Enhanced Aqueous Solubility of Phenolic Antioxidants Using Modified β-Cyclodextrins

Abstract

Phenolic antioxidants are useful additives with a possible role in cancer chemoprevention. This study describes inclusion complexation between phenolic antioxidants (butylated hydroxyanisole, BHA; butylated hydroxytoluene, BHT) and hydroxypropyl-β-cyclodextrins (HPB) or hydroxyethyl-β-cyclodextrin (HEB) and their characterization by phase solubility analysis, Xray diffraction and infrared (IR) spectroscopy. The complexes were prepared by shaking an aqueous mixture of the antioxidant with each of the cyclodextrins (1:1 molar) at 40 °C for six days and lyophilizing the resulting clear solution. Each of the complexes dissolved instantaneously in water. Phase solubility analysis indicated a more pronounced increase in the aqueous solubility of BHA compared to that of BHT. Xray diffraction patterns of the antioxidant-cyclodextrin complexes indicated a shift from crystalline pattern of the antioxidant to an amorphous pattern for the complexes. Also, the IR spectra of the BHA-cyclodextrin complexes indicated an almost complete disappearance or at least a shift in the -C-O-C- stretch (1200 cm^-1) compared to the corresponding stretch observed for BHA alone or a physical mixture (1:1) of BHA and each of the cyclodextrins. Furthermore, the sharp -OH absorption (3600 cm^-1) is retained in a physical mixture of BHT with either cyclodextrin (1:1) whereas this stretch is not observed in the IR spectra of either BHT-cyclodextrin complexes. These evidences indicate the formation of an inclusion complex between the antioxidants and each of the cyclodextrins.     

Analytical study of photodegradation of inclusion complexes of nimodipine with alpha-, gamma-cyclodextrin, methyl-beta-cyclodextrin, and hydroxypropyl-beta-Cyclodextrin

The inclusion behavior of alpha-cyclodextrin (alpha-CD), gamma-cyclodextrin (gamma-CD), hydroxypropyl-beta-cyclodextrin (HP-betaCD), and methyl-beta-cyclodextrin (M-betaCD) with nimodipine (NM) in solution and in the solid state was investigated. Inclusion complexes of nimodipine with cyclodextrins (at a molar ratio of 1:1) in the solid state were obtained by the kneading method. Photochemical stability of NM in the solid inclusion complexes was assessed by IR spectrometry. The modified derivatives of beta-CD and alpha-CD were found to slow the photodegradation rate, whereas in the presence of gamma-CD the photodegradation of NM was a bit faster than in the corresponding physical mixture. Photochemical degradation of NM in liquid inclusion complexes was monitored by UV spectroscopy. According to the slowing effect on photodegradation of NM in the inclusion complexes, the studied cyclodextrins can be ordered as gamma-CD < alpha-CD < HP-betaCD < M-betaCD.     

抗氧化剂从聚丙烯向食品模拟液中迁移的深层影响因素研究

目的研究影响有害物质向食品中迁移的因素,以有效预测包装材料对食品的污染风险。方法研究温度、模拟液的溶解度参数和抗氧化剂的相对分子质量分别对抗氧化剂BHA,BHT,1076和168从聚丙烯向乙醇模拟液中迁移焓变、分配系数和扩散系数的影响,并把Scatchard-Hilderbrand热力学理论模型预测的平衡分配系数(D_(r0))与实验值(D_r)进行比较分析。结果 4种抗氧化剂从PP向无水乙醇中迁移的平衡分配系数对数(ln D_r)、扩散系数对数(ln D_f)与温度倒数(1/T)成直线关系,符合吉布斯-亥姆霍兹方程和阿累尼乌斯方程,迁移为吸热反应,焓变随抗氧化剂相对分子质量的增大而减小,扩散系数随着相对分子质量和模拟液溶解度参数的减小而增大。同时,抗氧化剂从聚丙烯中迁移到不同溶解度参数模拟液中的平衡分配系数(模拟液质量浓度/塑料质量浓度)实验值,与Scatchard-Hilderbrand热力学理论模型计算值随模拟液溶解度参数的变化趋势基本一致。结论模拟液与PP的溶解度参数越接近,抗氧化剂初始迁移扩散系数越大,抗氧化剂相对分子质量对迁移扩散系数的影响越小,4种抗氧化剂从PP中迁移平衡分配系数变化符合Scatchard-Hilderbrand热力学理论模型。     

Gefitinib–cyclodextrin inclusion complexes: physico-chemical characterization and dissolution studies

Background: Gefitinib, an anticancer drug, has an extremely low aqueous solubility, and its oral absorption is limited by its dissolution rate. The solubility and dissolution of gefitinib can be improved by complexation with cyclodextrins (CDs). Methods: Phase solubility studies of gefitinib with hydroxypropyl βCD (HPβCD) and randomly methylated βCD (RMβCD) in n various aqueous systems was conducted to characterize the complexes in the liquid state. The inclusion complexes in the solid state were prepared by freeze-drying method and characterized by X-ray diffractometry (X-RD) and differential scanning calorimetry (DSC). Results: Gefitinib formed stable complexes with HPβCD and RMβCD in distilled water as indicated by the association rate constants (Ks) of 458.9 and 1096.2 M^?1 for HPβCD and RMβCD, respectively. The complexation of gefitinib with CDs in pH 4.5 acetate buffer indicated an A_N type of phase-solubility diagrams, whereas gefitinib and HPβCD in distilled water in the presence of polymers such as polyvinyl pyrrolidone K-30 (PVP) or hydroxypropyl methylcellulose E3 (HPMC) resulted in A_P-type phase-solubility diagrams. The solid-state amorphous complexes (as described by DSC and X-RD) showed substantial increases in the solubility and dissolution rate of gefitinib with both CDs. Further increases in the solubility and dissolution rate of the gefitinib-HPβCD freeze-dried complex were obtained by physically mixing the complex with PVP and HPMC. Conclusion: Gefitinib formed stable inclusion complexes with HPβCD and RMβCD, and the solubility and dissolution rate of the drug was significantly increased.     

Nimesulide and beta-cyclodextrin inclusion complexes: physicochemical characterization and dissolution rate studies

Complex formation of nimesulide (N) and β-cyclodextrin (βCD) in aqueous solution and in solid state and the possibility of improving the solubility and dissolution rate of nimesulide via complexation with βCD were investigated. Phase solubility studies indicated the formation of a 1:1 complex in solution. The value of the apparent stability constant Kc was 158.98 M^-1. Solid inclusion complexes of N and βCD were prepared by kneading and coevaporation methods. Differential scanning calorimetry (DSC) studies indicated the formation of solid inclusion complexes of N-βCD at a 1:2 molar ratio in both the methods. Solid complexes of N-βD (1:1 and 1:2 M) exhibited higher rates of dissolution and dissolution efficiency values than the corresponding physical mixtures and pure drug. Higher dissolution rates were observed with kneaded complexes than with those prepared by coevaporation. Increases of 25.6- and 38.7-fold in the dissolution rate were observed, respectively, with N-βCD 1:1 and 1:2 kneaded complexes.     

Influence of the preparation method on the physicochemical properties of tolbutamide/cyclodextrin binary systems

Tolbutamide (TBM) was found to form an inclusion complex with beta cyclodextrin (beta-CD) in solution and in solid state. Inclusion complex formation between tolbutamide and beta-cyclodextrin in aqueous solution was studied by phase solubility and spectral shift methods. The apparent stability constant Ks calculated by these techniques, in water, were estimated as 195.7 and 236.5 M(-1), respectively. The phase solubility studies revealed a B(S)-type diagram with an inclusion complex of 1:2 molar ratio. The solid inclusion complexes of TBM and beta-CD were prepared at a molar ratio of 1:2 by kneading, coprecipitation, freeze-drying, and spray-drying methods. In addition, the physical mixture was prepared. Characterization of TBM: beta-CD inclusion was performed using differential scanning calorimetry (DSC), Raman spectroscopy, and X-ray diffractometry and by application of a so-called ether wash method. All the inclusion systems investigated led to a significant improvement in the dissolution over free TBM, and the dissolution rate of the active material was observed to be independent of the preparation method.     

Inclusion Complexes of Tolnaftate with β-Cyclodextrin and Hydroxypropyl β-Cyclodextrin

Tolnaftate, an antifungal agent, was found to form inclusion complexes with both β-cyclodextrin (β-CD) and hydroxypropyl β-cyclodextrins (HPBCDs) with two different degrees of substitution [HPBCD(A)-8% and HPBCD(B)-3%]. Complex formation in the solution state was studied using phase solubility and spectral shift methods. Solid complexes were prepared by the coprecipitation method. Solubilities and dissolution rates were determined for each solid complex, its corresponding physical mixture, and free drug. The increase in solubility of tolnaftate with added HPBCD was found to be significantly greater than with added β-CD. For both HPBCD(A) and HPBCD(B), over the concentration range 0-0.05 M. 1:1 complexes with stability constants of 1460 ± 139 M^-1 and 1860 ± 165 M^-1 were observed, respectively. Over the β-CD concentration range 0-0.02 M, a 1:1 complex with a stability constant of 1190 ± 105 M^-1 was observed. At higher HPBCD concentrations, the increase in solubility was observed to show a positive deviation from linearity (type A_p phase diagram). Using the spectral method, in a 2 5% v/v methanol in water system, the stability constants were determined to be 1020 ± 150 M^-1 1110 ± 120 M^-1 and 1100 ± 260 M^-1 for HPBCD(A), HPBCD(B) and β-CD, respectively. The solid complexes prepared showed improved dissolution over physical mixtures and free drug.     

Inclusion complexes of fluorofenidone with β-cyclodextrin and hydroxypropyl-β-cyclodextrin

Background: Fluorofenidone is a novel antifibrotic drug and its aqueous solubility is low. Aim: This study was to prepare and characterize inclusion complexes of fluorofenidone (AKF-PD) with β-cyclodextrin (β-CD) and hydroxypropyl-β-cyclodextrin (HP-β-CD). Method: The AKF-PD/cyclodextrins (CDs) inclusion complexes were prepared by coprecipitation and freeze-drying, respectively. The solubility enhancement of AKF-PD was evaluated by phase solubility method. Inclusion complexation in solid phase was studied by X-ray diffraction (XRD) and differential thermal analysis (DTA). The dissolution profiles of AKF-PD/CDs inclusion complexes were investigated and compared with those of their physical mixtures and AKF-PD alone. Results: The phase solubility diagrams of AKF-PD with β-CD and HP-β-CD were of A_L-types, and the solubility of AKF-PD could be increased by 51.5% for β-CD at 0.014 M and 794.0% for HP-β-CD at 0.254 M. The results from XRD and DTA suggested that AKF-PD could form inclusion complex with β-CD or HP-β-CD. The dissolution rate of AKF-PD from the inclusion complexes was much more rapid than AKF-PD alone. Conclusions: The formulation of AKF-PD/CDs inclusion complexes showed superior performance in improving dissolution properties of AKF-PD.     

Enhancement of Solubility, Dissolution Rate, and Oral Bioavailability of Rs-82856 by Complex Formation with Cyclodextrins

RS-82856 is a new inotropic agent for treatment of congestive heart failure. Oral bioavailability was found to be very poor likely due to insufficient aqueous solubility (∼ 4.4 mcg/ml) and slow dissolution rate. Inclusion complexes with cyclodextrins were shown to enhance the solubility, dissolution rate and thereby oral bioavailability of the drug. Maximum solubilities of the drug complexes with alpha-, beta-, and gamma-cyclodextrin were 14, 30 and 55 times, respectively, more soluble than the uncomplexed drug. Phase solubility studies revealed a 1:l complexation constant of 136.5, 370.4, and 64.7 for alpha -, beta - and gamma-cyclodextrin complexes, respectively . The complexation between beta-cyclodextrin and the drug is apparently the strongest among the three cyclodextrins. Dissolution profiles of the beta-cyclodextrin complex indicated a dramatic increase in dissolution rate compared to that of the drug. However,a physical mixture of the beta-cyclodextrin and the drug gave an identical dissolution profile to that of the drug.The beta-cyclodextrin complex of the drug dissolves 90% with in 20 minutes while the free based is solves 25% with in the same time interval in water. In an acidic medium (ph 1.5) the beta-cyclodextrin complex and the free based is solve 90% and 30% respectively within 10 minutes.In asingle dose cross-over study in three dogs,the bioavailability of the beta-cyclodextrin complex was found to improve greatly over that of the drug. An increased C_max (2.5 times),and an increased AUC (2.5 times) were observed with the beta-cyclodextrin complex compared to the drug.     

Daidzein/cyclodextrin/hydrophilic polymer ternary systems

Objective: To evaluate the effect of different cyclodextrins (β-cyclodextrin [β-CD], methyl-β-cyclodextrin [Mβ-CD], or hydroxypropyl-β-cyclodextrin [HPβ-CD]) and/or hydrophilic polymers (carboxymethylcellulose, hydroxypropylmethylcellulose [HPMC], polyethyleneglycol, or polyvinylpyrrolidone [PVP]) on daidzein solubility in water.

Materials and methods: The corresponding associations were characterized in aqueous media using phase-solubility studies. The morphology of daidzein/cyclodextrin freeze-dried complexes was characterized using scanning electron microscopy, and their spatial configuration was proposed by means of nuclear magnetic resonance spectroscopy.

Results and discussion: In the presence of 6?mM of cyclodextrins, the solubility of daidzein in water was significantly enhanced: 5.7-fold (β-CD), 7.2-fold (Mβ-CD), and 9.4-fold (HPβ-CD). The analysis of the three solid complexes proved that the formation of inclusion complexes occurred through the insertion of the B and C rings of daidzein molecule into the cyclodextrins cavity. The association of daidzein/cyclodextrin complexes to the hydrophilic polymers HPMC or PVP (1%, w/w) was able to improve the solubility of daidzein even further.

Conclusion: The highest solubilizing effect was obtained for daidzein/HPβ-CD/PVP ternary system (12.7-fold).     

Enhancement of Solubility,Dissolution Rate,and Oral Bioavailability of Rs-82856 by Complex Formation with Cyclodextrins

Abstract

RS-82856 is a new inotropic agent for treatment of congestive heart failure. Oral bioavailability was found to be very poor likely due to insufficient aqueous solubility (～ 4.4 mcg/ml) and slow dissolution rate. Inclusion complexes with cyclodextrins were shown to enhance the solubility, dissolution rate and thereby oral bioavailability of the drug. Maximum solubilities of the drug complexes with alpha-, beta-, and gamma-cyclodextrin were 14, 30 and 55 times, respectively, more soluble than the uncomplexed drug. Phase solubility studies revealed a 1:l complexation constant of 136.5, 370.4, and 64.7 for alpha -, beta - and gamma-cyclodextrin complexes, respectively. The complexation between beta-cyclodextrin and the drug is apparently the strongest among the three cyclodextrins. Dissolution profiles of the beta-cyclodextrin complex indicated a dramatic increase in dissolution rate compared to that of the drug. However,a physical mixture of the beta-cyclodextrin and the drug gave an identical dissolution profile to that of the drug.The beta-cyclodextrin complex of the drug dissolves 90% with in 20 minutes while the free based is solves 25% with in the same time interval in water. In an acidic medium (ph 1.5) the beta-cyclodextrin complex and the free based is solve 90% and 30% respectively within 10 minutes.In asingle dose cross-over study in three dogs,the bioavailability of the beta-cyclodextrin complex was found to improve greatly over that of the drug. An increased C_max (2.5 times),and an increased AUC (2.5 times) were observed with the beta-cyclodextrin complex compared to the drug.     

Permeability and retention studies of (-)epicatechin gel formulations in human cadaver skin

(-)Epicatechin (EC) is a major antioxidant component of grape seed extract which has become increasingly popular in topical skin preparations. This study assessed the following: (1) the permeability through cellulose membranes of EC in three different gel formulations (Carbopol 940, Klucel, and Ultrez 10); (2) the effect of three different antioxidants (butylated hydroxytoluene (BHT), alpha-tocopherol (VE), and ascorbic acid (AA)) on the stability and penetration properties of EC; and (3) the permeability and retention of EC in Ultrez 10 gels, supplemented with BHT or VE, on human cadaver skin. Permeability studies through cellulose membranes showed that different gelling agents do not significantly affect the permeability of EC (n = 7/gel; p > 0.05). BHT and VE have antioxidant properties superior to AA (p < 0.05) and preserve 100% of the initial content of EC for 28 days. Permeation studies on cadaver human skin, following application of two anhydrous gel formulations (0.5% EC in Ultrez 10 containing BHT or VE), showed that EC was not detectable in the receiving solution. However, the EC amount in viable skin increased with time, indicating that EC penetrated and was retained in the upper part of the skin for approximately 1% and 3% of the dose for the formulations containing BHT and VE, respectively.     

Permeability and Retention Studies of (-)Epicatechin Gel Formulations in Human Cadaver Skin

ABSTRACT

(-)Epicatechin (EC) is a major antioxidant component of grape seed extract which has become increasingly popular in topical skin preparations. This study assessed the following: (1) the permeability through cellulose membranes of EC in three different gel formulations (Carbopol®940, Klucel®, and Ultrez?10); (2) the effect of three different antioxidants (butylated hydroxytoluene (BHT), alpha-tocopherol (VE), and ascorbic acid (AA)) on the stability and penetration properties of EC; and (3) the permeability and retention of EC in Ultrez?10 gels, supplemented with BHT or VE, on human cadaver skin. Permeability studies through cellulose membranes showed that different gelling agents do not significantly affect the permeability of EC (n?=?7/gel; p?>?0.05). BHT and VE have antioxidant properties superior to AA (p?<?0.05) and preserve 100% of the initial content of EC for 28 days. Permeation studies on cadaver human skin, following application of two anhydrous gel formulations (0.5% EC in Ultrez?10 containing BHT or VE), showed that EC was not detectable in the receiving solution. However, the EC amount in viable skin increased with time, indicating that EC penetrated and was retained in the upper part of the skin for approximately 1% and 3% of the dose for the formulations containing BHT and VE, respectively.     

Influence of the Preparation Method on the Physicochemical Properties of Tolbutamide/Cyclodextrin Binary Systems

Tolbutamide (TBM) was found to form an inclusion complex with β-cyclodextrin (β-CD) in solution and in solid state. Inclusion complex formation between tolbutamide and β-cyclodextrin in aqueous solution was studied by phase solubility and spectral shift methods. The apparent stability constant K_s calculated by these techniques, in water, were estimated as 195.7 and 236.5 M^?1, respectively. The phase solubility studies revealed a B_S-type diagram with an inclusion complex of 1:2 molar ratio. The solid inclusion complexes of TBM and β-CD were prepared at a molar ratio of 1:2 by kneading, coprecipitation, freeze-drying, and spray-drying methods. In addition, the physical mixture was prepared. Characterization of TBM:β-CD inclusion was performed using differential scanning calorimetry (DSC), Raman spectroscopy, and X-ray diffractometry and by application of a so-called ether wash method. All the inclusion systems investigated led to a significant improvement in the dissolution over free TBM, and the dissolution rate of the active material was observed to be independent of the preparation method.     

Nimesulide and β-Cyclodextrin Inclusion Complexes: Physicochemical Characterization and Dissolution Rate Studies

Complex formation of nimesulide (N) and β-cyclodextrin (βCD) in aqueous solution and in solid state and the possibility of improving the solubility and dissolution rate of nimesulide via complexation with βCD were investigated. Phase solubility studies indicated the formation of a 1:1 complex in solution. The value of the apparent stability constant Kc was 158.98 M^?1. Solid inclusion complexes of N and βCD were prepared by kneading and coevaporation methods. Differential scanning calorimetry (DSC) studies indicated the formation of solid inclusion complexes of N-βCD at a 1:2 molar ratio in both the methods. Solid complexes of N-βD (1:1 and 1:2 M) exhibited higher rates of dissolution and dissolution efficiency values than the corresponding physical mixtures and pure drug. Higher dissolution rates were observed with kneaded complexes than with those prepared by coevaporation. Increases of 25.6- and 38.7-fold in the dissolution rate were observed, respectively, with N-βCD 1:1 and 1:2 kneaded complexes.     

Host–guest inclusion system of mangiferin with β-cyclodextrin and its derivatives

The characterization, inclusion complexation behavior and binding ability of the inclusion complexes of mangiferin (MGF) with β-cyclodextrin and its derivatives (hydroxypropyl-β-cyclodextrin (HPβCD), sulfobutyl ether β-cyclodextrin (SBEβCD) and mono (6-ethylene-diamino-6-deoxy)-β-cyclodextrin (ENβCD)) were investigated in both solution and solid state by means of PL spectroscopy, ¹H and 2D NMR, XRD, TG and DSC. The results showed that the water solubility and thermal stability of MGF were significantly increased in the inclusion complex with cyclodextrins. The MGF/CDs complexes will be potentially useful for the design of a novel formulation of mangiferin for herbal medicine.     

Enhancement of dissolution rate and bioavailability of sulfamethoxazole by complexation with β-cyclodextrin

The purpose of this study was to improve the solubility and dissolution rate of sulfamethoxazole (SMZ) with inclusion compound of β-cyclodextrin (β-CD). The interaction between SMZ and β-CD in solution was studied by the phase-solubility method. The phase-solubility studies revealed the formation of inclusion complexes with poor solubility with an inclusion complex of 1:1 molar ratio and a stability constant of 122.3?M(-1). The solid complexes of SMZ with β-CD were prepared by using kneading and coprecipitation methods. The physical mixture of these chemicals was also prepared for comparison. Inclusion complexation was confirmed by the results from the studies of infrared spectoroscopy (IR) and differential scanning calorimetry (DSC). The effect of water-soluble polymers i.e., polyethylene glycol 20000 and non-ionic surfactants i.e., polysorbate 20 on the complexation of SMZ with β-CD was also investigated by the same methods. The rates of release of the active material from the complexes were determined from dissolution studies using USP XXII paddle method. The formulation, that provided delivery of active material near to the target value in six healthy volunteers and in vivo tests, clearly revealed that the bioavailability of active material was found to be enhanced by preparing ternary mixtures.     

A way for improving the stability of the essential oils in an environmental friendly formulation

The essential oils (EOs) possess amazing properties explaining the interest for their applications in many essential domains. They also present the disadvantage of their chemical instability in the presence of air, light, moisture, and high temperatures. The paper focuses on two of the most known and used EOs, lavender and mint, respectively. The idea of the study was to protect them using the encapsulated systems. The originality of the work consists in the combination between the advantages of the molecular encapsulation of the EOs by cyclodextrins (CD) with the advantages offered by the sol–gel process. Original formulations have been processed by entrapping these essential oils in silica matrices obtained from a colloidal silica sol by the aqueous route of the sol–gel method. Another non-toxic ingredient, β-cyclodextrin, able to form inclusion complexes (ICs) with the essential oils has been used. The characterization methods (chromatography, UV–vis, IR, and NMR spectroscopies) have evidenced the presence of the mentioned inclusion complexes. Due to their formation, which modifies the water solubility of the EOs, the chromatographic analysis was possible using water as solvent, which is a novelty in EOs determinations. Protected from both the cyclodextrin and silica matrix, the essential oils became more resistant versus the effects of the environment factors. Thus, the resulted powders can find applications in domains as agriculture, food industries, cosmetics, pharmaceutical, and medicine.     

Inclusion complexation of artemisinin with alpha-, beta-, and gamma-cyclodextrins

The present study was conducted to investigate the inclusion complexation of artemisinin (ART) with natural cyclodextrins (CyD), namely alpha-, beta-, and gamma-CyDs with the aim of improving its solubility and dissolution rate. Complex formation in aqueous solution and solid state was studied by solubility analysis, dissolution, and thermal analysis. Solubility diagrams indicated that the complexation of ART and the three CyDs occurred at a molar ratio of 1:1, and showed a remarkable increase in ART solubility. Moreover, the thermodynamic parameters calculated by using the van't Hoff equation revealed that the complexation process was associated with negative enthalpy of formation and occurred spontaneously. The complexation capability of CyDs with ART increased in the order of alpha- < gamma- < beta-CyDs and could be ascribed to the structural compatibility between the molecular size of ART and the diameter of the CyD cavities. Dissolution profiles of the three complexes demonstrated an increased rate and extent of dissolution compared with those of their respective physical mixtures and a commercial preparation. In solid-state analysis, using differential scanning calorimetry, the gamma-CyD was capable of complexing the highest percentage of ART, followed by beta- and alpha-CyDs. The respective estimated percentage of ART complexed by the CyDs were 85%, 40%, and 12%.     

Influence of Method of Preparation on Inclusion Complexes of Naproxen with Different Cyclodextrins

Abstract

The aim of this study is to increase the solubility of naproxen by inclusion complex formation with α, β, γ, hydroxypropylbeta and dimethylbetacyclodextrin. The apparent stability constants were calculated from the slope and intercept of the AL-solubility diagrams. The solid inclusion complexes of naproxen with cyclodextrins in 1:1 molar ratio were prepared by the kneaded-mix, spray-drying and freeze-drying method. The formation of inclusion complexes in the solid state were confirmed by X-Ray diffractometry I.R. spectroscopy and differential scanning calorimetry. The dissolution rate of naproxen from the inclusion complexes was much more rapid than naproxen alone. The best results were obtained with β-cyclodextrin inclusion complex prepared by the spray-drying method.