Evaluation and Floating Enhancement of Levodopa Sustained Release Floating Minitablets Coated with Insoluble Acrylic Polymer

This article describes the in vitro evaluation and the enhancement of the floating properties of coated sustained release (SR) minitablets (MTs). The evaluated system consisted of a 3-mm drug-containing gas-generating core prepared by melt granulation and subsequent compression, which was then coated with a flexible polymeric membrane. Eudragit® RL30D and acetyl triethylcitrate were used as a film former and a plasticizer, respectively. The coating level was fixed at 20% (wt/wt). The optimally coated floating MTs floated within 10 min and remained buoyant for more than 13 h, regardless of the pH of the test medium. By evaluating the dissolution profiles of levodopa at different pH, it was found that the release of levodopa was sustained for more than 12 h regardless of the pH, even if the coating did not cancel the effect of the pH-dependent solubility of the active drug. Finally, the robustness of the coated floating MTs was assessed by testing the drug release variability in function of the stirring conditions during dissolution tests.     

Formulation and evaluation of novel coated floating tablets of bergenin and cetirizine dihydrochloride for gastric delivery

A novel coated gastric floating drug-delivery system (GFDDS) of bergenin (BN) and cetirizine dihydrochloride (CET) was developed. First, the pharmacodynamic studies were performed and the results revealed that the new compounds of bergenin/cetirizine dihydrochloride had comparative efficacy as commercial products (bergenin/chlorphenamine maleate) but with fewer side effects on central nervous system (CNS). Subsequently, bergenin was formulated as an extended-release core tablet while cetirizine dihydrochloride was incorporated into the gastric coating film for immediate release. The formulation of GFDDS was optimized by CET content uniformity test, in vitro buoyancy and drug release. Herein, the effects of sodium bicarbonate (effervescent), hydroxypropyl methylcellulose (HPMC, matrix polymer) and coating weight gain were investigated respectively. The optimized GFDDS exhibited good floating properties (buoyancy lag time < 2?min; floating duration > 10?h) and satisfactory drug-release profiles (immediate release of CET in 10?min and sustained release of BN for 12?h). In vivo gamma scintigraphy proved that the optimized GFDDS could retain in the stomach with a prolonged gastric retention time (GRT) of 5?h, and the coating layer showed no side effect for gastric retention. The novel coated gastric floating drug-delivery system offers a new approach to enhance BN's absorption at its absorption site and the efficacy of both CET and BN.     

Formulation and evaluation of novel coated floating tablets of bergenin and cetirizine dihydrochloride for gastric delivery

A novel coated gastric floating drug-delivery system (GFDDS) of bergenin (BN) and cetirizine dihydrochloride (CET) was developed. First, the pharmacodynamic studies were performed and the results revealed that the new compounds of bergenin/cetirizine dihydrochloride had comparative efficacy as commercial products (bergenin/chlorphenamine maleate) but with fewer side effects on central nervous system (CNS). Subsequently, bergenin was formulated as an extended-release core tablet while cetirizine dihydrochloride was incorporated into the gastric coating film for immediate release. The formulation of GFDDS was optimized by CET content uniformity test, in vitro buoyancy and drug release. Herein, the effects of sodium bicarbonate (effervescent), hydroxypropyl methylcellulose (HPMC, matrix polymer) and coating weight gain were investigated respectively. The optimized GFDDS exhibited good floating properties (buoyancy lag time < 2?min; floating duration > 10?h) and satisfactory drug-release profiles (immediate release of CET in 10?min and sustained release of BN for 12?h). In vivo gamma scintigraphy proved that the optimized GFDDS could retain in the stomach with a prolonged gastric retention time (GRT) of 5?h, and the coating layer showed no side effect for gastric retention. The novel coated gastric floating drug-delivery system offers a new approach to enhance BN’s absorption at its absorption site and the efficacy of both CET and BN.     

Effect of added Pharmatose DCL11 on the sustained-release of metronidazole from Methocel K4M and Carbopol 971P NF floating matrices

In vitro dissolution of metronidazole from sustained release floating tablets was studied with varied proportions of sodium bicarbonate (SB) and Pharmatose DCL 11. Two polymers with different hydration characteristics, Methocel K4M and Carbopol 971P NF, were used to formulate the matrices. The variables studied include the matrices' release profile, hydration volume, and floating behavior. All Methocel matrices floated more than 8 h with SB proportions up to 24%, while Carbopol matrices floated more than 8 h with SB proportions only up to 12%. Matrices' hydration increased with time until reaching a peak and declining thereafter. Methocel matrices showed greater hydration volumes and greater drug dissolution compared to Carbopol matrices. After adding increasing quantities of Pharmatose to matrices containing 12% SB, hydration volume decreased while dissolution increased. These results were attributed to water-filled pores that formed following the Pharmatose dissolution and to reduced polymer proportions. Carbopol matrices showed greater susceptibility to the added Pharmatose, becoming more erodible and releasing higher quantities of metronidazole. The greater Carbopol susceptibility to added Pharmatose was attributed to its faster hydration. Methocel matrices hydrate rapidly only at the surface, delaying hydration and Pharmatose dissolution.     

Development of novel spray coated soft elastic gelatin capsule sustained release formulations of nifedipine

Nifedipine release from coated commercially available immediate release soft elastic gelatin capsules was investigated. Capsules were spray coated using two different polymeric combinations, ethylcellulose and hydroxypropylmethylcellulose or pectin, at different coating loads. In vitro drug release studies were conducted in three different dissolution media: with gastric pretreatment, without gastric pretreatment, and in water to investigate the pH effect on nifedipine release. Convolution of in vitro dissolution data for selected formulations and commercially available sustained release nifedipine formulations showed that the tested formulations provided release profiles of nifedipine that are very promising in terms of desirable sustained release formulations.     

Comparative study of drug release from pellets coated with HPMC or Surelease

The release of metoclopramide hydrochloride (very water soluble cationic drug) and diclofenac sodium (sparingly soluble anionic drug) from pellets coated with hydroxypropylmethylcellulose (HPMC; water-soluble polymer) or ethylcellulose aqueous dispersion (Surelease; water-insoluble polymer) at different coating loads was investigated. The release rates of either drug decreased as the coating load of HPMC increased, but overall, the release was fast, and the majority of both drugs released in about 1 hr, even at the highest coating load. The drug release mechanism for either drug was not affected by the coating load of HPMC or by the type of drug used, and it was found to be mainly diffusion controlled. Diclofenac sodium released slightly more slowly than metoclopramide hydrochloride from HPMC-coated pellets. This was attributed to the lower water solubility of the former drug. The release rate of either drug decreased greatly as the coating load of Surelease increased. The release of both drugs was sustained over 12 hr as the coating load of Surelease increased, and only about 70% of either drug was released after this period at the highest coating load (20%). The mechanism of release of metoclopramide hydrochloride was independent of coating load, and it was predominantly diffusion controlled. However, the mechanism of diclofenac sodium release was dependent on the coating load of Surelease. At low coating loads, diffusion of drug was facilitated due to the presence of more pores at the surface of the coated pellets; therefore, the rate of dissolution of the drug particles was the rate-limiting step. However, at high coating loads, drug release was mainly diffusion controlled. Despite its lower water solubility, diclofenac sodium released slightly faster than metoclopramide hydrochloride from Surelease-coated pellets at equivalent coating loads.     

Effects of coating layer and release medium on release profile from coated capsules with Eudragit FS 30D: an in vitro and in vivo study

The aim of the present research was to evaluate the impact of coating layers on release profile from enteric coated dosage forms. Capsules were coated with Eudragit FS 30D using dipping method. The drug profile was evaluated in both phosphate buffer and Hank’s solutions. Utilization X-ray imaging, gastrointestinal transmission of enteric coated capsules was traced in rats. According to the results, no release of the drug was found at pH 1.2, and the extent of release drug in pH 6.8 medium was decreased by adding the coating layers. The results indicated single-layer coated capsules in phosphate buffer were significantly higher than that in Hank’s solution. However, no significant difference was observed from capsules with three coating layers in two different dissolution media. X-ray imaging showed that enteric coated capsules were intact in the stomach and in the small intestine, while disintegrated in the colon.     

Technological Evaluation of three Enteric Coating Polymers I. With an Insoluble Drug

The enteric properties of a recent cellulose polymer, cellulose acetate trimellitate (CAT, EASTMAN KODAK) were evaluated on an insoluble substract for comparison, included in this paper are the properties of two other cellulose esters: cellulose acetate phthalate (CAP) and hydroxypropyl methylcellulose phthalate (HP55).

The physical properties and disintegration time at pH 1.2 and 6.5 were influenced by the level of coating solution. The gastroresistance was obtained more fastly with CAT and CAP than for HP55.

The influence of coating solution on drug release from tablet was investigated. The dissolution studies were made allowing the variation of pH in the dissolution medium during the kinetics.

Drug release from coated tablets was found to be dependent upon the type of polymers used to form film: higher release rates were obtained with CAT compared to CAP and HP55.     

Basic Coating Polymers for the Colon-Specific Drug Delivery in Inflammatory Bowel Disease

During acute attacks of inflammatory bowel disease, the luminal pH of the colon decreases significantly. This drop in pH can be exploited by developing coated dosage forms with acid-soluble coating polymers to achieve topical drug delivery to the colon. Two batches of minitablets, a conventional and a swellable formulation, were prepared by direct compression and coated with different amounts of either Eudragit® E or AEA® in a small coating pan. The release of the model drug dexamethasone from the coated tablets was measured spectrophotometrically at pH 2.0, 4.0, 5.0, and 6.8 and different stirring rates (100–200 rpm) to simulate the influence of pH and hydrodynamic stress on drug release. In general, lag times of drug release, determined as the time points of a 5% drug release, were longer with AEA-coated cores compared to those coated with Eudragit E, resulting from a lower polymer dissolution rate and water permeability of this film. In low pH media, drug release was dependent on the stirring rate because the onset of drug release is determined by the time required for dissolution of the basic polymer films. At pH 6.8, lag times from nonswelling tablets coated with Eudragit E, for which drug release only begins after complete erosion of the polymer film, are not significantly affected by hydrodynamic stress. Drug release from AEA-coated cores is determined by the slow drug diffusion through the polymer film. Lag times from tablets with swelling properties, for which drug release is induced by disruption of the basic polymer films due to water penetration and subsequent core swelling, are not significantly affected by hydrodynamic stress. Additional coating layers such as an intermediate hydroxypropylcellulose (HPC) layer and an enteric outer layer do not influence the lag times of drug release, nor does a 2-hr pretreatment of the entire dosage form in acidic media.     

Basic coating polymers for the colon-specific drug delivery in inflammatory bowel disease

During acute attacks of inflammatory bowel disease, the luminal pH of the colon decreases significantly. This drop in pH can be exploited by developing coated dosage forms with acid-soluble coating polymers to achieve topical drug delivery to the colon. Two batches of minitablets, a conventional and a swellable formulation, were prepared by direct compression and coated with different amounts of either Eudragit® E or AEA® in a small coating pan. The release of the model drug dexamethasone from the coated tablets was measured spectrophotometrically at pH 2.0, 4.0, 5.0, and 6.8 and different stirring rates (100-200 rpm) to simulate the influence of pH and hydrodynamic stress on drug release. In general, lag times of drug release, determined as the time points of a 5% drug release, were longer with AEA-coated cores compared to those coated with Eudragit E, resulting from a lower polymer dissolution rate and water permeability of this film. In low pH media, drug release was dependent on the stirring rate because the onset of drug release is determined by the time required for dissolution of the basic polymer films. At pH 6.8, lag times from nonswelling tablets coated with Eudragit E, for which drug release only begins after complete erosion of the polymer film, are not significantly affected by hydrodynamic stress. Drug release from AEA-coated cores is determined by the slow drug diffusion through the polymer film. Lag times from tablets with swelling properties, for which drug release is induced by disruption of the basic polymer films due to water penetration and subsequent core swelling, are not significantly affected by hydrodynamic stress. Additional coating layers such as an intermediate hydroxypropylcellulose (HPC) layer and an enteric outer layer do not influence the lag times of drug release, nor does a 2-hr pretreatment of the entire dosage form in acidic media.     

Multiparticulate drug delivery system of aceclofenac: development and in vitro studies

The aim of this study was to develop an enteric-coated multiunit dosage form containing aceclofenac, a nonsteroidal anti-inflammatory drug. The pellets were prepared by using extrusion/spheronization method, and the core pellets were coated with a pH-sensitive poly(meth) acrylate copolymer (Eudragit L100-55) to achieve site-specific drug release. The formulated pellets were characterized for percentage yield, size distribution, surface morphology studies, drug content, and flow properties. In vitro dissolution test was used for comparison of drug release profiles of various coated pellets. The practical yield was found to be 90-95%. The particle size of enteric-coated pellets was found to be in the range of 0.59-0.71 mm. The pellets were spherical in shape and surfaces of pellets were found to be rough and showing micropores. Enteric-coated pellets showed good flow properties and in vitro dissolution profile. Dissolution tests were carried out in a USP type II dissolution apparatus in media-simulating pH conditions of the gastrointestinal tract. The release of the aceclofenac from formulated pellets was established to be minimum in the pH 1.2 (<5%) for a period of 2 h, and at pH 6.8, it shows the maximum release (85 +/- 5% release within 1 h) which indicates gastric resistance of the formulated pellets. The 20% wt/wt enteric-coated pellets were compared to that of marketed product (tablets), it was observed that pellets showed better release profile. The study concluded that the formulated multiparticulate dosage forms can be used as an ideal drug delivery system for the aceclofenac.     

Method to study the effect of blend flowability on the homogeneity of acetaminophen

The aim of this study was to develop an enteric-coated multiunit dosage form containing aceclofenac, a nonsteroidal anti-inflammatory drug. The pellets were prepared by using extrusion/spheronization method, and the core pellets were coated with a pH-sensitive poly(meth) acrylate copolymer (Eudragit L100-55) to achieve site-specific drug release. The formulated pellets were characterized for percentage yield, size distribution, surface morphology studies, drug content, and flow properties. In vitro dissolution test was used for comparison of drug release profiles of various coated pellets. The practical yield was found to be 90–95%. The particle size of enteric-coated pellets was found to be in the range of 0.59–0.71 mm. The pellets were spherical in shape and surfaces of pellets were found to be rough and showing micropores. Enteric-coated pellets showed good flow properties and in vitro dissolution profile. Dissolution tests were carried out in a USP type II dissolution apparatus in media-simulating pH conditions of the gastrointestinal tract. The release of the aceclofenac from formulated pellets was established to be minimum in the pH 1.2 (<5%) for a period of 2 h, and at pH 6.8, it shows the maximum release (85 ± 5% release within 1 h) which indicates gastric resistance of the formulated pellets. The 20% wt/wt enteric-coated pellets were compared to that of marketed product (tablets), it was observed that pellets showed better release profile. The study concluded that the formulated multiparticulate dosage forms can be used as an ideal drug delivery system for the aceclofenac.     

Technological Evaluation of three Enteric Coating Polymers I. With an Insoluble Drug

Abstract

The enteric properties of a recent cellulose polymer, cellulose acetate trimellitate (CAT, EASTMAN KODAK) were evaluated on an insoluble substract for comparison, included in this paper are the properties of two other cellulose esters: cellulose acetate phthalate (CAP) and hydroxypropyl methylcellulose phthalate (HP55).

The physical properties and disintegration time at pH 1.2 and 6.5 were influenced by the level of coating solution. The gastroresistance was obtained more fastly with CAT and CAP than for HP55.

The influence of coating solution on drug release from tablet was investigated. The dissolution studies were made allowing the variation of pH in the dissolution medium during the kinetics.

Drug release from coated tablets was found to be dependent upon the type of polymers used to form film: higher release rates were obtained with CAT compared to CAP and HP55.     

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 Drug Delivery of Ph Dependent Soluble Drug-Pindolol

Pindolol, a pH dependent soluble beta adrenoceptor blocker has been formulated into a controlled drug delivery system. Drug pellets were prepared by extrusion spheronization technique. These were coated with different retardant polymers, namely ethylcellulose and Eudragit RS 100. The effect of different variables such as coating level and pH of dissolution medium have been studied. Drug release from pellets were found to be influenced by the pH of the dissolution medium. A flux release of the drug in the acidic buffer was observed from pellets coated with these polymers. To avoid this flux, a top coat using different pH sensitive polymers, namely Hydroxypropylmethyl cellulose phthalate (HPMCP 55) and Eudragit S 100 was successfully attempted and the drug release from the pellets was modified.     

Some Factors Affecting the Release of Drug from Membrane Coated Slow Release Tablets

Tablets containing sodium salicylate were prepared by direct compression and coated with ethylcellulose and polyethylene glycol 3350. The effect of drug loading, direct compression carrier type, polymer ratio in the coating solution, pH of the dissolution medium, and agitation speed on the drug release were investigated using the USP XXI paddle method. It was observed that direct compression carriers, ratio of ethyl cellulose to polyethylene glycol, the amount of drug present in the tablet, and agitation speed used did not have any influence on the drug release from coated tablets, while the pH of the dissolution medium (gastric vs. intestinal fluids) was found to affect the drug release.     

Formulation and evaluation of floating tablet of H2-receptor antagonist

Context: Conventional sustained dosage form of ranitidine hydrochloride (HCl) does not prevent frequent administration due to its degradation in colonic media and limited absorption in the upper part of GIT.

Objectives: Ranitidine HCl floating tablet was formulated with sublimation method to overcome the stated problem.

Methods: Compatibility study for screening potential excipients was carried out using Fourier transform infrared spectroscopy (FT-IR) and differential scanning chromatography (DSC). Selected excipients were further evaluated for optimizing the formulation. Preliminary screening of binder, polymer and sublimating material was based on hardness and drug release, drug release with release kinetics and floating lag time with total floatation time, respectively. Selected excipients were subjected to 3² factorial design with polymer and sublimating material as independent factors. Matrix tablets were obtained by using 16/32” flat-faced beveled edges punches followed by sublimation.

Results: FT-IR and DSC indicated no significant incompatibility with selected excipients. Klucel-LF, POLYOX WSR N 60?K and l-menthol were selected as binder, polymer and sublimating material, respectively, for factorial design batches after preliminary screening. From the factorial design batches, optimum concentration to release the drug within 12?h was found to be 420?mg of POLYOX and 40?mg of l-menthol. Stability studies indicated the formulation as stable.

Conclusion: Ranitidine HCl matrix floating tablets were formulated to release 90% of drug in stomach within 12?h. Hence, release of the drug could be sustained within narrow absorption site. Moreover, the dosage form was found to be floating within a fraction of second independent of the pH of media ensuring a robust formulation.     

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.     

Bioavailability enhancement of baclofen by gastroretentive floating formulation: statistical optimization,in vitro and in vivo pharmacokinetic studies

Objectives: The study was aimed to improve bioavailability of baclofen by developing gastroretentive floating drug delivery system (GFDDS).

Methods: Preliminary optimization was done to select various release retardants to obtain minimum floating lag time, maximum floating duration and sustained release. Optimization by 3² factorial design was done using Polyox WSR 303 (X₁) and HPMC K₄M (X₂) as independent variables and cumulative percentage drug released at 6?h (Q6h) as dependent variable.

Results: Optimized formulation showed floating lag time of 4–5 s, floated for more than 12?h and released the drug in sustained manner. In vitro release followed zero ordered kinetics and when fitted to Korsemeyer Peppas model, indicated drug release by combination of diffusion as well as chain relaxation. In vivo floatability study confirmed floatation for more than 6?h. In vivo pharmacokinetic studies in rabbits showed C_max of 189.96?±?13.04?ng/mL and T_max of 4?±?0.35?h for GFDDS. The difference for AUC_(0–T) and AUC_(0–∞) between the test and reference formulation was statistically significant (p > 0.05). AUC_(0–T) and AUC_(0–∞) for GFDDS was 2.34 and 2.43 times greater than the marketed formulation respectively.

Conclusion: GFDDS provided prolonged gastric residence and showed significant increase in bi oavailability of baclofen.     

Preparation and Evaluation of Controlled Release Propranolol Hydrochloride Beads

Conventional pan coating method was utilized to prepare propranolol-HCl sustained release coated beads. Eudragit RS 100 was used as release controlling materials. Overcoating of the beads with beeswax was also investigated. The beads were characterized for their particle size distribution, drug loading efficiency and their dissolution behaviour in 0.1N HCl, Most of the finished beads (72.4%) fall in the particle size range 800-1700 um. The actual drug content, calcu-lated as opposed to the theoretical drug content were 77.6% and 74.2% of the drug for the beads having particle size range 1700-1250 um and 1250-800 um respectively, The coating level of the polymer, the particle size of the beads and overcoating with beeswax play a major role in determining the release rate of the drug from the coated beads.