Improvement in solubility and dissolution rate of flavonoids by complexation with beta-cyclodextrin

The inclusion into the beta-cyclodextrin is used to improve pharmacokinetic characteristics of hesperetin and naringenin. Solubility of hesperetin and naringenin with increasing concentrations of beta-cyclodextrin grows as long as the temperature increased. Stability constants were determined by the solubility method by Higuchi and Connors at different temperatures, and the thermodynamic parameters were calculated for inclusion complex formation in aqueous solution. The solid complexes were obtained in a molar ratio of 1:1 and their dissolution behavior at different pH was examined.     

Improvement of water solubility and in vitro dissolution rate of aceclofenac by complexation with β-cyclodextrin and hydroxypropyl-β-cyclodextrin

The present study deals with the inclusion complexation of aceclofenac with β-cyclodextrin by grinding, microwave and spray-drying techniques. A derivative of β-cyclodextrin, hydroxypropyl-β-cyclodextrin, was also subjected to the complexation process with aceclofenac by spray-drying technique. The samples were subjected to in-vitro dissolution studies, fourier transform infra-red spectroscopy, differential scanning calorimetry, nuclear magnetic resonance spectroscopy and x-ray diffraction studies. The in-vitro dissolution of aceclofenac-hydroxypropyl-β-cyclodextrin complex was faster as compared to the aceclofenac- β-cyclodextrin complex and aceclofenac alone. Spray-dried aceclofenac-β-cyclodextrin complex were subjected to anti-inflammatory and analgesic activity and showed significant anti-inflammatory and analgesic activity.     

Improvement in solubility and dissolution rate of 1, 2-dithiole-3-thiones upon complexation with beta-cyclodextrin and its hydroxypropyl and sulfobutyl ether-7 derivatives.

Inclusion complexes between beta-cyclodextrin derivatives and 1, 2-dithione-3-thiones were studied in aqueous solution and in the solid state. Phase solubility study was used to evaluate the complexation in solution, at 37 degrees C, of three cyclodextrins, i. e., beta-cyclodextrin (betaCD), hydroxypropyl-beta-cyclodextrin (HPbetaCD), sulfobutyl ether-7-beta-cyclodextrin (SBE7betaCD), and four 1,2-dithiole-3-thiones, i.e., the parent compound dithiolethione (DTT), dimethyldithiolethione (DMDTT), 5-phenyldithiolethione (5PDTT), and anetholetrithione (ATT). Stability constants of the DTT complexes with HPbetaCD and SBE7betaCD were also determined spectrophotometrically using a nonlinear least-squares methodology. Differential scanning calorimetry (DSC) and scanning electronic microscopy (SEM) were used to characterize spray-dried complexes formed between 5PDTT and SBE7betaCD, ATT and SBE7betaCD. Dissolution studies using the USP paddle method were carried out in water at 37 degrees C for both ATT and 5PDTT binary systems with HPbetaCD and SBE7betaCD. Solubility enhancements were much greater with the more lipophilic ATT and 5PDTT compared to DTT and DMDTT, whatever the cyclodextrin used, in the rank order SBE7betaCD > HPbetaCD > betaCD. Stability constants obtained (between 120 and 12800 mol(-1)) were also the highest for the more lipophilic drugs and in the same rank order SBE7betaCD > HPbetaCD > betaCD. Results obtained by UV spectrophotometry were in good agreement with those obtained by phase-solubility study. DSC thermograms of spray-dried complexes of ATT and 5PDTT with HPbetaCD and SBE7betaCD lacked the endothermal peak of pure drug peak which was found for the physical mixtures (107 degrees C and 125 degrees C for ATT and 5PDTT, respectively). Finally, dissolution profiles of spray-dried inclusion complexes studied displayed a faster dissolution rate compared to physical mixtures and pure drugs. The present study showed that complexation of 1,2-dithiole-3-thiones with beta-cyclodextrin derivatives resulted in an increase in solubility, allowing intravenous formulation for bioavailability and metabolism studies and an increase in the dissolution rate of the drugs, which should be of interest for oral absorption of these lipophilic compounds.     

Enhanced solubility and dissolution rate of lamotrigine by inclusion complexation and solid dispersion technique

The solid-state properties and dissolution behaviour of lamotrigine in its inclusion complex with beta-cyclodextrin (betaCD) and solid dispersions with polyvinylpyrrolidone K30 (PVP K30) and polyethyleneglycol 6000 were investigated. The phase solubility profile of lamotrigine with betaCD was classified as AL-type, indicating formation of a 1:1 stoichiometry inclusion complex, with a stability constant of 369.96+/-2.26 M(-1). Solvent evaporation and kneading methods were used to prepare solid dispersions and inclusion complexes, respectively. The interaction of lamotrigine with these hydrophilic carriers was evaluated by powder X-ray diffractometry, Fourier transform infrared spectroscopy and differential scanning calorimetry. These studies revealed that the drug was no longer present in crystalline state but was converted to an amorphous form. Among the binary systems tested, PVP K30 (1:5) showed greatest enhancement of the solubility and dissolution of lamotrigine.     

Improvement of physical stability and dissolution rate of celecoxib suspensions by complexation with beta-cyclodextrins

Solid dispersions of celecoxib with beta-cyclodextrins were prepared by physical mixing, slugging and kneading methods at 1:1 and 1:2 molar ratios and characterized by differential scanning calorimetry. Celecoxib suspensions were formulated employing its solid dispersions with sodium carboxymethylcellulose as the suspending agent. Stability studies were conducted by subjecting all the suspensions to freeze-thaw cycling. The suspensions were evaluated for particle size, sedimentation volume, viscosity, redispersibility and dissolution rate initially and after stability testing. Celecoxib suspensions formulated employing its solid dispersions exhibited good physical stability and gave higher dissolution rates than those formulated with celecoxib alone. The suspension prepared from solid dispersions (1:2) by the kneading method gave the highest improvement in dissolution rate and efficiency. Celecoxib in the inclusion complex with beta-cyclodextrin produced suspensions of better physical stability and dissolution rate.     

Enhancement of solubility and dissolution rate of poorly water-soluble naproxen by complexation with 2-hydroxypropyl-β-cyclodextrin

The solubility and dissolution rate of naproxen (NPX) complexed with 2-hydroxypropyl-β-cyclodextrin (2-HPβCD) using coprecipitation, evaporation, freeze-drying and kneading method were investigated. Solubility of NPX linearly increased (correlation coefficient, 0.995) as 2-HP-βCD concentration increased, resulting in A_L type phase solubility curve. Inclusion complexes prepared by four different methods were compared by differential scanning calorimetry (DSC). The NPX showed sharp endothermic peak around 156°C but inclusion complexes by evaporation, freeze-drying and kneading method showed very broad peak without distinct phase transition temperature. In contrast, inclusion complex prepared by coprecipitation method resulted in detectable peak around 156°C which is similar to NPX, suggesting incomplete formation of inclusion complex. Dissolution rate of inclusion complexes prepared by evaporation, freeze-drying and kneading except coprecipitation method was largely enhanced in the simulated gastric and intestinal fluid when compared to NPX powder and commercial NAXEN^® tablet. However, about 65% of NPX in gastric fluid still remained unreleased but most of NPX dissolved within 5 min in intestinal fluid. In case of inclusion complex prepared by coprecipitation method, formation of inclusion complex appeared to be incomplete, resulting in no marked enhancement of dissolution rate. From these findings, inclusion complexes of poorly water-soluble NPX with 2-HPβCD were useful to increase solubility and dissolution rate, resulting in enhancement of bioavailability and minimization of gastrointestinal toxicity of drug upon oral administration of inclusion complex.     

Improvement of the in vitro dissolution of praziquantel by complexation with alpha-, beta- and gamma-cyclodextrins

Although praziquantel (PZQ) is the primary drug of choice in the treatment of schistosomiasis, its poor solubility has restricted its delivery via the oral route. In spite of its poor solubility, PZQ is well absorbed across the gastrointestinal tract, but large doses are required to achieve adequate concentrations at the target sites. Improving the solubility would enable the parenteral route to be used, thereby avoiding significant first pass metabolism. The aqueous solubility of PZQ was improved by forming inclusion complexes with alpha-, beta- and gamma-cyclodextrins (CDs). These complexes were assessed and confirmed by solubility analysis, Fourier transform infrared analysis, elemental analysis, differential scanning calorimetry and mass spectrometry. Dissolution of PZQ from the alpha-, beta- and gamma-CD complexes was 2.6-, 5- and 8-fold greater, respectively, than that of the pure drug. However, only the beta-complex had a stability constant in the optimum range for pharmaceutical use, suggesting that the preferred complex for further development would be a water-soluble beta-CD derivative.Copyright     

The influence of beta-cyclodextrin on the solubility and dissolution rate of paracetamol solid dispersions.

The effect of cyclodextrin (beta-CD) on the solubility and dissolution rate of various paracetamol dispersion powders (1:1 w/w), and tablets was studied. Lower solubility was exhibited by a spray dried solid dispersion made from paracetamol-Ethocel-Macrogol 6000 (95:2:3). The improvement in solubility was influenced by complexation with beta-CD and the crystalline nature of the powder products made by different procedures. The difference in crystallinity was confirmed by X-ray powder diffraction patterns. The dissolution rate of paracetamol from tablets made from the solid dispersions was satisfactory compared with paracetamol alone. The differences between the dissolution rate from the examined paracetamol tablets resulted from the different solubility of each powder and from the structural changes of particles which influenced the consolidation of the tablet mass.     

固体分散技术及包合技术对莫诺苯腙溶出度的影响

目的:考察固体分散技术及包合技术对莫诺苯腙溶出度的影响.方法:采用共沉淀法制备莫诺苯腙β-环糊精包合物,用旋转蒸发法制备莫诺苯腙PVP固体分散体,通过IR、UV、DSC法研究固体分散体及包合物的性质,测定了固体分散体及包合物的溶出速率,并考察两者的稳定性.结果:溶出速率的大小依次为固体分散体＞包合物＞原料药.UV、IR、DSC的结果表明形成了固体分散体及包合物.包合物具有良好的稳定性.结论:固体分散及包合技术能显著提高莫诺苯腙的溶出度,同时包合物能提高药物的稳定性.     

Enhancement of dissolution amount and in vivo bioavailability of itraconazole by complexation with beta-cyclodextrin using supercritical carbon dioxide

The main objective of this study was to improve the inclusion formation between itraconazole and beta-cyclodextrin and thus enhance dissolution amount and bioavailability characteristics of itraconazole. Inclusion complexes between itraconazole and beta-cyclodextrin were prepared using simple physical mixing, conventional coprecipitation method, and supercritical carbon dioxide (SC CO(2)). Effects of process variables (temperature, pressure) and drug:cyclodextrin ratio on inclusion yield and thermal behavior of the solid complexes prepared by SC CO(2) were studied and compared to those obtained by physical mixing and coprecipitation methods. In addition, dissolution amounts of the products obtained by different methods were measured in gastric fluid. Finally, pharmacokinetic studies of the inclusion complexes were conducted in male Wistar rats to assess the bioavailability of the prepared complexes. Results showed that temperature, pressure and itraconazole:beta-cyclodextrin ratio had significant effects on the inclusion yield of the complex prepared by SC CO(2) method. Higher inclusion yields were obtained in the SC CO(2) method as compared to physical mixing and coprecipitation methods. In vivo drug pharmacokinetic studies showed that the itraconazole-beta-cyclodextrin product prepared using SC CO(2) gave higher bioavailability of itraconazole (in blood, liver and kidney of male Wistar rats) as compared to the products obtained by physical mixing or coprecipitation methods.     

Enhancement of water solubility of indomethacin by complexation with protein hydrolysate

Complex formation between indomethacin (Indo) and casein hydrolysate was developed as a novel technique for enhancing the water solubility of Indo. The complex (Indo-Pep) was prepared by mixing an ethanol solution of Indo and an aqueous solution of peptide mixture, followed by lyophilization. The water solubility of Indo-Pep under weakly acidic and neutral conditions is much higher than that of Indo alone. The water solubility of Indo increased with increasing quantity of peptide. Characterization of Indo-Pep using scanning electron microscopy, differential scanning calorimetry, and X-ray diffraction showed that Indo was incorporated in Indo-Pep in an amorphous state. The fluorescence quenching of Indo-Pep also suggested complexation between Indo and the peptides. An aqueous solution of Indo-Pep was fractioned by centrifugation followed by filtration using membrane filters and ultrafilters. Analysis of the fractions by dynamic light scattering and ultraviolet–visible spectroscopy showed that Indo-Pep consisted of small particles and was not a hydrocolloidal material.     

Improvement of solubility and oral bioavailability of rutin by complexation with 2-hydroxypropyl-beta-cyclodextrin

The object of this study was to enhance the solubility, dissolution rate, and oral bioavailability of rutin by complexation with 2-hydroxypropyl-beta-cyclodextrin (HP-beta-CyD). The interaction of rutin with cyclodextrins (CyDs) was evaluated by the solubility, and ultraviolet (UV) and circular dichroism (CD) spectrophotometries. The chemical and enzymatic stability of rutin was examined in an alkaline buffer solution and in rat small intestinal homogenates, respectively. Dissolution rates of rutin and its CyD complexes were measured by the dispersed amount method. In vivo absorption studies of rutin after oral administration via conventional tablet containing rutin alone or its beta-CyD complexes was performed on beagle dogs. The stability constants calculated from the phase solubility method increased in the order of HP-gamma-CyD < G2-beta-CyD < beta-CyD < HP-beta-CyD. Spectroscopic studies also revealed that HP-beta-CyD and beta-CyD formed a relatively more stable inclusion complex with rutin. The dissolution rates of rutin increased by the complexation with CyDs in the order of rutin alone < HP-beta-CyD < or = beta-CyD. HP-beta-CyD inhibited the hydrolysis of rutin in the alkaline buffer solution and the small intestinal homogenates of rats, suggesting that HP-beta-CyD may stabilize rutin in a gastrointestinal tract after oral administration. When the tablet containing rutin or its beta-CyD complexes was administered to beagle dogs, the plasma levels of homovanillic acid (HVA) (a major stable metabolite of rutin) after oral administration of HP-beta-CyD complex were much higher than in either that of rutin alone or in its beta-CyD complex. The in vivo absorption study suggests that HP-beta-CyD increased the oral bioavailability of rutin from the gastrointestinal tracts of beagle dogs because of the increase in solubility, faster dissolution rate, and gastrointestinal stability. HP-beta-CyD has a significant advantage with respect to providing high aqueous solubility while maintaining a lack of toxicity in oral pharmaceutical preparations of rutin.     

Improvement of solubility and dissolution rate of poorly water-soluble salicylic acid by a spray-drying technique.

Spray drying techniques have been applied to improve the solubility and dissolution rate of poorly water-soluble salicylic acid. Spray drying of the acid dispersed in acacia solutions resulted in as much as a 50% improvement in the solubility of the product. Solubility improvement was closely related not only to the concentration of acacia but also the amount of amorphous material in the spray-dried products. The heat of solution was inversely related to these parameters. The dissolution rate of spray-dried product was almost instantaneous being about 60 times faster than that of the original powder. A great improvement in the wettability of the spray-dried material seemed to be mainly responsible for the increase of dissolution rate.     

Improvement of dissolution and absorption characteristics of benzodiazepines by cyclodextrin complexation

Inclusion complexes of 13 benzodiazepines with 3 cyclodextrins (α-, β-, γ-CyDs) in aqueous solution and in the solid phase were studied by solubility methods, spectroscopy (UV, CD, IR), thermal analysis, and X-ray diffractometry, and their modes of interaction were assessed. The importance of the hydrophobicity of the guest molecule and the spatial relationship between host and guest molecules were clearly reflected in the magnitude of the stability constant of the inclusion complexes. The solid complexes of some benzodiazepines with γ-CyD were obtained in a variety of molar ratios, and dissolution and membrane permeation behaviors were examined. The rates of dissolution and permeation of benzodiazepines through a cellophane membrane were significantly increased by γ-CyD complexation. As an example, the rapid dissolving form of diazepam-γ-CyD complex was found to significantly increase the serum levels of drug after oral administration to rabbits.     

Improvement of solubility of C70 by complexation with cyclomaltononaose (delta-cyclodextrin)

We investigated the solubilizing effects of cyclomaltononaose (delta-CD), a cyclic oligosaccharide composed of nine alpha-1,4-linked D-glucose units, on C70 by using the ball-milling method based on a solid-solid mechanochemical reaction. The complex between C70 and delta-CD was characterized by UV-VIS spectrometry and fast atom bombardment mass spectrometry (FAB-MS). Coloration of the C70/delta-CD system was red-brown in aqueous solution, and the UV-VIS spectrum was in agreement with that of C70 in hexane solution. The FAB-MS spectrum of the C70/delta-CD system showed a negative ion peak corresponding to the molecular weight of a complex between two delta-CD and one C70. These findings suggest that the solubilization of C70 in water was due to complex formation of C70 with delta-CD, and the stoichiometric ratio of this complex was 1: 2 (C70: delta-CD).     

Improvement of solubility and dissolution rate of indomethacin by solid dispersions in Gelucire 50/13 and PEG4000

The aim of this study was to prepare and characterize solid dispersions of water insoluble non-steroidal anti-inflammatory drug, indomethacin (IND), with polyethylene glycol 4000 (PEG4000) and Gelucire 50/13 (Gelu.) for enhancing the dissolution rate of the drug. The solid dispersions (SDs) were prepared by hot melting method at 1:1, 1:2 and 1:4 drug to polymer ratios. Scanning electron microscopy (SEM), X-ray powder diffractometry (XRD) and differential scanning calorimetry (DSC) were used to examine the physical state of the drug. Furthermore, the solubility and the dissolution rate of the drug in its different systems were explored. The data from the XRD showed that the drug was still detectable in its solid state in all SDs of IND–Gelu. and disappeared in case of higher ratio of IND–PEG4000. DSC thermograms showed the significant change in melting peak of the IND when prepared as SDs suggesting the change in crystallinity of IND. The highest ratio of the polymer (1:4) enhanced the drug solubility about 4-folds or 3.5-folds in case of SDs of IND–PEG or IND–Gelu., respectively. An increased dissolution rate of IND at pH 1.2 and 7.4 was observed when the drug was dispersed in these carriers in form of physical mixtures (PMs) or SDs. IND released faster from the SDs than from the pure crystalline drug or the PMs. The dissolution rate of IND from its PMs or SDs increased with an increasing amount of polymer.     

Cyclodextrin and phospholipid complexation in solubility and dissolution enhancement: a critical and meta-analysis

Introduction: Poor solubility and dissolution of drugs are the major challenges in drug formulation and delivery. In order to improve the solubility and dissolution profile of drugs, various methods have been investigated so far. The cyclodextrin (CD) complexation and phospholipid (PL) complexation are among the exhaustively investigated methods employed for more precise improvement of the solubility and dissolution of poorly water-soluble drugs.

Areas covered: The article discusses the CD and PL complexation techniques of solubility and dissolution enhancement. Various studies reporting the CD and PL complexation as the potential approaches to improve the dissolution, absorption and the bioavailability of the drugs have been discussed. The article critically reviews the physicochemical properties of CDs and PLs, eligibility of drugs for both the complexation, thermodynamics of complexation, methods of preparation, characterization, advantages, limitation and the meta-analysis of some studies for both the techniques.

Expert opinion: The CD and PL complexation techniques are very useful in improving solubility and dissolution (and hence the bioavailability) of biopharmaceutical classification system Class II and Class IV drugs. The selection of a particular kind of complexation can be made on the basis of eligibility criteria (of drugs) for the individual techniques, cost, stability and effectiveness of the complexes.     

Improvement of dissolution properties of lamotrigine by inclusion complexation and solid dispersion technique

The aim of the present work was to improve the dissolution characteristics of the poorly water soluble antiepileptic drug lamotrigine (LMN) by inclusion complexation using hydroxy propyl beta-cyclodextrin (HP beta-CD) by co-evaporation technique and by, solid dispersion, prepared by the melt method using poloxamer 407 (L 127). Phase solubility studies showed AL type curves with both the carriers. Dissolution of LMN was significantly improved (p < 0.05) by inclusion complexation and solid dispersion preparation. Results of solid state characterization performed by Fourier Transform Infrared Spectroscopy, Differential Scanning Calorimetry and Powder X-ray Diffractrometry techniques revealed a decrease in the crystallinity of LMN that might be accounting for improvement in the dissolution properties as seen from dissolution studies.     

卡马西平β-环糊精包合物的制备及其包合作用的考察

目的为提高卡马西平的溶解性,采用饱和水溶液法制备卡马西平β-环糊精包合物并对其工艺和包合作用进行研究。方法以包封率、收率、载药量为指标,采用综合评分法,通过正交设计优选最佳包合工艺。采用连续递变浓度法测定包合比,绘制不同温度下的相溶解度曲线,测定包合常数和热力学参数。结果最佳包合工艺为包合温度80℃,卡马西平与β-环糊精物质的量比为1∶1,包合时间为1 h。所测定的包合物的包封率为93%,收率为98.6%,载药量为16%。相溶解度曲线为AL型,于25、35、45和55℃下包合常数分别为499.8、673.2、916.9和1 240.8 L·mol-1,吉布斯自由能(ΔG)分别为-15.4、-16.7、-18.0和-19.4 k J·mol-1,焓变(ΔH)为24.7 k J·mol-1,熵变(ΔS)为134.3 J·mol-1·K-1。结论所制备的卡马西平β-环糊精包合物,溶解性显著提高,包合过程是自发进行的熵驱动下的吸热反应。