Preparation, characterization and in vitro dissolution of aceclofenac-loaded PVP solid dispersions prepared by spray drying or rotary evaporation method

This study was conducted to enhance dissolution rate of aceclofenac (ACF) with extremely low solubility and high permeability (BCS class II) in water using poly vinyl pyrrolidone (PVP) and sodium lauryl sulfate as carriers. Solid dispersions were prepared by spray drying method and rotary evaporation method using different ratios of ACF and polymers. The characterization of solid dispersions was evaluated by scanning electron microscopy, Fourier transformation infrared spectroscopy, differential scanning calorimetry and powder X-ray diffractometer. The dissolution behavior of solid dispersions was compared with pure ACF (API) and Airtal^® (Deawoong, Co, Korea) as control groups in simulated phosphate buffer at pH 6.8. The dissolution rate of the drug was affected by nature and amount of polymer used. The prepared solid dispersion of ACF/PVP (1:5) appeared to have the highest dissolution rate. Therefore, solid dispersion techniques of spray drying and rotary evaporation method can be successfully used for the enhancement of the dissolution rate of ACF.     

Improvement of dissolution rate of tacrolimus by solid dispersion technique

Tacrolimus has a poor solubility in water ranging from 4 to 12 μg mL^?1. The mean bioavailability is ~21 %.The present study was carried out with a view to enhance the dissolution rate of poorly water-soluble drug tacrolimus using Gelucire 44/14^® and Gelucire 50/13^® as carriers and lactose monohydrate as an adsorbent. A combination of melt and adsorption techniques was employed for the preparation of solid dispersions (SD) to make final product easy for handling. Phase solubility study was conducted to evaluate the effect of carriers on aqueous solubility of tacrolimus. In order to elucidate the mechanism of dissolution enhancement, solid state characteristics were investigated using Fourier transform infrared spectroscopy, differential scanning calorimetry and powder X-ray diffraction. Mathematical modeling of in vitro dissolution data indicated the best fitting with Korsemeyer–Peppas model and the drug release kinetics primarily as Fickian/anomalous diffusion. All prepared solid dispersions showed dissolution improvement compared to pure drug, with Gelucire 50/13^® as the superior carrier over Gelucire 44/14^®. Almost similar dissolution profile was obtained as a function of storage time; this can be explained by no change in XRD and DSC pattern after 45 days storage period.     

Meloxicam-Paracetamol Binary Solid Dispersion Systems with Enhanced Solubility and Dissolution Rate:Preparation,Characterization, and In Vivo Evaluation

The aim of this work included the improvement of meloxicam solubility and maximizing its pharmacological activity by forming binary solid dispersions with paracetamol. Different binary solid dispersions were prepared using paracetamol as a pharmacologically related coformer with favorable structural, dissolution, and solubility properties. The prepared binary solid dispersions were characterized using differential scanning calorimetry (DSC), Fourier transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), and scanning electron microscopy (SEM). Saturation solubility and dissolution rate were determined for meloxicam-paracetamol binary solid dispersions and compared to each drug individually. The pharmacological effects of meloxicam were enhanced in binary solid dispersions compared to the physical mixture using mice as animal models. This finding could be attributed to the improvement of meloxicam saturation solubility in the binary solid dispersion systems. Solid state characterization demonstrated the formation of amorphous phase with low crystallinity as obtained by XRD data. The solid dispersion prepared by freeze drying at 1:10 molar ratio showed more than sevenfold increase in solubility of meloxicam and more than 65% increase in dissolution rate compared to both generic preparation and physical mixture tablets. Significant differences (P < 0.05) in the analgesic effect represented by the increase in time of licking of forepaws to 7.92 s for the solid dispersion (SD) (F4) system compared to 6.15 and 4.82 s, for physical mixture and control groups were observed, respectively. A significant difference (P < 0.05) in the anti-inflammatory effect was demonstrated for the binary solid dispersion showing more than 50% decrease in the volume of carrageenan-induced tail edema compared to that of the physical mixture. Therefore, the freeze dried binary solid dispersion of meloxicam and paracetamol has shown to increase the analgesic and anti-inflammatory activities as compared to the physical mixture.     

Physicochemical characterization of tacrolimus-loaded solid dispersion with sodium carboxylmethyl cellulose and sodium lauryl sulfate

To develop a novel tacrolimus-loaded solid dispersion with improved solubility, various solid dispersions were prepared with various ratios of water, sodium lauryl sulfate, citric acid and carboxylmethylcellulose-Na using spray drying technique. The physicochemical properties of solid dispersions were investigated using scanning electron microscopy, differential scanning calorimetery and powder X-ray diffraction. Furthermore, their solubility and dissolution were evaluated compared to drug powder. The solid dispersion at the tacrolimus/CMC-Na/sodium lauryl sulfate/citric acid ratio of 3/24/3/0.2 significantly improved the drug solubility and dissolution compared to powder. The scanning electron microscopy result suggested that carriers might be attached to the surface of drug in this solid dispersion. Unlike traditional solid dispersion systems, the crystal form of drug in this solid dispersion could not be converted to amorphous form, which was confirmed by the analysis of DSC and powder X-ray diffraction. Thus, the solid dispersion system with water, sodium lauryl sulfate, citric acid and CMC-Na should be a potential candidate for delivering a poorly water-soluble tacrolimus with enhanced solubility and no convertible crystalline.     

Anomalous properties of spray dried solid dispersions

The use of solid dispersions for oral dosage forms can increase the dissolution rate of poorly soluble drugs. Spray drying is one process that can be used to prepare solid dispersions. Spray dried solid dispersions of griseofulvin, poly[N-(2-hydroxypropyl)methacrylate] (PHPMA) and polyvinylpyrrolidone (PVP) were prepared from acetone and water. When methanol was substituted for water, the morphology, stability and dissolution properties of the solid dispersion changed dramatically. The glass transition temperature for the ternary solid dispersion (GF, PHPMA, and PVP) shifted from 83°C (acetone/water) to 103°C for the acetone/methanol system. These differences in the dispersions are thought to derive from conformational variations of the polymers in solution prior to spray drying. Both PHPMA and PVP formed globules in solution of a size range between 16 and 33 nm. The effect of drug and polymer concentration in solution (before spray drying) on the properties of the solid dispersion was studied. It was found that solid dispersions that were prepared using lower concentrations of drug and polymers in solutions resulted in the formation of particles that display a lower relaxation rate. This result supports the hypothesis that the polymer conformation may significantly change the properties of the solid dispersion. © 2009 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci 98:4724–4737, 2009     

Enhanced release of oxazepam from tablets containing solid dispersions

Solid dispersions of different ratios of Gelita collagel as the carrier and lactose were prepared by the spray drying method. Dissolution studies have shown that by preparing solid dispersions the dissolution rate and the solubility of oxazepam increase markedly, independent of the ratio of drug, carrier and lactose. The properties of the solid dispersions were characterized by X-ray diffraction and polarizing microscopic studies. An amorphous form of all prepared solid dispersions were indicated in X-ray studies. Tablets of solid dispersions of oxazepam/Gelita Collagel, physical mixtures and the drug alone were prepared. The best results from the dissolution test were obtained for tablets containing solid dispersions. They remained in good physical properties when stored for one year in normal conditions.     

他达那非固体分散体的制备和性质研究

目的制备他达那非(tadalafil,TD)固体分散体并进行性质研究。方法利用喷雾干燥法制备固体分散体,以表观溶解度和溶出度为指标筛选处方,采用差示扫描量热(DSC)、粉末X-射线衍射(PXRD)和接触角测定等技术研究药物的存在状态和润湿性等理化性质。结果固体分散体将他达那非的表观溶解度提高22.6倍;20min内药物的累积溶出超过90%;固体分散体药物以分子或无定形状态存在;接触角减小,润湿性增大。结论采用十二烷基硫酸钠(SDS)和介孔硅为载体制备的他达那非固体分散体,能明显提高药物的表观溶解度和溶出度。     

Complexation of celecoxib with beta-cyclodextrin: characterization of the interaction in solution and in solid state

Inclusion complexation between celecoxib, a specific cyclooxygenase II inhibitor, and beta-cyclodextrin (beta-CD) was studied in solution and solid state. Drug cyclodextrin complexes were prepared by spray drying while physical mixtures were obtained by simple blending. Inclusion complexes were characterized by nuclear magnetic resonance spectroscopy (NMR), differential scanning calorimetry (DSC), X-ray diffractometry (XRD), scanning electron microscopy (SEM), infrared spectroscopy (IR), and polarimetry. Phase solubility analysis was carried out to determine the stability constant. Solubility studies revealed the existence of a 1:1 complex between celecoxib and beta-CD. NMR studies suggested a strong interaction between celecoxib and beta-CD prepared by spray drying. XRD and SEM analysis illustrated that celecoxib existed as an amorphous complexed form in spray-dried complexes. Dissolution studies showed that the celecoxib entrapped in spray-dried complexes dissolved much faster than the uncomplexed drug and physical mixtures. The data obtained suggest that celecoxib forms an inclusion complex with beta-CD in solution and solid state, which was confirmed by various analytical techniques. A shorter t50% of dissolution is found for the formulation prepared by spray drying when compared on a weight basis in a USP II apparatus.     

Effect of excipients on dissolution enhancement of aceclofenac solid dispersions studied using response surface methodology: a technical note

The aim of present study was to enhance the dissolution rate of poorly water-soluble drug aceclofenac by solid dispersion technique using corn starch, dicalcium phosphate, lactose, and microcrystalline cellulose as carriers. Solid dispersions were prepared by solvent wetting method using 3² full factorial design for each of the carrier. The prepared solid dispersions were evaluated for differential scanning calorimetry, X-ray diffraction, scanning electron microscopy, Fourier-transform infrared spectroscopy (FTIR), and angle of repose. In vitro dissolution studies were carried out in phosphate buffer (pH 7.5) and 0.1 N HCl (pH 1.2). The results of solid state characterization bring to view that in solid dispersions the crystalline drug gets converted to its amorphous form. FTIR study results indicated the absence of interaction between aceclofenac and carriers. For prepared solid dispersions, angle of repose was found to be in the range of 26.19° to 35.29°, which indicates good flowability. Enhanced drug dissolution was obtained with carrier in order lactose > corn starch > microcrystalline cellulose > dicalcium phosphate. Hence, these carriers could be used to enhance the dissolution rate of poorly water-soluble drug.     

Silymarin-solid dispersions: characterization and influence of preparation methods on dissolution

The influence of preparation methodology of silymarin solid dispersions using a hydrophilic polymer on the dissolution performance of silymarin was investigated. Silymarin solid dispersions were prepared using HPMC E 15LV by kneading, spray drying and co-precipitation methods and characterized by FTIR, DSC, XRPD and SEM. Dissolution profiles were compared by statistical and model independent methods. The FTIR and DSC studies revealed weak hydrogen bond formation between the drug and polymer, while XRPD and SEM confirmed the amorphous nature of the drug in co-precipitated solid dispersion. Enhanced dissolution compared to pure drug was found in the following order: co-precipitation > spray drying > kneading methodology (p < 0.05). All preparation methods enhanced silymarin dissolution from solid dispersions of different characteristics. The co-precipitation method proved to be best and provided a stable amorphous solid dispersion with 2.5 improved dissolution compared to the pure drug.     

Enhanced solubility and dissolution of simvastatin by HPMC-based solid dispersions prepared by hot melt extrusion and spray-drying method

The objective of this study was to use low viscosity grade hydroxypropyl methyl cellulose (Methocel^® E3 LV and Methocel^® E5 LV) to enhance the solubility and dissolution of poorly water soluble drug simvastatin (SIM). Two different technologies, hot melt extrusion and spray drying were employed. Characterization of hot melt extrudes and spray dried samples was done by Fourier-transform infrared spectroscopy, differential scanning calorimetry, X-ray diffraction studies and scanning electron microscopy. The result of the study showed the conversion of crystalline form drug into amorphous form indicating increase in dissolution rate and solubility of SIM.     

盐酸溴己新固体分散体制备及体外溶出实验

目的制备盐酸溴己新（BH）固体分散体并研究其体外溶出度。方法以聚乙烯吡咯烷酮（PVP）为载体,采用喷雾干燥法制备难溶性药物盐酸溴己新固体分散体,并进行体外溶出实验。结果制备成的固体分散体能显著提高盐酸溴己新的体外溶出速率,PVPk-15载体的固体分散体溶出较PVPk-30载体的固体分散体快。随着PVPk-15载体比例增加,固体分散体的溶出先增大后减小,BH-PVPk-15为1∶5时的固体分散体具有良好的体外速释作用。结论将盐酸溴己新制成固体分散体能明显提高其溶解度及体外释放速率。     

Development of amorphous dispersions of artemether with hydrophilic polymers via spray drying: Physicochemical and in silico studies

Artemether (ARM) is a poorly water soluble and poorly permeable drug effective against acute and severe falciparum malaria, hence there is a strong need to improve its solubility. The objective of the study was to enhance the solubility and dissolution rate of ARM by preparation of solid dispersions using spray-drying technique. Solid dispersions of ARM were prepared with Soluplus, Kollidon VA 64, HPMC and Eudragit EPO at weight ratios of 1:1, 1:2, 1:3 using spray drying technology, and characterized by Fourier transform infrared spectroscopy, differential scanning calorimetry (DSC), and X-ray powder diffraction (XRD) to identify the physicochemical interaction between drug and carrier, as well as effect on dissolution. The prepared solid dispersion of ARM with polymers showed reduced crystallinity as compared to neat ARM, which was confirmed by DSC and XRD. Drug/polymer interactions were studied in-silico by docking and molecular dynamics which indicated formation of van der Waals type of interactions of ARM with the polymers. Based on solubility studies, the optimum drug/Soluplus ratio was found to be 1:3. The dissolution studies of formulation SD3 showed highest drug release up to 82% compared to neat ARM giving only 20% at 60 minutes. The spray-dried products were free of crystalline ARM; possessed higher dissolution rates, and were stable over a period according to ICH guidelines. These findings suggest that an amorphous solid dispersion of ARM could be a viable option for enhancing the dissolution rate of ARM.     

Improved dissolution behavior of lipophilic drugs by solid dispersions: the production process as starting point for formulation considerations

INTRODUCTION: Many new drug substances have low aqueous solubility which can cause poor bioavailability after oral administration. The application of solid dispersions is a useful method to increase the dissolution rate of these drugs and thereby improve their bioavailability. So far, several methods have been developed to prepare solid dispersions. To obtain a product with the desired attributes, both the formulation and production processes should be considered. AREAS COVERED: The most currently used methods to produce solid dispersions, such as the fusion method, hot melt extrusion, spray drying, freeze drying and supercritical fluid precipitation, are reviewed in this paper. In addition, the physicochemical characteristics of the obtained solid dispersions are discussed. EXPERT OPINION: Solid dispersions can be successfully prepared by simple fusion, hot melt extrusion, spray drying, freeze drying and supercritical fluid precipitation. Hot melt extrusion, spray drying and freeze drying are processes that can be applied for large scale production. The simple fusion method is not very suitable for large scale production, but is particularly suitable for screening formulations. The most recent method to produce sold dispersions is supercritical fluid precipitation. The process conditions of this method need extensive investigation, in particular in relationship with the selection of the type of carrier and/or solvent. Both processes and formulation aspects strongly affect the characteristics of solid dispersion products. Furthermore, application of crystalline solid dispersions is gaining increasing interest because they are thermodynamically more stable than amorphous solid dispersions.     

Effect of physiochemical variables on phase solubility and dissolution behavior of indomethacin solid dispersion system

To study the influence of temperature and pH on solubility and dissolution behavior of indomethacin solid dispersions were prepared using several classes of hydrophilic carriers. Investigations on dissolution of indomethacin in binary system are reported earlier. However the phase solubility and dissolution behavior at different pH and temperature left void. The present investigation includes: phase solubility study at various pH; preparation of solid dispersion by solvent evaporation, melting and kneading method; characterization of various blends by dissolution study, and solid state studies to ensure interaction of drug with carrier. The binding between drug and carriers (PVP K30, βCD and PEG) was explained by thermodynamic parameters as calculated from phase solubility study. Indomethacin in association with PVP K30 showed very high apparent binding constant (Ka) and Gibb’s free energy change (?G) in comparison to other blends. The ternary system (drug:βCD:PVP K30, 1:5:1) showed better dissolution of about 80.97 and 99 % at pH 7.2 after 5 and 30 min respectively. At higher proportion of carrier (1:9) in binary solid dispersion of drug and PVP K30, drug dissolution was 96.23 and 97.85 % after 5 and 30 min respectively. This raised solubility of indomethacin would be helpful in designing a dosage form.     

Producing Amorphous Solid Dispersions via Co-Precipitation and Spray Drying: Impact to Physicochemical and Biopharmaceutical Properties

Many small-molecule active pharmaceutical ingredients (APIs) exhibit low aqueous solubility and benefit from generation of amorphous dispersions of the API and polymer to improve their dissolution properties. Spray drying and hot-melt extrusion are 2 common methods to produce these dispersions; however, for some systems, these approaches may not be optimal, and it would be beneficial to have an alternative route. Herein, amorphous solid dispersions of compound A, a low-solubility weak acid, and copovidone were made by conventional spray drying and co-precipitation. The physicochemical properties of the 2 materials were assessed via X-ray diffraction, differential scanning calorimetry, thermal gravimetric analysis, and scanning electron microscopy. The amorphous dispersions were then formulated and tableted, and the performance was assessed in vivo and in vitro. In human dissolution studies, the co-precipitation tablets had slightly slower dissolution than the spray-dried dispersion, but both reached full release of compound A. In canine in vitro dissolution studies, the tablets showed comparable dissolution profiles. Finally, canine pharmacokinetic studies showed that the materials had comparable values for the area under the curve, bioavailability, and C_max. Based on the summarized data, we conclude that for some APIs, co-precipitation is a viable alternative to spray drying to make solid amorphous dispersions while maintaining desirable physicochemical and biopharmaceutical characteristics.     

Improved dissolution behavior of lipophilic drugs by solid dispersions: the production process as starting point for formulation considerations

Introduction: Many new drug substances have low aqueous solubility which can cause poor bioavailability after oral administration. The application of solid dispersions is a useful method to increase the dissolution rate of these drugs and thereby improve their bioavailability. So far, several methods have been developed to prepare solid dispersions. To obtain a product with the desired attributes, both the formulation and production processes should be considered.

Areas covered: The most currently used methods to produce solid dispersions, such as the fusion method, hot melt extrusion, spray drying, freeze drying and supercritical fluid precipitation, are reviewed in this paper. In addition, the physicochemical characteristics of the obtained solid dispersions are discussed.

Expert opinion: Solid dispersions can be successfully prepared by simple fusion, hot melt extrusion, spray drying, freeze drying and supercritical fluid precipitation. Hot melt extrusion, spray drying and freeze drying are processes that can be applied for large scale production. The simple fusion method is not very suitable for large scale production, but is particularly suitable for screening formulations. The most recent method to produce sold dispersions is supercritical fluid precipitation. The process conditions of this method need extensive investigation, in particular in relationship with the selection of the type of carrier and/or solvent. Both processes and formulation aspects strongly affect the characteristics of solid dispersion products. Furthermore, application of crystalline solid dispersions is gaining increasing interest because they are thermodynamically more stable than amorphous solid dispersions.     

Caffeine: A potential complexing agent for solubility and dissolution enhancement of celecoxib

Complexation of caffeine with the drug celecoxib was used to enhance its solubility as well as in vitro dissolution in the present investigation. Caffeine was extracted from tea leaves using the sublimation method. A molecular complex (1:1) of caffeine–celecoxib was prepared using the solubility method. The solubility of celecoxib in distilled water and the caffeine complex was determined using a HPLC method at a wavelength of 250?nm. Dissolution studies of pure celecoxib, a marketed capsule (Celebrex^®), and the complex were performed using USP dissolution apparatus I for pure celecoxib and the complex and apparatus II for the capsule in distilled water. The highest solubility (48.32?mg/mL) as well as percent dissolution (90.54%) of celecoxib was obtained with the caffeine–celecoxib complex. The results for solubility and dissolution were highly significant as compared to pure celecoxib and the marketed capsule (p?<?0.01). These results suggest that caffeine is a promising complexing agent for solubility as well as dissolution enhancement of the poorly soluble drug celecoxib.     

Enhancement of solubility and permeability of Candesartan cilexetil by using different pharmaceutical interventions

The poor solubility and wettability of Candesartan cilexetil (CAN) leads to poor dissolution and hence, low bioavailability after oral administration. The aim of the present study was to improve the solubility and dissolution rate and hence the permeability of CAN by preparing solid dispersions/inclusion complexes. Solid dispersions were prepared using PEG 6000 [hydrophilic polymer] and Gelucire 50/13 [amphiphilic surfactant] by melt agglomeration (MA) and solvent evaporation (SE) methods in different drug-to-carrier ratios, while inclusion complexes were made with hydroxypropyl-β-cyclodextrin (HP-β-CD) [complexing agent] by grinding and spray drying method. Saturation solubility method was used to evaluate the effect of various carriers on aqueous solubility of CAN. Based on the saturation solubility data, two drug-carrier combinations, PEG 6000 (MA 1:5) and HP-β-CD (1:1 M grinding) were selected as optimized formulations. FTIR, DSC, and XRD studies indicated no interaction of the drug with the carriers and provided valuable insight on the possible reasons for enhanced solubility. Dissolution studies showed an increase in drug dissolution of about 22 fold over the pure drug for PEG 6000 (MA 1:5) and 12 fold for HP-β-CD (1:1 M grinding). Ex-vivo permeability studies revealed that the formulation having the greatest dissolution also had the best absorption through the chick ileum. Capsules containing solid dispersion/ complex exhibited better dissolution profile than the marketed product. Thus, the solid dispersion/inclusion complexation technique can be successfully used for enhancement of solubility and permeability of CAN.     

Evaluation of molecular pharmaceutical and in‐vivo properties of spray‐dried isolated andrographolide—PVP

Objectives Andrographolide, a natural lipophilic molecule, has a wide range of pharmacological actions. However, due to low aqueous solubility, it has low oral bioavailability. The purpose of the study was to increase the solubility and dissolution rate of isolated andrographolide by formulating its solid dispersion. Method Solid dispersions were obtained by a spray‐drying technique using different ratios of drug to polyvinylpyrrolidine (PVP K‐30). Solid dispersions in compression with isolated drug and corresponding physical mixtures were characterized for various molecular pharmaceutical properties and subjected to stability study for up to 3 months. Key findings A five‐fold increase in saturation solubility of andrographolide with higher values of Q_5min (cumulative percentage release in 5 min) and lower values of t_75% (time required for 75% w/w drug release) for solid dispersion was observed in different dissolution mediums. This was attributed to the formation of amorphous nature and intermolecular hydrogen bonding between drug and PVP K‐30. The stability study showed there to be no significant change in molecular pharmaceutical properties and dissolution profile over the period of 3 months. Moreover, the in‐vivo study in Wistar albino rats also justified improvement in the therapeutic efficacy of andrographolide after solid dispersion. Conclusions This study demonstrates the utility of solid dispersion to improve primary and secondary pharmaceutical properties of andrographolide using PVP K‐30 as a carrier.