Preparation and In-Vitro Evaluation of Prolonged Release Tablets of Pheniramine Aminosalicylate

Prolonged release tablets of pheniramine aminosalicylate were prepared from co-precipitates of the drug in different types of Eudragit. The hardness of the tablet had a pronounced effect on the release rate of the drug. Tablets (500 mg, hardness 13 kg) and 375 mg tablets (hardness 6.5 kg) prepared from the co-precipitates containing 15% of the drug in Eudragit L 100, and 20% of the drug in Eudragit S 100 respectively, showed release rate patterns that were in agreement with Lang primary requirements for drug release from sustained release tablets.

Tablets (500 mg) prepared from the co-precipitates containing 15% of the drug in Eudragit L 100 or Eudragit S 100 and 375 mg tablets containing 20% of the drug in Eudragit S 100 showed release rate patterns that were best described by Higuchi equation, indicating that a diffusion controlled mechanism was mainly operative.     

The Effect of Polymer Coating Systems on the Preparation, Tableting, and Dissolution Properties of Sustained-Release Drug Pellets

The preparation of sustained-release (SR) drug pellets and their tablets was evaluated. Pellets containing indomethacin, pseudoephedrine hydrochloride (P-HCl), or pseudoephedrine (P) base were prepared by spraying a mixture of drug, Eudragit S-100 resins, dibutyl sebacate, and alcohol onto nonpareil seeds via the Wurster-column process. The oven-dried drug/Eudragit S-100 (DS) pellets were coated with different levels of Eudragit RS and Eudragit S-100 acrylic resins. Tablets containing P-HCl or P-base SR pellets, microcrystalline cellulose, and Methocel K4M were compressed. The solubility of the drug entity in the polymer solution was found to be the most critical factor affecting the yield and the physical properties of the resultant DS pellets. Dissolution studies of Eudragit RS coated drug pellets demonstrated that the release profiles depended not only on the physicochemical properties of the drug, particularly aqueous solubility, but also on the coating levels. The release rate profiles of the matrix tablets can be modified by varying the types of P-HCl or P-base SR pellets in the formulation. The release of drug from the matrix tablets is primarily matrix controlled.     

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.     

Preparation of Acetaminophen Microcapsules by Coaservation-Phase Separation Method

In this study, it was aimed to prepare prolonged action microcapsules of acetaminophen with short biological half-life by a non-solvent addition method which is one of the conservation-phase separation techniques.

For this purpose, the three different particle size ranges of acetaminophen (0.088-0.177 mn, 0.250-0.354 mn, 0.420-0.500 mn) were used. The solution of polyisobuthylene in cyclohexane as a non-solvent and Eudragit RS and Eudragit RL as coating polymers were also used. The prepared mi crosapsules were compressed by a hydraulic press using different types of direct tableting agents such as Ludipress, Avicel PH 101 and Lactose EP D 30. Dissolution rates of each tablet containing 160 mg of microencapsulated acetaminophen were examined by continuous flow-through cell method

The results of this study showed that the release rate of drug from microcapsules prepared with Eudragit RS was lower than that of microcapsules prepared with Eudragit RL. However different particle size ranges of drug didn't affect significantly the release rate; but different types of direct tableting agents were effective on the release rate of drug.     

Diclofenac release from eudragit-containing matrices and effects of thermal treatment

Ethyl acrylate-methyl methacrylate copolymer (Eudragit NE40D) was evaluated as matrix material for preparing controlled-release tablets of diclofenac sodium. Drug release could be modified in a predictable manner by varying the Eudragit NE40D content, but was pH dependent, being markedly reduced at lower pH. This could be attributed to the low solubility of the drug at these pH values. Thermal treatment of the tablets at 60 degrees C was also found to affect the rate of drug release, which was found to decrease with an increase in the treatment duration, but could be stabilized after 96 hr of treatment. This was also associated with a corresponding increase in the tablet tensile strength. However, treatment of the granules for 5 hr prior to compaction into tablets could shorten the stabilizing time of the drug release to 48 hr and that of the tensile strength to 24 hr. The effect of thermal treatment may be ascribed to better coalescence of the Eudragit particles to form a fine network, resulting in matrix of higher tortuosity and lower porosity.     

Evaluation of Tableted Microspheres of Dipyridamole

Microspheres of dipyridamole were prepared by solvent evaporation methods. The effect of additives Avicel PH 101, and beta cyclodextrin on the release rate of tableted microspheres were studied. Incorporating Avicel or beta cyclodextrin increased the dipyridamole release rates in tableted microspheres. Beta cyclodextrin was found to be a good additive for microsphere tablets to increase the drug release rates without causing disintegration.     

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.     

Controlled-Release Theophylline Tablet Formulations Containing Acrylic Resins, II. Combination Resin Formulations

Theophylline tablet formulations containing a combination of cationic and anionic acrylic resins were prepared and evaluated. Equal amounts of Eudragit RSPM (cationic resin) and Eudragit L100 (anionic resin) were included at the 15% level (total polymer content) into the tablet formulations. Pressure-hardness profiles with theophylline-resin compacts (4:1) demonstrated that compacts containing the RSPM resin were the most compressible. The dissolution profiles for theophylline in acidic media showed slower release rates from tablets containing the combined resins than from those containing each of the single resins. It was proposed that this decrease in drug release rate was a result of a solid state interaction between the oppositely charged polymers. As the amount of retardant in the matrix increased, the release rates in acidic media decreased. In pH 7.4 phosphate buffer, much faster release was seen due to the higher solubility of the Eudragit L-100 resin at this pH level. Tablet hardness between the range of 6.8 kg to 15 kg showed minimal influences on the dissolution rate. Recompression and relubrication of the tablet formulation containing both polymers, produced a decrease in release rates of theophylline from the tablet matrix.     

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.     

Controlled-Release Theophylline Tablet Formulations Containing Acrylic Resins,II. Combination Resin Formulations

Abstract

Theophylline tablet formulations containing a combination of cationic and anionic acrylic resins were prepared and evaluated. Equal amounts of Eudragit RSPM (cationic resin) and Eudragit L100 (anionic resin) were included at the 15% level (total polymer content) into the tablet formulations. Pressure-hardness profiles with theophylline-resin compacts (4:1) demonstrated that compacts containing the RSPM resin were the most compressible. The dissolution profiles for theophylline in acidic media showed slower release rates from tablets containing the combined resins than from those containing each of the single resins. It was proposed that this decrease in drug release rate was a result of a solid state interaction between the oppositely charged polymers. As the amount of retardant in the matrix increased, the release rates in acidic media decreased. In pH 7.4 phosphate buffer, much faster release was seen due to the higher solubility of the Eudragit L-100 resin at this pH level. Tablet hardness between the range of 6.8 kg to 15 kg showed minimal influences on the dissolution rate. Recompression and relubrication of the tablet formulation containing both polymers, produced a decrease in release rates of theophylline from the tablet matrix.     

Eudragit(®) RS PO/RL PO as rate-controlling matrix-formers via roller compaction: Influence of formulation and process variables on functional attributes of granules and tablets

The influence of plasticizer level, roll pressure and sintering temperature was investigated on the granule properties, tablet breaking force and theophylline release from tablets. Nine formulations using theophylline as a model drug, Eudragit(?) RL PO, Eudragit(?) RS PO, or both as a matrix former and triethyl citrate (TEC) as a plasticizer were prepared. The formulations were roller compacted and the granules obtained were evaluated for particle size distribution and flowability. These granules were compacted into tablets at a compression force of 7?kN. The tablets were thermally treated at different temperatures (50 and 75°C) for 5?h and were evaluated for breaking force and dissolution. Increase in roll pressure and TEC levels resulted in a progressive increase in the mean particle size of the granules. The flowability of the granules also improved with increasing roll pressures and TEC levels. Tablet breaking force increased with an increase in TEC levels and sintering temperatures. But these effects were significant only at the highest level of plasticizer and sintering temperature respectively. For the tablets containing Eudragit(?) RS PO, theophylline release decreased proportionately with increase in TEC levels and sintering temperatures. Tablets containing either Eudragit(?) RL PO or a mixture of RS PO and RL PO failed to impart an extended-release property to the tablets at the studied variables i.e. roll pressure, TEC levels and sintering temperature. It was clearly demonstrated that with suitable optimization of these parameters, the release-rate of a water soluble drug from the matrix tablets prepared via roller compaction can be finely controlled.     

Degradation kinetics of thiamine hydrochloride in directly compressed tablets iii water vapour transmission through free and applied eudragit films

Water vapour transmission through free and applied film of four Eudragit resins namely, E₁₀₀, L₁₀₀ and RS₁₀₀ to directly compressed thiamine hydrochloride tablets was investigated. The type of Eudragit film influenced both water vapour transmission and moisture absorption characteristics of the tablets compressed with either single or binary blend of vehicles. The moisture absorption rate constant K_a, for a given batch was found to be a function of vapour pressure, P, and film thickness, L. The relationship between K_a and either of these parameters is exponental and may be expressed as K_a = A exp (x/P) and K_a = K*_a exp (-x*L). In general, film coating with Eudragit resins affected the physical characteristics of the tablets. The rate of drug release, K has an exponentially relationship as K_e K_o exp (-c/L).     

Comparison of two varieties of microcrystalline cellulose as filler-binders I. Perdnisone tablets

A comparative study of two varieties of microcrystalline cellulose (Avicel PH 101 and Avicel PH 102) as excipients in direct compression prednisone tablets has been carried out. The effects of compression force, proportion of drug/excipient and variety of cellulose (defined by means of mean particle size) on the structural, mechanical and release properties of the tablets were studied. Differences were observed in the behaviour of the two varieties of cellulose affecting all the properties analyzed. These differences diminished, and disappeared in some cases, when 10% prednisone was present. The different degrees of interparticle association and the relations between the structural, mechanical and drug release properties of the tablets explain the differences observed.     

Formulation factors affecting drug release from poly(lactic acid) (PLA) microcapsule tablets

A sustained-release (SR) formulation of phenobarbital (PB) microcapsule tablet was prepared using low molecular weight (MW) DL- and high MW L-poly(lactic acid) (PLA) polymer. Microencapsulation of PB showed a unimodal size distribution (375 to 550 microns) of the microcapsules with high loading capacity (> 84%). Drug release from the microcapsule was influenced by the polymer ratios and increased with an increase in L-PLA amount. Microcapsules and physical mixtures of PB and the PLA were directly compressed independently to form microcapsule and matrix tablets, respectively. Drug release from the microcapsule tablets was significantly lowered (p < .001) compared to matrix tablets or free microcapsule (free microcapsule > matrices > microcapsule tablets). We also investigated the effect of tablet adjuvants, compression pressures, and microcapsule loading on the tablet performance in terms of friability, hardness, porosity, tensile strength, and the release kinetics of PB. The drug release rate increased with increasing compression pressure in the case of Emcompress or lactose, but not Avicel. The drug release rate was three- to fivefold increased with sodium starch glycolate compared to tablets without a disintegrant. With an increase in microcapsule loading, a decrease in the drug release rate was observed; however, the tablet performance remained satisfactory. The morphology of the microcapsules was monitored microscopically after the dissolution and the disintegration of tablets. The drug release accelerated with compression pressures and microcapsule loading from the tablets due to mechanical destruction of the microcapsule wall, which was more clearly seen after disintegration and dissolution of the tablets. Our data suggest that the PLA microcapsule can be tableted to make a SR product without significantly affecting its release kinetics.     

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.     

Comparative Study of Aqueous and Organic Enteric Coatings of Chlorpheniramine Maleate Tablets

Two acrylic polymers (Eudragit® L 12.5 P and L 30 D) and a cellulosic polymer (cellulose acetate trimellitate, CAT) in organic and aqueous formulations were used in order to obtain an enteric coating on tablets containing clorpheniramine maleate as a water-soluble model drug. The coating of tablets was executed in a coating pan in similar conditions for each kind of solvent. The coated tablets were tested according to the delayed-release test of USP 23 (Method A). In our experimental conditions different amounts of polymers were needed to obtain an enteric coating. The lowest amount was in the case of Eudragit L 30 D (aqueous), after which appeared Eudragit L 12.5 P (organic), CAT (organic), and finally, CAT (aqueous) as the polymer that needed to be of the highest amount. During the dissolution test differences in the size and aspect of the tablets were observed according to the polymers. Acrylic polymers did not show changes in size and aspect, but CAT polymers showed a notable increase in size. me different behavior of the tablets during the dissolution test can explain the differences observed in the adjustment of the release data. The release data were tested assuming common kinetic models. In the present study it was observed that Eudragit L polymers release the drug in a first-order kinetic and that CAT releases it according to a zero-order kinetic.     

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     

Evaluation of Eudragit RS-PO and Ethocel 100 matrices for the controlled release of lobenzarit disodium

Lobenzarit disodium is a drug for the treatment of rheumatoid arthritis. In this work, inert matrix tablets of lobenzarit disodium were prepared by direct compression using Ethocel® 100 and Eudragit® RS-PO as polymeric materials in different ratios. The obtained powder mixtures and tablets were evaluated from the rheological and technological points of view. The dissolution test was performed to evaluate the in vitro release kinetic of the matrices. The obtained dissolution profiles demonstrated that the matrices containing Eudragit RS-PO showed a slower release rate and therefore were more suitable for controlling the release of drug. The fit to the Higuchi model indicates that the drug release mechanism from these matrices was controlled by the diffusion step.     

Wax-matrix tablet for time-dependent colon-specific delivery system of sophora flavescens Aiton: preparation and in vivo evaluation

A wax-matrix time-dependent colon-specific tablet (WM-TDCS) was studied. Wax-matrix tablet core consisting of semi-synthetic glycerides, as a wax polymeric expanding agent, carboxymethyl starch sodium (CMS-Na), and NaCl was prepared, and Sophora flavescens Aiton (ASF, extracts of traditional Chinese medicine) was used as model drug. The wax-matrix ASF tablets core was coated with Eudragit NE 30 D as the inner coating materials and with Opadry OY-P-7171 as the outer coating materials. The in vitro release behaviors of the coated tablets were examined and then in vivo absorption kinetics of the coated tablets in dogs was further investigated. The volume of the tablet core was markedly increased at 37 degrees C because of the expand effect of polymer semi-synthetic glycerides and CMS-Na. The drug release from WM-TDCS was more stable than TDCS in vitro and in vivo. The lag time of ASF release was also controlled by the thickness of the inner coating layer. In vivo evaluation demonstrated that in vivo lag time of absorption was in a good agreement with in vitro lag time of release. ASF wax-matrix tablets coated with Eudragit NE 30 D and Opadry OY-P-7171 using the regular coating technique could be designed to achieve a lag time of 3 h in the small intestinal tract.