Solubilization of Glibenclamide with β-Cyclodextrin & its Derivatives

Abstract

Gilbenclamide, a widely used potent hypoglycaemic agent was solubllized using β -Cyclodextrin and β -Cyclodextrin derivatives. Complexes were prepared by kneading method in a molar ratio of 1:1 of the drug and the cyclodextrlns respectively. The Glibenclamide β -Cyelocextrin complex was characterized and evaluated by I.R. studies, Differential Scanning Calorimotry 6 X-ray diffractometry. The in-vitro dissolution rates of drug from inclusion complexes of β Cyclodextrins and its derivatives were compared. A significant Improvement In dissolution lor, rates of Gllbenclamide was observed with Inclusion complexes of all the Cyclodextrins. However, the solubilizing effect was more in case of β-Cyclodextrin derivatives.     

Comparative study on Inclusion compounds of 4-Biphenylacetic acid with β-Cyclodextrin, Hydroxypropylated-β-Cyclodextrins, and methylated-β-Cyclodextrins

The inclusion behavior of Hydroxypropyl-β-Cyclodextrin (HP-β-Cyd) and of methylated-β-Cyclodextrins, heptakis-(2,6-di-O-methyl)-β-Cyclodextrin (DM-β-Cyd) and heptakis-(2,3,6-tri-O-methyl)-β-Cyclodextrin (TM-β-Cyd), in solution and solid state was compared with that of natural β-Cyclodextrin (β-Cyd) using an anti-inflammatory drug, 4-biphenylacetic acid (BPAA), as a guest molecule. The solubility of BPAA with β-Cyd and β-Cyd derivatives in aqueous solution were determined. Stability constants were calculated by phase solubility method at various pH values and temperatures. The formation of inclusion complexes with β-Cyd and β-Cyd derivatives in the solid slate were confirmed by infrared spectroscopy, differential scanning calorimetry and X-Ray diffractometry, and in the liquid phase by ultraviolet spectroscopy, circular dichroism and NMR studies. Dissolution rate and “in vitro” release of BPAA from complexes were examined. The results obtained suggest that DM-β-Cyd is more effective than other β-Cyclodextrins in improving the pharmaceutical properties of BPAA.     

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.     

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.     

Inclusion Complexation of Lorazepam with β — Cyclodextrin

The preparation of an inclusion complex of Lorazepam, a benzodiazepine antianxiety agent with β -cyclodextrin is described. The inclusion compound was prepared by the homogeneous coprecipitation method in the molar ratio of 1:2 of the drug and β -cyclodextrin respectively. The formation of inclusion complex was evaluated by UV spectral studies, IR studies, X-ray diffractometry, and Differential Thermal Analysis. The solubility and in-vitro drug release studies indicated that the complex form of the drug significantly increase the solubility and the dissolution rate compared to the free form. Tablets prepared with Lorazepam- β -cyclodextrin complex also showed a significant increase in dissolution of the drug indicating that P-cyclodextrin plays an important role in the solubilization of the drug.     

Solubility and dissolution rate of progesterone-cyclodextrin-polymer systems

This contribution focused on the solubility improvement of the poorly water-soluble steroid hormone progesterone which, in its natural state, presents a reduced oral bioavailability. In the first part of this study, two simple, reproducible methods that were candidates for use in the preparation of inclusion complexes with cyclodextrins were investigated. Solubility capacities of the progesterone complex with hydroxypropyl-β-CD (HPβ-CD), hydoxypropyl-γ-CD (HPγ-CD), permethyl-β-CD (PMβ-CD), and sulfobutylether-β-CD (SBEβ-CD), prepared by the freeze-drying and precipitation methods, were evaluated by Higuchi phase solubility studies. The results showed that HPβ-CD and PMβ-CD were the most efficient among the four cyclodextrins for the solubilization of progesterone, with the highest apparent stability constants. Therefore, dissolution studies were conducted on these latest progesterone/cyclodextrin complexes and physical mixtures. Two additional natural cyclodextrins, β-CD and γ-CD, were taken as references. Hence, the influence of more highly soluble derivatives of β-CD (HPβ-CD, PMβ-CD) on the progesterone dissolution rate, in comparison to pristine β-CD, alongside an increase in the cavity width for γ-CD versus β-CD, were investigated. The dissolution kinetics of progesterone dissolved from HPβ-CD, PMβ-CD, and γ-CD revealed higher constant rates in comparison to β-CD. Therefore, the aim of the second part of this study was to investigate the possibility of improving the dissolution rate of progesterone/β-CD binary systems upon formation of ternary complexes with the hydrophilic polymer, PEG 6000, as β-CD had the smallest progesterone solubility and dissolution capacity among the four cyclodextrins studied (β-CD, HPβ-CD, HPγ-CD and PMβ-CD). The results indicated that dissolution constant rates were considerably enhanced for the 5% and 10% progesterone/β-CD complexes in PEG 6000.

The interaction of progesterone with the cyclodextrins of interest on the form of the binary physical mixtures, complexes, or ternary complexes were investigated by differential scanning calorimetry (DSC) and Fourier transformed-infrared spectroscopy (FT-IR). The results proved that progesterone was diffused into the cyclodextrin cavity, replacing the water molecules and, in case of ternary systems, that the progesterone β-cyclodextrin was well dispersed into PEG, thus improving progesterone bioavailability for subsequent oral delivery in the same way as derivatized cyclodextrins. The present work proves that ternary complexes are promising systems for drug encapsulation.     

Effects of Cyclodextrins and Phospholipids in Enhancing Dissolution of Indomethacin

Inclusion complexes of indomethacin (IND) and β-cyclodextrins (β-CD) were prepared by the freeze drying methods. Solid dispersion of IND and Dimyristoylphosphatidylcholine (DMPC) was prepared as coprecipitate (CPPT) by the solvent method. These formulations were characterized by X-ray diffractometry and dissolution rate determinations. Dissolution of IND from β-CD inclusion complex was found to be 133 times faster than the corresponding pure IND, whereas it was about 4 times faster from a DMPC CPPT sample. Various derivatives of β-CDs showed variable rates of dissolution of IND. β-CD and most of the other derivatives showed almost instantaneous dissolution of IND at a molar ratio of 1:1 (IND:β-CD) except dimethyl-β-cyclodextrin (DMB) derivative, which showed a fairly constant release of IND over 90 minutes. DMB may, therefore, have the potential for use in the formulation of a constant-release preparation. X-ray diffraction spectra showed that indomethacin remained as amorphous state in CPPT or in inclusion complex. Thus, these formulations may have the potential to produce faster onset of action, reduced dosing and decreased GI irritation.     

Study of Surfactants/β-Cyclodextrin Interactions Over Mequitazine Dissolution

Surfactant/β-cyclodextrin interactions were investigated by studying the dissolution of mequitazine in different binary (aqueous solutions of β-CD or surfactants) and ternary (aqueous solution of β-CD and surfactants) dissolution media. Results were compared with those obtained from binary media with 50, 250, and 500 mg of surfactants (preceding paper). Results show that there is an interaction between β-cyclodextrin and surface-active agent, and that the type and extent of interaction are controlled by the nature and the amount of the surface-active agent. A decrement in drug dissolution rate was obtained from all of the ternaly media containing β-cyclodextrin and sodium lauryl sulfate as surfactant in the ratio of 1:1 mol/mol. These facts suggest that sodium lauryl sulfate and β-cyclodextrin form an inclusion compound in the molecular ratio of 1:1.     

Inclusion of Methoxybutropate in β-and Hydroxypropyl β-Cyclodextrins: Comparison of Preparation Methods

Interactions between methoxybutropate and β-cyclodextrin or hydroxypropyl β-cyclodextrin and the possibility of obtaining inclusion complexes have been evaluated by phase solubility diagram, HPLC, DSC, and x-ray diffractometry. Solid inclusion complexes were prepared by spray drying, kneading, and solid dispersion. The dissolution profiles of the obtained powders were studied in order to define the most appropriate cyclodextrin preparation method and molar ratio to use in the production of methoxybutropate inclusion complexes     

Inclusion complexation of nimesulide with beta-cyclodextrins

Nimesulide (NM), a nonsteroidal anti-inflammatory drug (NSAID) has poor aqueous solubility. The present study describes the complexation of NM with β-cyclodextrin (β-CD) and its derivative hydroxypropyl β-cyclodextrin (HPβ-CD). The complexation was studied by phase solubility method, Fourier transformed infrared (FTIR) spectroscopy, differential scanning calorimetry (DSC), and X-ray diffractometry (XRD). The complexes were prepared by a freeze-drying technique. The in vitro dissolution rate of drug-HPβ-CD complex was faster compared to the drug-β-CD complex and drug alone.     

Influence of the substitution of β-cyclodextrins by cationic groups on the complexation of organic anions

The inclusion complexation of the organic anion, dansyl-acid, by cationic derivatives of β-cyclodextrin has been investigated. A series of cationic β-cyclodextrins with various positive charge has been synthesized by selective functionalization of the primary face of β-cyclodextrin with amino groups. The complexes were of the 1:1 stoichiometry; the stability constants (K₁₁) have been evaluated from UV–Vis measurements by application of the Benesi–Hildebrand equation. The presence of amino groups increased the complexation ability. β-cyclodextrin fully substituted at the primary face with amino groups showed the strongest inclusion binding ability towards the dansyl-acid guest. The enhanced complexation for anions was ascribed to the cationic amino groups. A simple thermodynamic model of the electrostatic contribution to the complexation is presented.     

Influence of Hydroxypropyl β-Cyclodextrin on Solubility and Dissolution Profile of Ketoprofen in Its Solid Dispersions

Solid dispersions of hydroxypropyl β-cyclodextrins (HPB), a highly water soluble derivative of β-cyclodextrin and ketoprofen (KPF), were prepared by kneading, coevaporation, and freeze-drying. X-ray diffraction, differential scanning calorimetry, and scanning electron microscopy were used to investigate characteristics of the solid dispersions and to study the possibility of complexation of the drug with HPB. A marked difference in characteristics of dispersions was observed due to their methods of preparation. The solubility of KPF in the solid dispersions was studied by the dispersed powder technique and was found to have improved considerably over that of the drug pure alone. The dispersions had good compressibiliry. Tablets so compressed displayed good dissolution profiles.     

Inclusion Complexes of Terfenadine-Cyclodextrins

Terfenadine, a poorly soluble, H₁-antihistamine was solubilised using B-cyclodextrin and its derivatives. A molar ratio of 1:1 of the drug and cyclodextrin was prepared by the kneading method. The inclusion complex was characterised and evaluated by Differential Scanning Calorimetry & X-ray Diffractometry. In vitro dissolution profile of the inclusion complex was studied. Dissolution rates of the drug-cyclodextrin complexes were more as compared to the drug alone. An attempt was also made to prepare a palatable syrup of terfenadine-cyclodextrin complex. Various combination of co-solvents and additives were used to formulate a stable and an acceptable liquid oral.     

Inclusion of Vitamin D2 in β-Cyclodextrin. Evaluation of Different Complexation Methods

Evaluation of inclusion complexation of vitamin D2 with β-cyclodextrin in aqueous solution and solid state was performed by Phase Solubility Diagramm, HPLC, DSC, X-RAY Diffractometry, NMR. Solid inclusion complexes were prepared by spray-drying, kneading and solid dispersion. The dissolution profiles of the complex either in powder or in tablets were studied in order to select the best inclusion process.     

Inclusion Complexation of 4-Biphenylacetic Acid with β-Cyclodextrin

The preparation of an inclusion complex of 4-biphenylacetic acid (BPAA), a non-steroidal antiinflammatory drug, with β-cyclo-dextrin is described. The presumible structure of the inclusion system, the molar ratio, which was found 1:1, and the formation constant were calculated by the analysis of IR, UV, DSC, X-ray diffraction, and ¹H-NMR. Dissolution rate and solubility were also studied. BPAA solubility in water resulted significantly (4,2-fold) increased by complexation, such as its dissolution rate which appears, in the first 12 min, 18 times greater for the complex than the drug alone.     

The influence of diluent on the release of theophylline from hydrophilic matrix tablets

The role of β-cyclodextrin (β-CD) on the apparent solubility of theophylline was investigated by the solubility method. Binary systems of theophylline and β-CD were prepared using the dry co-grinding method. Their characterization was performed by differential scanning calorimetry (DSC). The dissolution rate of theophylline and theophylline/β-CD and dissolution studies of matrix tablets prepared from mixtures containing theophylline and ground theophylline were carried out. It can be concluded that β-CD is related to an increase in the apparent solubility and dissolution rate of the drug, promoting improvement on the release of theophylline from matrices manufactured with hydroxypropylmethylcellulose (HPMC). This can be attributed to the amorphous state and the increased wettability of the drug.     

Effect of Grinding of β-Cyclodextrin and Glibenclamide on Tablet Properties. Part I. in vitro

Physical properties including dissolution characteristics of glibenclamide (GB) tablets were studied. Directly compressed and wet-granulated GB tablets gave only 35% and 40% drug dissolved, respectively. Physical mixing, kneading, and grinding of β-cyclodextrin (CD) with GB were investigated. It was found that the grinding method could markedly enhance the release of drug from the tablets. The physical properties of these tablets were unchanged after they had been stored at 40°C and 75% RH for at least 3 months. The GBKD mixture at a ratio of 1 to 4, ground for 24 or 48 hr, exhibited superior dissolution and chemical stability. Differential scanning calorimetry indicated that an inclusion complex was produced. Decreasing grinding time or CD concentration could result in incomplete formation of the inclusion complex. It was concluded that pretreatment of the drug with CD by the grinding method could significantly improve the dissolution and stability of GB tablets.     

Development of fast-dissolving tablets of flurbiprofen-cyclodextrin complexes

The present study was aimed at developing a tablet formulation based on an effective flurbiprofen-cyclodextrin system, able to allow a rapid and complete dissolution of this practically insoluble drug. Three different cyclodextrins were evaluated: the parent β-cyclodextrin (previously found to be the best partner for the drug among the natural cyclodextrins), and two amorphous, highly soluble β-cyclodextrin derivatives, i.e., methyl-β-cyclodextrin and hydroxyethyl-β-cyclodextrin. Equimolar drug-cyclodextrin binary systems prepared according to five different techniques (physical mixing, kneading, sealed-heating, coevaporation, and colyophilization) were characterized by Differential Scanning Calorimetry, x-ray powder diffractometry, infrared spectroscopy, and optical microscopy and evaluated for solubility and dissolution rate properties. The drug solubility improvement obtained by the different binary systems varied from a minimum of 2.5 times up to a maximum of 120 times, depending on both the cyclodextrin type and the system preparation method. Selected binary systems were used for preparation of direct compression tablets with reduced drug dosage (50 mg). Chitosan and spray-dried lactose, alone or in mixture, were used as excipients. All formulations containing drug-cyclodextrin systems gave a higher drug dissolved amount than the corresponding ones with drug alone (also at a dose of 100 mg); however, the drug dissolution behavior was strongly influenced by formulation factors. For example, for the same drug-cyclodextrin product the time to dissolve 50% drug varied from less than 5 minutes to more than 60 minutes, depending on the excipient used for tableting. In particular, only tablets containing the drug kneaded with methyl-β-cyclodextrin or colyophilized with β-cyclodextrin and spray-dried lactose as the only excipient satisfied the requirements of the Food and Drug Administration (FDA) for rapid dissolving tablets, allowing more than 85% drug to be dissolved within 30 minutes. Finally, it can be reasonably expected that the obtained drug dissolution rate improvement will result in an increase of its bioavailability, with the possibility of reducing drug dosage and side effects.     

Multicomponent complexes of piroxicam with cyclodextrins and hydroxypropyl methylcellulose

The purpose of the study was to investigate the effect of hydroxypropyl methylcellulose (HPMC) on the complexation of piroxicam (PX) with β-cyclodextrin (β-CD) and dimethyl-β-cyclodextrin (DM-β-CD) in solution and in the solid state. Phase solubility study revealed a positive effect of the polymer on the drug complexation. Improvement in stability constants values, K_s, of ternary complexes clearly proves the benefit of the HPMC addition for promoting higher complexation efficiency. Solid binary and ternary complexes were prepared by spray drying. Drug-CD and drug-CD-polymer interactions were studied in the solid state by differential scanning calorimetry (DSC), zeta-potential measurements, and particle size distribution. A marked increase in the PX dissolution rate was observed even in binary and ternary complexes. The presence of HPMC in ternary complexes slightly retarded the release of PX. Cyclodextrin complexation increased the PX concentration gradient over the semipermeable membrane, resulting in an increased PX flux. The retarded diffusion of PX to the membrane interface decreased the PX flux values of the ternary complexes.     

The Dislocation Structure of a Single-Crystal γ + γ′ Two-Phase Alloy After Tensile Deformation

The dislocation structures of an industrial single-crystal γ + γ′ two-phase alloy DD3 after tensile deformation from room temperature to 1273K were studied by transmission electron microscopy. The strength of this alloy decreased with an increase in the temperature, and showed a strength peak at 1033K. At room temperature, the dislocations shearing the γ′ particles were found to be 1/3<112> partial dislocations on the dodecahedral slip system <112>{111}. Some dislocation pairs on the cubic <110>{100} system that blocked the glide of dislocations were found at a medium temperature of 873K. As a result, dislocation bands were formed. Shearing of γ′ particles by 1/3<112> partial dislocations on the dodecahedral slip system <112>{111} was also found at this temperature. At the peak temperature of 1033K, because of the strong interaction between dislocations on the {111} and {100} planes, the extent of dislocation bands with high dislocation densities was extensive. The 1/3<112> partial dislocations on the dodecahedral slip system <112>{111} also existed. When the temperature reached the high temperature of 1133K, the range of dislocation bands was limited. The γ′ particles were sheared by <110> dislocation pairs on the octagonal <110>{111} system and the cubic <110>{100} system. At 1273K, the regular hexagonal dislocation networks were formed in the γ matrix and at the γ/γ′ interface. The Burgers vectors of the network were found to be b₁ = 1/2[110], b₂ = 1/2[1–10], b₃ = [100], and the last one was formed by the reaction of b₁ + b₂ → b₃. Dislocations shearing the γ′ particles were found to be <110> dislocation pairs on the octagonal system <110>{111} and cubic slip system <110>{100} at 1273K.