Sustained Release Matrix of Mebeverine Hydrochloride Using Polyacrylate Resin “Eudragit Retard” Kinetic of Drug Release and Evaluation of a Kinetic Model

Abstract

In this study Eudragit RS PM and RL PM were evaluated as carriers for the preparation of prolonged release solid dispersions of mebeverine hydrochloride by solvent and melting methods. The prepared tablets were examined for dissolution at pH 1.2 and 7.4, Eudragit RS PM and RL PM were found satisfactory as potential slow release carriers. The solid dispersion prepared by the solvent method showed a slow release pattern. Drug release appeared to fit both, first order and Higuchi matrix model kinetics. However, on application of the differential rate treatments, the evidence supported the Higuchi matrix model. Effect of temperatures on dissolution rate was studied for thermodynamic consideration.

The drug release was pH-independent until pH 7.4.As the pH increased, the release was significantly reduced due to solubility problem.     

Preparation and Preliminary Evaluation of Eudragit RL and RS Pseudolatices for Controlled Drug Release

Eudragit RL and RS pseudolatices were prepared by the solvent change technique, which consisted of dissolving the polymer in a water miscible organic solvent or in a mixed water miscible organic solvent system, followed by dispersian in deionized water under mild agitation. The organic solvent (s) was removed from the aqueous organic solution to leave a stable Eudragit latex.

Eudragit pseudolatex coated theophylline pellets were prepared in a fluidized-bed coating machine. The effects of polymer type and coating level, plasticizer concentration, and PH of the dissolution medium on drug release were investigated. The higher content of quaternary ammonium groups attached to the polymer backbone make the coatings produced from Eudragit RL too water sensitive; and hence unsuitable for controlling theophylline release. On the other hand, Eudragit RS films retarded theophylline release. On the other hand, Eudragit RS films retarded theophylline release over a wide pH range. Release of the drug was found to be a function of the polymer coating level, plasticizer concentration and dependent on pH of the dissolution medium.     

Eudragit Microcapsules of Nifedipine and Its Dispersions in HPMC-MCC: Physicochemical Characterization and Drug Release Studies

Nifedipine and its solid dispersions in hydroxypropyl methyl cellulose-microcrystalline cellulose (HPMC-MCC) were microencapsulated with Eudragit RL PM by an emulsion solvent evaporation method. The microcapsules are spherical, discrete, free flowing, and covered with a continuous coating of the polymer. XRD and DTA indicated the presence of nifedipine in solution form in the solid dispersions and their microcapsules. No chemical interaction between nifedipine and excipients in the microcapsules was observed. Nifedipine as such and its microcapsules gave very slow release because of its highly crystalline nature and poor solubility. Solid dispersion in HPMC-MCC gave fast and rapid dissolution of nifedipine. When these solid dispersions were microencapsulated a slow, controlled, and complete release over a period of 12 hr was observed from the resulting microcapsules. Drug release depended on the proportion of HPMC-MCC in the solid dispersion used as a core, coat, core ratio, and size of the microcapsules. Release was independent of pH and ionic strength. Drug release was governed by diffusion rate and followed first-order kinetics.     

Development of Diclofenac Sodium Controlled Release Solid Dispersions by Spray Drying Using Optimization Strategy I. Powder Formulation

Diclofenac sodium (DS) controlled release solid dispersions were prepared by spray drying using ethylcellulose (EC), methacrylic acid copolymer (Eudragit), chitosan, hydroxypropyl methylcellulose (HPMC), and carbomer as single carriers and EC-chitosan as combined carriers. Among solid dispersions of 3:1 drugsingle carrier, the system containing chitosan exhibited the slowest dissolution followed by the systems containing Eudragit, EC, HPMC, and carbomer, respectively. Combined carriers of EC-chitosan exhibited more dissolution retarding effect than single carrier of EC or chitosan. An Hadamard matrix H[8] was employed to estimate the main effects of four parameters: spray feeding volume and contents of absolute ethanol, EC, and chitosan. Optimization strategy using multiple linear regression and a feasibility computer program was utilized to obtain the optimum quantities of the four parameters that would result in a required DS controlled release solid dispersion. The validation of the optimum DS solid dispersion was confirmed by statistical analysis. The optimized 10: (2.5+0.02) DS:(EC+chitosan) controlled release solid dispersion exhibited a dissolution profile that was well fitted to Higuchi model.     

Development of Diclofenac Sodium Controlled Release Solid Dispersions by Spray Drying Using Optimization Strategy I. Powder Formulation

Abstract

Diclofenac sodium (DS) controlled release solid dispersions were prepared by spray drying using ethylcellulose (EC), methacrylic acid copolymer (Eudragit), chitosan, hydroxypropyl methylcellulose (HPMC), and carbomer as single carriers and EC-chitosan as combined carriers. Among solid dispersions of 3:1 drugsingle carrier, the system containing chitosan exhibited the slowest dissolution followed by the systems containing Eudragit, EC, HPMC, and carbomer, respectively. Combined carriers of EC-chitosan exhibited more dissolution retarding effect than single carrier of EC or chitosan. An Hadamard matrix H[8] was employed to estimate the main effects of four parameters: spray feeding volume and contents of absolute ethanol, EC, and chitosan. Optimization strategy using multiple linear regression and a feasibility computer program was utilized to obtain the optimum quantities of the four parameters that would result in a required DS controlled release solid dispersion. The validation of the optimum DS solid dispersion was confirmed by statistical analysis. The optimized 10: (2.5+0.02) DS:(EC+chitosan) controlled release solid dispersion exhibited a dissolution profile that was well fitted to Higuchi model.     

Preparation, Physical Characterization, Mechanisms of Drug/Polymer Interactions, and Stability Studies of Controlled-Release Solid Dispersion Granules Containing Weak Base as Active Substance

Verapamil hydrochloride solid dispersion granules were prepared using solvent evaporation technique. Ethyl cellulose, hydroxypropyl cellulose, Eudragit L or Eudragit S were used as polymers for controlling the dissolution rate of the drug substance, and to avoid the continuous decrease of drug dissolution rate at higher pH values. By incorporating Eudragit L in ethyl cellulose network it is possible to prepare controlled-release formulation with increased release rate of active substance (weak base) at higher pH values without causing abrupt drug release at lower pH values. The release rate at low pH values was not highly influenced by Eudragit L content. The behavior of Eudragit L and Eudragit S in coprecipitates was different relating to the solubilization effect and the release of active substance. In order to understand the drug release mechanism better, the release data were tested assuming Higuchi model and first-order kinetic model. Since the calculated correlation coeflcients were very close for both kinetics, to distinguish between the mechanisms the differential forms of first-order and square root of time equation were used. The differential test showed that diffusion-controlled release was operative in solid dispersions, except for series with higher content of Eudragit S. X-ray powder difSraction method, IR spectroscopy studies, and differential thermal analysis were used for physical characterization of coprecipitates and drugpolymer interaction evaluation. After 24 months of real time stability studies, the prepared coprecipitates were still x-ray amorphous, with no changes in their IR spectra and DTA studies. Ehe dissolution rates of the tested formulations showed no significant changes during the stability studies, reflecting the stability of x-ray amorphous drug phase.     

Eudragit Microcapsules of Nifedipine and Its Dispersions in HPMC-MCC: Physicochemical Characterization and Drug Release Studies

Abstract

Nifedipine and its solid dispersions in hydroxypropyl methyl cellulose-microcrystalline cellulose (HPMC-MCC) were microencapsulated with Eudragit RL PM by an emulsion solvent evaporation method. The microcapsules are spherical, discrete, free flowing, and covered with a continuous coating of the polymer. XRD and DTA indicated the presence of nifedipine in solution form in the solid dispersions and their microcapsules. No chemical interaction between nifedipine and excipients in the microcapsules was observed. Nifedipine as such and its microcapsules gave very slow release because of its highly crystalline nature and poor solubility. Solid dispersion in HPMC-MCC gave fast and rapid dissolution of nifedipine. When these solid dispersions were microencapsulated a slow, controlled, and complete release over a period of 12 hr was observed from the resulting microcapsules. Drug release depended on the proportion of HPMC-MCC in the solid dispersion used as a core, coat, core ratio, and size of the microcapsules. Release was independent of pH and ionic strength. Drug release was governed by diffusion rate and followed first-order kinetics.     

Formulation and Release Kinetics of Sustained Release Phenylpropanolamine Hydrochloride Granules and Tablets

Abstract

Sustained release phenylpropanolamine hydrochloride (PPH) granules and tablets were prepared using HPMC, HPMC and SCMC, Eudragit RS, Eudragit RS+L or HPMC + Eudragit RS matrices. The release pattern of PPH from the prepared granules and tablets was found to be in the following order HPMC > HPMC + SCMC > RS > RS + 1> HPMC + RS. The results revealed that, although the drug concentration was kept constant in all the prepared granules and tablets, the drug release from these formulations was clearly different and depends mainly on the type of matrix used. The presence of Eudragit L with Eudragit RS and Eudragit RS with HPMC resulted in a marked decrease in the drug release compared with that obtained from the matrix containing HPMC or Eudragit RS alone. The release data of PPH from the prepared granules and tablets were treated mathematically according to zero order, first order, Langenbuchar, modified Langenbucher and Higuchi models. The results revealed that no one model was able adequately to describe the drug release profiles from these formulations. In-vivo studies in human volunteers showed that, the peak urinary excretion of PPH occurred over a sustained period from 2 to 6.5 hr in case of HPMC + SCMC tablets and from 2 to 10 hr in case of either RS+L or HPMC + RS tablets.     

Influence of Formulation and Other Factors on the Release of Chlorpheniramine Mateate from Polymer Coated Beads

Controlled release beads containing chlorpheniramine maleate, coated with Eudragit RL and RS, were prepared using the Wurster process. The effect of membrane thickness, polymer ratio of the coating material, agitation speed and pH of the dissolution medium on drug release were investigated using the USP dissolution basket method. The in vitro release of drug was described adequately by a previously published equation. The release rate constant (K) was dependent on the membrane thickness, the polymer ratio and pH of the dissolution medium. On the other hand, agitation speed used in this study did not have any influence on the release of the drug.     

Controlled Release Theophylline Tablet with Acrylic Polymers Prepared by Spray-Drying Technique in Aqueous System

Sustained release and enteric theophylline tablets were prepared by directly compressing spray-dried microsphers with Eudragits L30D, L100-55 and E30D. The spray-drying process was free from using organic solvent. Drug dissolution of the enteric tablet in an acidic solution (pH 1.2) was highly dependent on the polymer content of the microsphere. Completely enteric function was observed with drug-to-polymer ratio of 1:3 using Eudragit L30D or L100-55. Tablet with Eudragit E30D formulated at the 2-40% level showed good sustained drug release which was throughly independent of the pH of dissolution media. The dissolution pattern was similar to that of Theo-dur and gave a straight line in Higuchi plot. In each tablet, the controlled drug release was attributed to continuous and well-dispersed polymer matrix formed by spray-drying and subsequent compressing process     

Influence of Formulation and Other Factors on the Release of Chlorpheniramine Mateate from Polymer Coated Beads

Abstract

Controlled release beads containing chlorpheniramine maleate, coated with Eudragit RL and RS, were prepared using the Wurster process. The effect of membrane thickness, polymer ratio of the coating material, agitation speed and pH of the dissolution medium on drug release were investigated using the USP dissolution basket method. The in vitro release of drug was described adequately by a previously published equation. The release rate constant (K) was dependent on the membrane thickness, the polymer ratio and pH of the dissolution medium. On the other hand, agitation speed used in this study did not have any influence on the release of the drug.     

Controlled Release Theophylline Tablet with Acrylic Polymers Prepared by Spray-Drying Technique in Aqueous System

Abstract

Sustained release and enteric theophylline tablets were prepared by directly compressing spray-dried microsphers with Eudragits L30D, L100-55 and E30D. The spray-drying process was free from using organic solvent. Drug dissolution of the enteric tablet in an acidic solution (pH 1.2) was highly dependent on the polymer content of the microsphere. Completely enteric function was observed with drug-to-polymer ratio of 1:3 using Eudragit L30D or L100-55. Tablet with Eudragit E30D formulated at the 2–40% level showed good sustained drug release which was throughly independent of the pH of dissolution media. The dissolution pattern was similar to that of Theo-dur and gave a straight line in Higuchi plot. In each tablet, the controlled drug release was attributed to continuous and well-dispersed polymer matrix formed by spray-drying and subsequent compressing process     

The Release Rate of Indomethacin from Solid Dispersions with Eudragite

The coprecipitates were prepared by a solvent technique using Eudragit E as carrier and indomethacin as a model drug.

X-Ray diffractometry, differential scanning calorimetry (DSC) and wettability tests were employed to investigate the physical state of the studied formulations. Up to 50% of indomethacin can be dispersed in an amorphous state in Eudragit E.

The influence of the pH on the in vitro release of solid dispersions has been evaluated. Because of the good solubility of Eudragit E at pH 1.2 a fast dissolution rate of the drug was observed while a marked delay was noticed at pH 7.5 where the polymer is only permeable to water. At pH 5.8 the kinetics of drug release can be modulated by the drug/polymer ratio. The dissolution rate of the drug can be increased by decreasing its amount in the coevaporate.     

The Release Rate of Indomethacin from Solid Dispersions with Eudragite

Abstract

The coprecipitates were prepared by a solvent technique using Eudragit E as carrier and indomethacin as a model drug.

X-Ray diffractometry, differential scanning calorimetry (DSC) and wettability tests were employed to investigate the physical state of the studied formulations. Up to 50% of indomethacin can be dispersed in an amorphous state in Eudragit E.

The influence of the pH on the in vitro release of solid dispersions has been evaluated. Because of the good solubility of Eudragit E at pH 1.2 a fast dissolution rate of the drug was observed while a marked delay was noticed at pH 7.5 where the polymer is only permeable to water. At pH 5.8 the kinetics of drug release can be modulated by the drug/polymer ratio. The dissolution rate of the drug can be increased by decreasing its amount in the coevaporate.     

Preparation and dissolution characteristics of controlled release diltiazem pellets

Different series of Diltiazem pellets with slow release of the active substance were prepared, by pan coating technique, using different mixtures of acrylic polymers (Eudragit E, Eudragit L, Eudragit RL and Eudragit RS) as film coating agents. The thickness of the coatings were varied by different amounts of Eudragit. Release profiles of Diltiazem hydrochloride were investigated using USP XX rotating basket method (Erweka DT-D6) with 1000 ml buffer solution (pH values 1.5; 2.2; 5.5; 6.8; 7.0) at 37°C as solvent. In vitro dissolution findings showed that Eudragit coatings gave prolonged release of Diltiazem hydrochloride. The permeability of coatings in gastric and intenstinal juices was found to be influenced by the amount of Eudragit L in the formulation. Also, the drug release rate was found to be dependent on the amount of coating applied. In order to understand the drug release mechanism better, the release data were tested assuming common kinetic models. In the present study square - root of the time plots and Weibull plots were not sufficiently linear, although several correlation coefficients were high. When the goodness of fit of release data to first - order kinetics and Hixson - Crowell 's equation was evaluated, the difference between these two models was often noted to be minimal.     

Eudragit RL and RS Pseudolatices: Properties and Performance in Pharmaceutical Coating as a Controlled Release Membrane for Theophylline Pellets

Theophylline Active pellets were coated with Eudragit RL and RS pseudolatices in a fluidized bed. The effects of polymer ratio, additional oven drying, addition of dispersed solids, and addition of water miscible organic solvents on sustained drug release through the lates film were determined by using a modified U.S.P. Paddle dissolution method.

The release rate of theophylline can be varied by changing the polymer ratio. permeability to the drug increases with an increase in the content of Eudragit RL. Additional oven drying at 60°C for 10 hours caused no significant change in the dissolution profiles. The addition of dispersed solids such as talcum and silica resulted in an increase in drug release rate. There is no significant change in dissolution profiles when 50% methanol or acetone was added to the Eudragit RS pseudolatex.     

Preparation and dissolution characteristics of controlled release diltiazem pellets

Abstract

Different series of Diltiazem pellets with slow release of the active substance were prepared, by pan coating technique, using different mixtures of acrylic polymers (Eudragit E, Eudragit L, Eudragit RL and Eudragit RS) as film coating agents. The thickness of the coatings were varied by different amounts of Eudragit. Release profiles of Diltiazem hydrochloride were investigated using USP XX rotating basket method (Erweka DT-D6) with 1000 ml buffer solution (pH values 1.5; 2.2; 5.5; 6.8; 7.0) at 37°C as solvent. In vitro dissolution findings showed that Eudragit coatings gave prolonged release of Diltiazem hydrochloride. The permeability of coatings in gastric and intenstinal juices was found to be influenced by the amount of Eudragit L in the formulation. Also, the drug release rate was found to be dependent on the amount of coating applied. In order to understand the drug release mechanism better, the release data were tested assuming common kinetic models. In the present study square - root of the time plots and Weibull plots were not sufficiently linear, although several correlation coefficients were high. When the goodness of fit of release data to first - order kinetics and Hixson - Crowell ‘s equation was evaluated, the difference between these two models was often noted to be minimal.     

Controlled Release Salbutamol Sulphate Molded Tablets Using Eudragit Retard

Permeable acrylic resins were used as efficient retarding materials to prepare controlled release salbutamol sulphate molded tablets. The formulation is simple, efficient, economic and is easily shaped into molded tablets. The effects of two types of acrylic resins, namely: Eudragit RL100 ad Eudragit RS100 in concentrations 1, 2 and 5% w/w on the physical characteristics as well as on the in vitro release patterns of salbutamol sulphate from molded tablets prepared with either polyethylene glycol (PEG) 4000 or 6000 were studied. It was revealed that, as the molecular weight of the PEG increased, the hardness of the tablets increased. Considerable retardation in the drug release was observed by using Eudragit RS100 as compared to Eudragit RL100. The formulation prepared with PEG 6000 and 5% Eudragit RS100 produced much more release time prolongation than the other tested formulations. On the other hand, tablets prepared by the direct compression technique produced a faster release of salbutamol sulphate than those prepared by molding.     

Effect of Microsphere Size and Formulation Factors on Drug Release from Controlled-Release Furosemide Microspheres

Controlled-release furosemide microspheres were prepared with various combinations of Eudragit L: Eudragit RS and Eudragit S: Eudragit RS and release of drug from microspheres containing these polymers in different ratios was studied. A wide range of release rates of drug can obtained by a simple change in the ratio of polymers. An increase in Eudragit RS content of polymer microsphere matrix brought about a decrease in the release rate.

On the other hand, the effect of particle size on the drug release rate from furosemide microspheres was also investigated. The effect of microsphere sizes on release rate depends on the type of Eudragit. The decrease in release rates of small microspheres may be due to agglomerate formation. Dissolution data indicated that the release followed Higuchi's matrix model kinetics.     

Controlled Release Salbutamol Sulphate Molded Tablets Using Eudragit Retard

Abstract

Permeable acrylic resins were used as efficient retarding materials to prepare controlled release salbutamol sulphate molded tablets. The formulation is simple, efficient, economic and is easily shaped into molded tablets. The effects of two types of acrylic resins, namely: Eudragit RL100 ad Eudragit RS100 in concentrations 1, 2 and 5% w/w on the physical characteristics as well as on the in vitro release patterns of salbutamol sulphate from molded tablets prepared with either polyethylene glycol (PEG) 4000 or 6000 were studied. It was revealed that, as the molecular weight of the PEG increased, the hardness of the tablets increased. Considerable retardation in the drug release was observed by using Eudragit RS100 as compared to Eudragit RL100. The formulation prepared with PEG 6000 and 5% Eudragit RS100 produced much more release time prolongation than the other tested formulations. On the other hand, tablets prepared by the direct compression technique produced a faster release of salbutamol sulphate than those prepared by molding.