Change of phase-solubility behavior by gamma-cyclodextrin derivatization

Sulfobutylether-β-cyclodextrin

This review presents the early history, the motivation, the research and some of the backstories behind the discovery and development of sulfobutylether-β-cyclodextrin as a novel parenterally safe solubilizer and stabilizer. A specific sulfobutylether-β-cyclodextrin with an average degree of 6.5 sulfobutyl-groups variably substituted on the 2-, 3- and 6-hydroxyls of the seven glucopyranose (dextrose) units of β-cyclodextrin, is known by its commercial name, Captisol®. Today it is in 13 FDA approved injectables and numerous clinical candidates. It is also an example of a novel product discovered and initially preclinically developed at an academic institution.

Determination and tissue distribution studies of dantrolene sodium with hydroxypropyl-β-cyclodextrin in rat tissue by HPLC/MS/MS

The established analytical method for determining the concentration of dantrolene sodium (Da) in rat tissues by HPLC/MS/MS technique was successfully applied to tissue distribution studies of Da in rats. Tissue homogenate samples were pretreated by protein precipitation with pre-cooled methanol. Chromatographic separation was achieved on an Acquity HPLC column (Kromat Universil XB-C₁₈ , 2.1 × 150 mm, 3 μm). Mass spectrometry was conducted with an electrospray ionization interface in negative ionization mode and multiple reaction monitoring was used for quantitative analysis. The results showed that Da was rapidly and widely distributed in tissues and reached the maximum concentration within 0.5 h in all tissues after oral administration of Da-hydroxypropyl-β-cyclodextrin (DHC). It was then metabolized by liver and finally excreted from kidney,which indicated that DHC inclusion complex has better absorption and higher oral bioavailability than Da. The results also provided evidence for the safety and effectiveness of drug clinical application.

Drug Solubilization by Mixtures of Cyclodextrins: Additive and Synergistic Effects

Cyclodextrins are popular drug solubilizers, but the use of the natural cyclodextrins is hampered by their tendency to coprecipitate with the drug. To understand and overcome such problems, we have studied the solubility of dexamethasone in the presence of natural β-cyclodextrin and γ-cyclodextrin, individually and in various combinations. Equilibrium models of the phase-solubility diagrams with individual cyclodextrins revealed that dexamethasone was solubilized as 1:1 complexes, but formation of insoluble higher-order complexes set an upper limit to the concentration of solubilized dexamethasone. This limit could be raised from 8 to 17 mM by using combinations of the two cyclodextrins, as their solubilizing properties were additive in some regions of the phase-solubility diagram and synergistic in other regions. The additive effects arise from the additivity of solubilities-the same phenomenon contributes to the good solubilizing properties of many modified cyclodextrins. The synergistic effects, however, could not be explained. The results open up for an increased use of the natural cyclodextrins as an improved alternative to modified cyclodextrins.

γ-Cyclodextrin

γ-Cyclodextrin (γCD) is a cyclic oligosaccharide formed by bacterial digestion of starch and used as solubilizing agent and stabilizer in a variety of pharmaceutical and food products. γCD is a large (molecular weight 1297Da) hydrophilic molecule that does not readily permeate biological membranes and is rapidly digested by bacteria in the gastrointestinal tract. In humans γCD is metabolized by α-amylase that is found in, for example, saliva, bile fluid and tears. Thus, bioavailability of γCD is negligible. Also, γCD is readily excreted unchanged in the urine after parenteral administration. Like other cyclodextrins, γCD can form water-soluble inclusion complexes with many poorly-soluble compounds. In comparison with the natural αCD and βCD, γCD has the largest hydrophobic cavity, highest water solubility and the most favorable toxicological profile. The focus of this review is production, physiochemical properties, pharmacokinetics, toxicity and applications of γCD and its derivatives. Also, the aggregation behavior of γCD in aqueous media is discussed.

Amorphous Soluble Cyclodextrins: Pharmaceutical and Therapeutic Uses

Amorphous water soluble derivatives of cyclodextrins are potent, nontoxic solubilizers of drugs and lipids. Their use as excipients which enable effective oral administration of sex hormones is described. Furthermore, these com pounds were used intravenously as an active drug to assist an organism in unloading a toxic lipophile.

FT-IR and X-ray spectroscopic investigations of Na-diclofenac-cyclodextrins interactions

The association of DCF-Na (the salt of the 2-[(2,6-dichlorophenyl)amino]-phenyl-acetic acid) with beta-CD (cyclodextrin) in some therapeutic formulas can contribute to the optimisation of the physico-chemical and pharmaceutical properties of the parent drug. The understanding of the interaction between DCF with beta-CD represents the objective of this study. FT-IR spectroscopy is one of the methods which clarify the nature of these interactions in complexes of such type. Therefore the changes in FT-IR spectra of binary dispersed systems DCF/beta-CD in physical mixture and coprecipitate from methanol (molar ratios: 1/1, 1/2, 2/3, 3/4, 7/4) were analysed. The analysis of the broadening of the X-ray powder diffraction line has been applied to investigate the average effective crystallite size, the mean square of the microstrain caused by distortions within beta-CD crystallite and the fault probability in the binary dispersed DCF/beta-CD coprecipitate system.

Effect of alkyl chain length and degree of substitution on the complexation of sulfoalkyl ether beta-cyclodextrins with steroids

This study was designed to test how the sulfoalkyl ether (SAE) modification of beta-cyclodextrin (beta-CD) affects the binding capacity of testosterone and progesterone, thereby enhancing their solubility. The SAE-beta-CD derivatives contain either sulfopropyl ether (SPE) or sulfobutyl ether (SBE) groups on the 2-, 3-, and 6-hydroxyl positions of the dextrose moieties. SAE-beta-CDs are a mixture of positional and regional isomers containing from one to as many as 12 SAE groups per CD. The effect of chain length and the degree of substitution on complexation behavior was investigated by the phase-solubility method. The results were compared with those obtained with beta-CD, where possible, and with hydroxypropyl-beta-CD (HP-beta-CD). To determine the effect of degree of substitution (DS) on the binding, mixtures of SAE-beta-CDs with multiple substitution levels and varying average degrees of substitution were studied as well as mixtures of SAE-beta-CDs that contained the same degree of substitution. Mixtures that contained SAE-beta-CDs of the same degree of substitution were isolated from the multiple substitution level mixtures by ion-exchange chromatography and purified for investigation. Unlike the parent beta-CD, linear increases in the apparent solubilities of testosterone and progesterone were observed, and the binding potentials were comparable to those of beta-CD or better. The results demonstrate that the binding potentials of the SAE-beta-CD derivatives were dependent on the guest molecule, the degree of substitution, and the alkyl ether chain length. Our previous study showed the inhibition of complexation by direct sulfonation of the beta-CD. However, in the present work, interferences with the charged sulfonate groups were avoided by repositioning them away from the cavity. Increasing the degree of substitution assisted in complex formation; however, its effects were limited. Reduction of the alkyl chain length, as in the case of SPE-beta-CD compared with SBE-beta-CD, decreased the complexation potential. This decrease in complexation potential was further suppressed with an increase in the number of substituents placed on the CD torus. Generally, the binding potential of SAE-beta-CD derivatives increased with increasing alkyl chain length. However, placement of more than an optimum number of SAE groups on the CD torus resulted in inhibition of complexation.

Cyclodextrin sulfates: characterization as polydisperse and amorphous mixtures

Alpha- and beta-cyclodextrins and their hydroxypropyl derivatives were converted by the reaction with chlorosulfonic acid in pyridine to the corresponding sulfates. Cyclodextrin sulfates were shown by fast-atom bombardment mass spectrometry (negative ion mode, triethanolamine matrix) to be mixtures with nearly symmetrical distributions of degree of substitution by sulfate groups and by powder X-ray diffraction to be amorphous. Thus, in these aspects, cyclodextrin sulfates are similar to the potent drug solubilizers hydroxypropylcyclodextrins.

Pharmaceutical usefulness of hydroxypropylcyclodextrins: "e pluribus unum" is an essential feature

A series of hydroxypropyl-beta-cyclodextrins was prepared by a method that leads to a preferential substitution on the secondary hydroxyls, mainly O-2, of beta-cyclodextrin with (S)-2-hydroxypropyl groups. The series consisted of mixtures of compounds with average degrees of substitution of 8, 3, and 1.6 and of a specially isolated monosubstituted compound; thus, the number of components progressively decreased in this series. The crystallinity in the series increased progressively, the first member being fully amorphous and the last one fully crystalline. All members of the series formed clear aqueous solutions at concentrations of greater than 50.0, 2.0, 0.6, and 0.3%, respectively. Therefore, pharmaceutically useful hydroxypropylcyclodextrin preparations are those containing a large number of chemically individual compounds--a feature resulting in an amorphous state and high water solubility.

Effect of cyclodextrin derivatives on indomethacin stability in aqueous solution

The effect of various cyclodextrins (CD) and cyclodextrin derivatives on indomethacin stability in phosphate buffer, pH 7.4, was investigated. The influence of CD-ring size, type of substituent, degree of substitution, substitution pattern, and influence of CD concentration were monitored. The indomethacin complex in solution was studied by 1H-NMR spectroscopy to develop a molecular inclusion model. The most favorable ring size for the stabilization of indomethacin was the beta-CD. The beta-CD derivatives inhibited the hydrolysis of indomethacin more effectively than the parent CD. Among the studied CD derivatives, those with lipophilic substituents, such as ethyl or methyl, were superior to those with hydrophilic substitutents. The more hydroxyl groups of the glucose moiety are substituted, the better is the stabilizing effect. Further, the p-chlorobenzoic part of the indomethacin molecule is included in the CD channel.

Amorphous water-soluble cyclodextrin derivatives: 2-hydroxyethyl, 3-hydroxypropyl, 2-hydroxyisobutyl, and carboxamidomethyl derivatives of beta-cyclodextrin

The pharmaceutical usefulness of natural, crystalline cyclodextrins can be improved by chemical conversions into water-soluble, amorphous mixtures of their derivatives. Reaction of beta-cyclodextrin with 2-chloroethanol, 3-chloropropanol, isobutylene oxide, or iodoacetamide yielded the title compounds. Distributions of the substitution degree were close to symmetrical and relatively narrow. The average substitution degrees increased with the amount of alkylating reagent used in the preparation. The number of components (half-width of distribution) increased with increasing average substitution degree. Further, distributions of the substitution degree were measured in glucose derivatives after hydrolysis of 2-hydroxyethyl, 2-hydroxypropyl, and 2-hydroxyisobutyl-beta-cyclodextrin. The results show an uneven distribution of substituents around the cyclodextrins, suggesting that growth of oligoglycol side chains and/or clustering of substituents on one glucose residue occurs.

Drug solubilizers to aid pharmacologists: amorphous cyclodextrin derivatives

Conversion of crystalline alpha-, beta-, or gamma-cyclodextrins into amorphous mixtures of water soluble derivatives yields non-toxic solubilizers which dissolve drugs through the formation of inclusion complexes. From these types of compounds 2-hydroxypropyl ethers of cyclodextrins have presently been investigated and the ranges for the safe use in working with (a) receptor binding assays on membrane preparations, (b) cells in vitro, and (c) parenteral use in mice were established for these compounds. The drugs which were investigated were dissolved in amounts linearly proportionate to the concentration of the solubilizers used and did not precipitate upon dilution by aqueous media. These solubilizers may considerably facilitate pharmacological evaluation of new, water insoluble potential drugs.

gamma-Cyclodextrin:testosterone complex suitable for sublingual administration

A crystalline complex of testosterone with gamma-cyclodextrin was evaluated for solubility and dissolution rate. Whereas these parameters were at least an order of magnitude lower than those of testosterone complexes with amorphous derivatives of cyclodextrins, the properties of the crystalline complex enabled the preparation of a suitable pharmaceutical form for the sublingual administration of hormone to humans. This is in contrast to the situation with similar beta-cyclodextrin complexes, in which such administration was ineffective. Sublingual administration of the gamma-cyclodextrin complex, as shown in previous work using amorphous complexes, avoided rapid first-pass loss of hormone and directed it effectively into the circulation; administration of the complex into the stomach resulted in much lower circulatory hormone levels.

Hydroxypropyl-beta-cyclodextrin derivatives: influence of average degree of substitution on complexing ability and surface activity

The average degree of substitution of mixtures of hydroxypropyl-beta-cyclodextrin derivatives has a large influence on the complexing abilities and physiochemical properties of the derivatives. A low degree of substitution is preferable, since these derivatives show the best complexing properties and, at the same time, low surface activities.