interactions in solid state in one case and XRD indicated reduction in the crystallinity of CLF in another. It was concluded that solid-dispersion formulations of Clofazimine can be used to design a solid dosage form of the drug, which would have significant advantages over the currently marketed soft gelatin capsule dosage form.     

In vitro and in vivo studies on a novel solid dispersion of repaglinide using polyvinylpyrrolidone as the carrier

In order to improve the dissolution and absorption of the water insoluble drug repaglinide, a solid dispersion was developed by solvent method using polyvinylpyrrolidone K30 (PVP K30) as the hydrophilic carrier for the first time. Studies indicated that both solubility and the dissolution rate of repaglinide were significantly increased in the solid dispersion system compared with that of repaglinide raw material or physical mixtures. The repaglinide solid dispersions with PVP K30 solid state was characterized by polarizing microscopy, differential scanning calorimetry (DSC), X-ray diffraction (XRD), and Fourier transform infrared spectroscopy (FT-IR). DSC and XRD studies indicated that repaglinide existed in an amorphous form in the solid dispersion. FT-IR analysis demonstrated the presence of intermolecular hydrogen bonding between repaglinide and PVP K30 in the solid dispersion. In the in situ gastrointestinal perfusion experiment, solid dispersion was shown to remarkably enhance the absorption of repaglinide in stomach and all segments of intestine. In vivo pharmacokinetic study in rats showed that immediate and complete release of repaglinide from the solid dispersion resulted in rapid absorption that significantly increased the bioavailability and the maximum plasma concentration over repaglinide raw material. These results demonstrated PVP K30 was an appropriate carrier for solid dispersion of repaglinide, with increased dissolution and oral absorption.     

In vitro and in vivo studies on a novel solid dispersion of repaglinide using polyvinylpyrrolidone as the carrier

In order to improve the dissolution and absorption of the water insoluble drug repaglinide, a solid dispersion was developed by solvent method using polyvinylpyrrolidone K30 (PVP K30) as the hydrophilic carrier for the first time. Studies indicated that both solubility and the dissolution rate of repaglinide were significantly increased in the solid dispersion system compared with that of repaglinide raw material or physical mixtures. The repaglinide solid dispersions with PVP K30 solid state was characterized by polarizing microscopy, differential scanning calorimetry (DSC), X-ray diffraction (XRD), and Fourier transform infrared spectroscopy (FT-IR). DSC and XRD studies indicated that repaglinide existed in an amorphous form in the solid dispersion. FT-IR analysis demonstrated the presence of intermolecular hydrogen bonding between repaglinide and PVP K30 in the solid dispersion. In the in situ gastrointestinal perfusion experiment, solid dispersion was shown to remarkably enhance the absorption of repaglinide in stomach and all segments of intestine. In vivo pharmacokinetic study in rats showed that immediate and complete release of repaglinide from the solid dispersion resulted in rapid absorption that significantly increased the bioavailability and the maximum plasma concentration over repaglinide raw material. These results demonstrated PVP K30 was an appropriate carrier for solid dispersion of repaglinide, with increased dissolution and oral absorption.     

Evaluation of Solid Dispersions of Clofazimine

ABSTRACT

Clofazimine (CLF) was formulated with polyethylene glycol (PEG) and polyvinyl pyrrolidone (PVP) as a solid solid dispersion (SSD) to increase the aqueous solubility and dissolution rate of the drug. Different molecular weights of PEG (1500, 4000, 6000, and 9000 Da) and PVP (14,000 and 44,000 Da) were used in different drug:carrier weight ratios (1:1, 1:5, and 1:9) and their effect on the dissolution performance of the drug was evaluated in USP Type 2 apparatus using 0.1 N HCl medium. The dissolution rate was compared with corresponding physical mixtures, a currently marketed soft gelatin capsule product, and free CLF. The effect of different methods of preparation (solvent/melt) on the dissolution rate of CLF was evaluated for PEG solid dispersions. Saturation solubility and phase solubility studies were carried out to indicate drug:carrier interactions in liquid state. Infrared (IR) spectroscopy and X-ray diffraction (XRD) were used to indicate drug:carrier interactions in solid state. Improvement in the drug dissolution rate was observed in solid dispersion formulations as compared to the physical mixtures. The dissolution rate improved with the decreasing weight fraction of the drug in the formulation. Polyvinyl pyrrolidone solid dispersion systems gave a better drug release profile as compared to the corresponding PEG solid dispersions. The effect of molecular weight of the PEG polymers did not follow a definite trend, while PVP 14,000 gave a better dissolution profile as compared to PVP 44,000. Improvement in saturation solubility of the drug in the solid dispersion systems was noted in all cases. Further, IR spectroscopy indicated drug:carrier interactions in solid state in one case and XRD indicated reduction in the crystallinity of CLF in another. It was concluded that solid-dispersion formulations of Clofazimine can be used to design a solid dosage form of the drug, which would have significant advantages over the currently marketed soft gelatin capsule dosage form.     

Drug–polymer miscibility,interactions, and precipitation inhibition studies for the development of amorphous solid dispersions for the poorly soluble anticancer drug flutamide

The major goal of this research was to successfully formulate solid dispersion (SD) of the poorly soluble anticancer drug flutamide (FLT) using various hydrophilic polymers. Furthermore, to get more insight into SD, solid-state studies (miscibility and molecular interaction) were correlated with solution study (precipitation inhibition, dissolution). Hydrophilic polymers like PVP K90, HPMC, Eudragit EPO, and PEG 8000 were used at different drug-to-polymer w/w ratios. Solid-state miscibility studies were carried out using modulated differential scanning calorimetry (MDSC). SDs were prepared using solvent-evaporation technique and characterized by powder X-ray diffraction (PXRD) and MDSC. Infrared, Raman spectroscopy and molecular modeling were used to investigate drug-polymer interactions in the dispersions. Precipitation inhibition studies were carried out at various FLT-hydrophilic polymer ratios. Precipitation inhibition studies showed that PEG 8000 has the highest efficiency, followed by PVP K90, while HPMC and EPO showed no effect on precipitation inhibition. In the solid-state, MDSC of the physical mixture (PM) suggested that FLT is miscible to a greater extent with EPO and PEG 8000. Characterization of the amorphous dispersions using MDSC and PXRD concluded that FLT transformed from crystalline to amorphous form in the presence of PVP K90 and PEG 8000. Spectroscopic results confirmed stronger interaction of FLT with PVP K90 and PEG 8000, thereby confirming the in-solution precipitation and molecular modeling binding energy results. Amorphous dispersions formulated with PVP and PEG were stable and showed higher dissolution, an important property necessary to improve the physicochemical properties and drug delivery of poorly soluble anticancer drug FLT.     

Enhancement of the dissolution and permeation rates of meloxicam by formation of its freeze-dried solid dispersions in polyvinylpyrrolidone K-30

Freeze-drying (FD) and solvent evaporation (SE) were used to prepare solid dispersions (SDs) of meloxicam (MX) in polyvinylpyrrolidone K-30 (PVP). The SDs were prepared at different ratios, namely 1:1, 1:3, and 1:5 MX:PVP weight ratio. Differential scanning calorimetry (DSC), infrared absorption spectroscopy (IR), and x-ray powder diffractometry (XPD) were utilized to characterize the physicochemical properties of the SDs. Meloxicam (MX) in the solid dispersions appeared with less crystallinity form and was present in a complete amorphous form at higher PVP ratio. Dissolution rates of MX as a pure drug, physical mixtures (PMs), and SDs indicated a marked increase of the dissolution rate of MX in presence of PVP. The increase in the dissolution rate was dependent on the ratio of PVP and the method of preparation. In addition, the permeability of the drug through standard cellophane membrane and hairless mouse skin was also evaluated. The permeation rate of MX was significantly increased in the case of SDs and was dependent on the ratio of PVP. The results were primarily due to increase wettability, the solubilization of the drug by the carrier, and formation of MX amorphous form.     

Part II: bioavailability in beagle dogs of nimodipine solid dispersions prepared by hot-melt extrusion

The aim of the present work was to investigate the in vitro dissolution properties and oral bioavailability of three solid dispersions of nimodipine. The solid dispersions were compared with pure nimodipine, their physical mixtures, and the marketed drug product Nimotop. Nimodipine solid dispersions were prepared by a hot-melt extrusion process with hydroxypropyl methylcellulose (HPMC, Methocel E5), polyvinylpyrrolidone/vinyl acetate copolymer (PVP/VA, Plasdone S630), and ethyl acrylate, methyl methacrylate polymer (Eudragit EPO). Previous studies of XRPD and DSC data showed that the crystallinity was not observed in hot-melt extrudates, two T(g)s were observed in the 30% and 50% NMD-HPMC samples, indicating phase separation. The weakening and shift of the N-H stretching vibration of the secondary amine groups of nimodipine as determined by FT-IR proved hydrogen bonding between the drug and polymers in the solid dispersion. The dissolution profiles of the three dispersion systems showed that the release was improved compared with the unmanipulated drug. Drug plasma concentrations were determined by HPLC, and pharmacokinetic parameters were calculated after orally administering each preparation containing 60 mg of nimodipine. The mean bioavailability of nimodipine was comparable after administration of the Eudragit EPO solid dispersion and Nimotop, but the HPMC and PVP/VA dispersions exhibited much lower bioavailability. However, the AUC(0-12 hr) values of all three solid dispersions were significantly higher than physical mixtures with the same carriers and nimodipine powder.     

Development of solid dispersions of β-lapachone in PEG and PVP by solvent evaporation method

β-lapachone (βlap) has shown potential use in various medical applications. However, its poor solubility has limited its systemic administration and clinical applications. The aim of this work is to develop solid dispersions of βlap using poly (ethylene glycol) (PEG 6000) and polyvinylpyrrolidone (PVP K30) as hydrophilic polymers and evaluate the dissolution rate in aqueous medium. Solid dispersions were prepared by solvent evaporation method using different weight ratios of βlap and hydrophilic polymer (1:1, 1:2, and 1:3). Characterization performed by differential scanning calorimetry, Fourier transform infrared spectroscopy, X-ray diffraction, and scanning electron microscopy showed that βlap was molecularly dispersed within the polymer matrix. The in vitro dissolution tests showed an enhancement in the dissolution profile of βlap as solid dispersions prepared in both PVP and PEG, although the former showed better results. The drug:polymer ratio influenced βlap dissolution rate, as higher amounts of hydrophilic polymer led to enhanced drug dissolution. Thus, this study demonstrated that solid dispersions of βlap in PVP offers an effective way to overcome the poor dissolution of βlap.     

Enhancement of the Dissolution and Permeation Rates of Meloxicam by Formation of Its Freeze-dried Solid Dispersions in Polyvinylpyrrolidone K-30

ABSTRACT

Freeze-drying (FD) and solvent evaporation (SE) were used to prepare solid dispersions (SDs) of meloxicam (MX) in polyvinylpyrrolidone K-30 (PVP). The SDs were prepared at different ratios, namely 1:1, 1:3, and 1:5 MX:PVP weight ratio. Differential scanning calorimetry (DSC), infrared absorption spectroscopy (IR), and x-ray powder diffractometry (XPD) were utilized to characterize the physicochemical properties of the SDs. Meloxicam (MX) in the solid dispersions appeared with less crystallinity form and was present in a complete amorphous form at higher PVP ratio. Dissolution rates of MX as a pure drug, physical mixtures (PMs), and SDs indicated a marked increase of the dissolution rate of MX in presence of PVP. The increase in the dissolution rate was dependent on the ratio of PVP and the method of preparation. In addition, the permeability of the drug through standard cellophane membrane and hairless mouse skin was also evaluated. The permeation rate of MX was significantly increased in the case of SDs and was dependent on the ratio of PVP. The results were primarily due to increase wettability, the solubilization of the drug by the carrier, and formation of MX amorphous form.     

Physical Characterization and Dissolution Properties of Verapamil. HCI Coprecipitates

Verapamil hydrochloride coprecipitates were prepared using solvent-evaporation technique. Ethylcellulose, hydroxypropyl cellulose, hydroxypropyl methylcellulose phtalate HP 55 were used as polymers. The solid dispersions obtained were grounded and sieved to prepare solid dispersion granules. The dissolution behavior of solid dispersion granules was studied using buffer solutions with pH 1.5; 6.8 and half-change method during 24 hours. The drug release rate was found to be dependent on the ratio of the polymers in coprecipitates. In order to understand the drug release mechanism better, the release data were tested assuming common kinetic models. The best fit kinetic model was diffusion model and the dissolution rate constants calculated using Higuchi equation, demonstrated that dissolution rate increased with increasing the ratio of HPMCP HP 55 in coprecipitates. Physical characterization was made using X-ray diffractometry, IR spectrophotometry and DTA studies. Prepared coprecipitates were X-ray amorphous. Also, after nine months real time studies they remain amorphous, with no changes in their IR spectra and DTA curves. The dissolution rate of the test dispersions showed no significant changes during the stability studies, reflecting the stability of X-ray amorphous drug phase.     

Part II: Bioavailability in Beagle Dogs of Nimodipine Solid Dispersions Prepared by Hot-Melt Extrusion

ABSTRACT

The aim of the present work was to investigate the in vitro dissolution properties and oral bioavailability of three solid dispersions of nimodipine. The solid dispersions were compared with pure nimodipine, their physical mixtures, and the marketed drug product Nimotop®. Nimodipine solid dispersions were prepared by a hot-melt extrusion process with hydroxypropyl methylcellulose (HPMC, Methocel E5), polyvinylpyrrolidone/vinyl acetate copolymer (PVP/VA, Plasdone S630®), and ethyl acrylate, methyl methacrylate polymer (Eudragit® EPO). Previous studies of XRPD and DSC data showed that the crystallinity was not observed in hot-melt extrudates, two T_gs were observed in the 30% and 50% NMD-HPMC samples, indicating phase separation. The weakening and shift of the N–H stretching vibration of the secondary amine groups of nimodipine as determined by FT-IR proved hydrogen bonding between the drug and polymers in the solid dispersion. The dissolution profiles of the three dispersion systems showed that the release was improved compared with the unmanipulated drug. Drug plasma concentrations were determined by HPLC, and pharmacokinetic parameters were calculated after orally administering each preparation containing 60 mg of nimodipine. The mean bioavailability of nimodipine was comparable after administration of the Eudragit® EPO solid dispersion and Nimotop®, but the HPMC and PVP/VA dispersions exhibited much lower bioavailability. However, the AUC_{0–12 hr} values of all three solid dispersions were significantly higher than physical mixtures with the same carriers and nimodipine powder.     

Enhanced solubility of piperine using hydrophilic carrier-based potent solid dispersion systems

Context: Piperine alkaloid, an important constituent of black pepper, exhibits numerous therapeutic properties, whereas its usage as a drug is limited due to its poor solubility in aqueous medium, which leads to poor bioavailability.

Objective: Herein, a new method has been developed to improve the solubility of this drug based on the development of solid dispersions with improved dissolution rate using hydrophilic carriers such as sorbitol (Sor), polyethylene glycol (PEG) and polyvinyl pyrrolidone K30 (PVP) by solvent method. Physical mixtures of piperine and carriers were also prepared for comparison.

Methods: The physicochemical properties of the prepared solid dispersions were examined using SEM, TEM, DSC, XRD and FT-IR. In vitro dissolution profile of the solid dispersions was recorded and compared with that of the pure piperine and physical mixtures. The effect of these carriers on the aqueous solubility of piperine has been investigated.

Results: The solid dispersions of piperine with Sor, PEG and PVP exhibited superior performance for the dissolution of piperine with a drug release of 70%, 76% and 89%, respectively after 2?h compared to physical mixtures and pure piperine, which could be due to its transformation from crystalline to amorphous form as well as the attachment of hydrophilic carriers to the surface of poorly water-soluble piperine.

Conclusion: Results suggest that the piperine solid dispersions prepared with improved in vitro release exhibit potential advantage in delivering poorly water-soluble piperine as an oral supplement.     

Dissolution Properties of Glibenclamide in Combinations with Polyvinylpyrrolidone

Investigations were done on the enhanced aqueous solubility of glibenclamide. Eight kin & of glibenclamide coprecipitates, using two kinds of polyvinylpyrrolidone (PVP) having different molecular weights, were prepared in a solid powdered form by the conventional evaporation method. The formation of coprecipitates was confirmed by powder x-ray diffractometry, differential scanning calorimetry and Fourier-transform infrared spectroscopy. The aqueous solubility of glibenclamide was improved by increasing the concentrations of PVP. The coprecipitates prepared in this study were found to have higher dissolution rates compared to intact glibenclamide and physical mixtures of glibenclamide and PVP.     

Solubility of Solid Dispersions of Pizotifen Malate and Povidone

We analyzed the physicochemical characteristics of solid dispersions of pizotifen malate and povidone (Kollidon 12) at different proportions; we used X-ray diffraction, infrared spectrometry, and differential scanning calorimetry (DSC) and tested the solubility of the solid dispersions in equilibrium. The results were compared with findings for physical mixtures with the same proportions. A solid dispersion with a drug proportion of 16%–17% formed a eutectic mixture. Solubility of pizotifen malate increased with the proportion of drug in the solid dispersion up to a drug:polymer ratio of 40:60. The hydrotropic effect of the polymer also favored solubility: In physical mixtures, this effect was greatest at a drug:polymer ratio of 10:90; solubility at this proportion was equal to that of the solid dispersion at the same proportion.     

Solubility of solid dispersions of pizotifen malate and povidone

We analyzed the physicochemical characteristics of solid dispersions of pizotifen malate and povidone (Kollidon 12) at different proportions; we used X-ray diffraction, infrared spectrometry, and differential scanning calorimetry (DSC) and tested the solubility of the solid dispersions in equilibrium. The results were compared with findings for physical mixtures with the same proportions. A solid dispersion with a drug proportion of 16%-17% formed a eutectic mixture. Solubility of pizotifen malate increased with the proportion of drug in the solid dispersion up to a drug:polymer ratio of 40:60. The hydrotropic effect of the polymer also favored solubility: In physical mixtures, this effect was greatest at a drug:polymer ratio of 10:90; solubility at this proportion was equal to that of the solid dispersion at the same proportion.     

Characterization of solid dispersions of Patchouli alcohol with different polymers: effects on the inhibition of reprecipitation and the improvement of dissolution rate

Solid dispersion technique is known to be an effective approach for the polymer to keep drugs stable in the solid state, thereby improving the dissolution rate and oral bioavailability through inhibiting reprecipitation in supersaturated solution. In this study, to evaluate the inhibitory effect of polyethylene glycol-6000 (PEG), Polyvinylpyrrolidone K30 (PVP) and Aminoalkyl methacrylate copolymer (Eudragit), the reprecipitation profiles were observed from supersaturated solutions of Patchouli alcohol (PA) in the presence and absence of the polymers. Furthermore, the dissolution profiles of PA solid dispersions formulated with PEG, PVP or Eudragit were compared for investigating the effect on improving dissolution of each polymer. Solid dispersions formulated with Eudragit were found to result in solution with the highest extent of supersaturation. By contrast, PEG and PVP were less effective. At equivalent supersaturation, all three polymers are capable of mitigating reprecipitation relative to that of PA alone. In addition, in the PA solid dispersion with Eudragit (E-SD (1/3)), the highest concentration of supersaturation of PA was maintained for prolonged time. These results unambiguously indicate that it is imperative to select the appropriate polymer and drug/polymer ratio in addition to considering the stability of the supersaturated solution, which was generated following dissolution of amorphous solid dispersion.