Influence of methacrylic and acrylic acid polymers on the release performance of weakly basic drugs from sustained release hydrophilic matrices

Weakly basic drugs and their salts exhibit a drop in aqueous solubility at high pH conditions, which can result in low and incomplete release of these drugs from sustained release formulations. The objective of this study is to modulate matrix microenvironmental pH by incorporation of acidic polymers and thus enhance the local solubility and release of basic drugs in high pH environment. Two weakly basic drugs, papaverine hydrochloride and verapamil hydrochloride with widely different pKa and aqueous solubilities at the pH of interest (6.8), were investigated for their release from hydrophilic matrices and the effect of a methacrylic (Eudragit L100-55) and an acrylic acid polymer (Carbopol 71G), were studied. For papaverine HCl, release increased with an increase in the levels of the acidic polymer used. Direct measurement of matrix pH using microelectrodes illustrated that the mechanism of release enhancement was based on modulation of microenvironmental pH. For verapamil HCl, incorporation of L100-55 resulted in release retardation due to an interaction between the anionic polymer and the cationic drug and the extent of retardation increased with an increase in the polymer level. The interaction product was characterized by NIR, FT-IR, and MTDSC techniques. Verapamil HCl release from Carbopol 71G based matrix tablets was higher than that from conventional hydroxypropyl methylcellulose (HPMC) based matrices, without any incorporated acidic additives.     

Design and evaluation of pH modulated controlled release matrix systems for colon specific delivery of indomethacin

Indomethacin, a potent non steroidal anti-inflammatory drug (NSAID), is indicated for the local treatment of colorectal carcinoma. The aim of the present study was to design and investigate various matrix systems for controlled and site specific delivery of indomethacin to the colon. Various pH sensitive and hydrophobic polymers were investigated for their effect on drug release and site specificity. Effect of proportion of Eudragit L100 and Eudragit S100 in matrix either alone or in combination was evaluated. Effect of hydrophobic non-swellable polymer ethyl cellulose on the release pattern of drug from the Eudragit bases was also investigated. Matrix tablets prepared with Eudragit showed pH dependent release profile with the formulations of Eudragit L100 showing faster rate of drug release than Eudragit S100 in alkaline pH. The release profile from matrix tablets containing Eudragit L100 and Eudragit S100 in combination or with ethyl cellulose correlated well with the relative proportion of the two polymer types in the matrix base. Selected formulations when evaluated in simulated gastric fluid pH without enzymes showed negligible to low drug release (less than 10%) in the first 4-6 h followed with controlled release for 14-16 h. It was concluded that pH sensitive matrix bases in combination with a hydrophobic polymer like ethyl cellulose canbe ideal for site specific delivery of drugs to colon with controlled release profile.     

Influence of an enteric polymer on drug release rates of theophylline from pellets coated with Eudragit RS 30D

The purpose of this research study was to investigate the influence of an enteric polymer on the drug release properties of theophylline pellets coated with Eudragit RS 30D. Theophylline pellets were coated with aqueous colloidal dispersions of Eudragit RS 30D containing various amounts of Eudragit L 100-55. The effect of storage conditions on the release of drug from coated pellets was determined as a function of the pH of the dissolution medium. The results from the dissolution study showed significant changes in the dissolution rate of theophylline from pellets coated with Eudragit RS 30D when cured at 40 degrees C for 4 days. No change in the drug release rate was observed when Eudragit L100-55 was present in the Eudragit RS 30D dispersion. Increasing the ratio of Eudragit L100-55 to Eudragit RS 30D resulted in faster drug release rates from the coated pellets. An increase in the pH of the dissolution medium was found to enhance drug release from the pellets coated with Eudragit RS 30D containing Eudragit L 100-55. Theophylline pellets when coated with Eudragit RS 30D containing the enteric polymer Eudragit L100-55 demonstrated no aging effects when stored at elevated temperatures. The overcoating of the pellets with Eudragit RD 100 did not affect the drug release profiles and prevented the particles from agglomerating during curing and storage.     

Improved drug delivery to the lower intestinal tract with tablets compression-coated with enteric/nonenteric polymer powder blends

The objective of this study was to develop pH-erosion-controlled compression-coated tablets for potential colonic drug delivery with improved gastric resistance and pulsatile release based on compression-coatings of powder blends of the enteric polymer Eudragit® L100-55 and the extended release polymer ethylcellulose. Tablet cores containing model drugs of varying solubilities (acetaminophen, carbamazepine and chlorpheniramine maleate) were compression-coated with different ratios of Eudragit® L100-55:ethylcellulose 10cP FP at different compression forces and tablet core:compression-coat ratios. The compression-coated tablets were characterized by drug release, media uptake, erosion behaviour and wettability. All drugs were released in a pulsatile fashion in higher pH-media after a lag time, which was controlled by the erosion properties of the Eudragit L:ethylcellulose compression-coating. The addition of ethylcellulose avoided premature drug release in lower pH-media and significantly increased the lag time in higher pH-media because of a reduction in wettability, media uptake and erosion of the compression-coatings. Importantly, ethylcellulose also reduced the pH-dependency of the erosion process between pH 5.5 and 7.4. The lag time could also be increased by increasing the compression force and decreasing the core:compression-coat ratio. In conclusion, tablets compression-coated with blends of Eudragit L and ethylcellulose resulted in excellent release properties for potential targeting to the lower intestinal tract with no release in lower pH-media and rapid release after a controllable lag time in higher pH-media.     

Design of pH-independent controlled release matrix tablets for acidic drugs

The rate and extent of drug release from most controlled release systems are influenced by the pH of the dissolution medium for drugs with pH-dependent solubility. This dependency of drug release on pH may lead to additional inter- and intra-subject variability in drug absorption. In the present study, a pH-independent controlled release matrix system for acidic drugs was designed by incorporating release-modifiers in the formulation. Controlled release matrix tablets were prepared by compression of divalproex sodium, Methocel K4M and Eudragit E 100 or Fujicalin as the release-modifier. For formulations without any release-modifier, the extent and rate of drug release at pH 6.8 was much higher than that at pH 1.0. Formulations containing Eudragit E 100 provided drug release that was essentially independent of pH. This was achieved because Eudragit E 100 significantly increased the drug release in acidic medium and slightly decreased the release rate at higher pH. The increased release in the acidic medium can be attributed to the elevation of the micro-environmental pH in the swollen polymer gel layer. Formulations containing Fujicalin were less effective than those containing Eudragit E 100. This was attributed to the relative inability to elevate the pH and shorter residence time of Fujicalin in the matrix relative to Eudragit E 100.     

Enteric polymers as acidifiers for the pH-independent sustained delivery of a weakly basic drug salt from coated pellets

Weakly basic drugs and their salts exhibit a decrease in aqueous solubility at higher pH, which can result in pH-dependent or even incomplete release of these drugs from extended release formulations. The objective of this study was to evaluate strategies to set-off the very strong pH-dependent solubility (solubility: 80 mg/ml at pH 2 and 0.02 mg/ml at pH 7.5, factor 4000) of a mesylate salt of weakly basic model drug (pK_a 6.5), in order to obtain pH-independent extended drug release. Three approaches for pH-independent release were investigated: (1) organic acid addition in the core, (2) enteric polymer addition to the extended release coating and (3) an enteric polymer subcoating below the extended release coating. The layering of aspartic acid onto drug cores as well as the coating of drug cores with an ethylcellulose/Eudragit L (enteric polymer) blend were not effective to avoid the formation of the free base at pH 7.5 and thus failed to significantly improve the completeness of the release compared to standard ethylcellulose/hydroxypropyl cellulose (EC/HPC)-coated drug pellets. Interestingly, the incorporation of an enteric polymer layer underneath the EC/HPC coating decreased the free base formation at pH 7.5 and thus resulted in a more complete release of up to 90% of the drug loading over 18 h. The release enhancing effect was attributed to an extended acidification through the enteric polymer layer. Flexible release patterns with approximately pH-independent characteristics were successfully achieved.     

Release performance of a poorly soluble drug from a novel, Eudragit-based multi-unit erosion matrix

Mechanisms governing the release of drugs from controlled delivery systems are mainly diffusion, osmosis and erosion. For poorly soluble drugs, the existing mechanisms are limited to osmosis and matrix erosion, that are commonly observed in single unit matrix dosage forms. This study reports formulation and dissolution performance of Eudragit L 100 55 and Eudragit S 100 based multi-unit controlled release system of a poorly soluble thiazole based leukotriene D(4) antagonist, that was obtained by an extrusion/spheronization technique. Effect of triethyl citrate, that was incorporated in the matrix, on the dissolution performance of the drug was also evaluated. In vitro matrix erosion and drug release from the pellets were determined by the use of USP Dissolution Apparatus I, pH 6.8 phosphate buffer, gravimetry and UV spectrophotometry, respectively. Results obtained demonstrated that matrix erosion and drug release occurred simultaneously from the pellets. Pellets eroded with a consequent reduction in size without any change in the pellet geometry for over 12 h. Matrix erosion and drug release followed zero order kinetics. Data obtained strongly suggested a polymer controlled, surface erosion mechanism.     

Carbopol 934-Sodium Alginate-Gelatin Mucoadhesive Ondansetron Tablets for Buccal Delivery: Effect of pH Modifiers

The present work aims at developing mucoahesive tablets of ondansetron hydrochloride using bioadhesive polymers like carbopol-934, sodium alginate and gelatin. Tablets prepared by direct compression using different polymer with varying ratio were evaluated for hardness, friability, uniformity of weight, disintegration time, microenvironmental pH, bioadhesion and in vitro release. Hardness, friability disintegration time and drug release were found within pharmacopoeial limit. Microenvironmental pH decreased whereas bioadhesive strength, water uptake, and in vitro release increased with increase in carbopol-934. Increasing sodium alginate and gelatin increased the microenviromental pH and decreased bioadhesive strength, water uptake and in vitro release. With a view to investigate the modulation of drug release from formulation by addition of pH modifiers viz. citric acid and sodium bicarbonate, the tablets with carbopol-934 (2.0), sodium alginate (0.5) and gelatin (6.5) were used and the effect of pH modifiers on microenvironmental pH, bioadhesion, water uptake, in vitro permeation and in vitro release was studied. Microenvironmental pH, bioadhesive strength, water uptake, in vitro release and permeation decreased with increasing concentration of citric acid whereas microenvironmental pH, water uptake and release were enhanced and bioadhesive strength was lowered with increase in sodium bicarbonate. Present study demonstrates carbopol-934, sodium alginate, gelatin polymer system with added pH modifier can be successfully formulated for buccal delivery of ondansetron with desired release profile.     

Effect of anionic polymers on the release of propranolol hydrochloride from matrix tablets.

Anionic polymers, namely Eudragit S, Eudragit L 100-55, and sodium carboxymethylcellulose, were incorporated into hydroxypropylmethylcellulose (HPMC K100M) to modify the drug release from HPMC matrices. The effects of changing the ratio of HPMC to anionic polymers were examined in water and in media with different pH. The dissolution profiles were compared according to release rates. The interaction between propranolol hydrochloride and anionic polymers was confirmed using the UV difference spectra method. The drug release was controlled with the type of anionic polymer and the interaction between propranolol hydrochloride and anionic polymers. The HPMC-anionic polymer ratio also influenced the drug release. The matrix containing HPMC-Eudragit L 100-55 (1:1 ratio) produced pH-independent extended-release tablets in water, 0.1 N HCl, and pH 6.8 phosphate buffer.     

阳离子聚合物Eudragit RL对电解质的敏感性及其对不同药物释放的影响

研究聚合物Eudragit RL在电解质溶液中的膨胀行为,以及介质组成及聚合物膨胀度对硝苯地平、氯苯那敏(扑尔敏)和吲哚美辛从聚合物骨架中释放的影响。用转篮法及浆板法测定微球和药膜的释放度。结果表明Eudragit RL的膨胀度随电解质浓度增加而下降,且受电解质种类的影响显著。硝苯地平和氯苯那敏从聚合物骨架中的释放速率与聚合物膨胀行为间呈良好正相关,但吲哚美辛从聚合物中的释放速率受聚合物膨胀和离子对药物的置换两种因素同时控制。提示Eudragit RL骨架中药物的释放方式受介质组成和药物种类的影响。     

Strategies for the design of hydrophilic matrix tablets with controlled microenvironmental pH

Incorporation of weak acids as pH modifiers enhances the release of weakly basic drugs in higher pH environments by reducing the microenvironmental pH (pHM). The objectives of this study were: (a) to investigate the relationship between pHM, drug release, and pH modifier release and (b) to achieve simultaneous release of the drug and the pH modifier over the entire dissolution time (6 h, phosphate buffer, pH 6.8). Using dipyridamole as a model drug, we investigated drug and acid release and determined the average pHM potentiometrically using tablet cryosections. The first approach was based on incorporating different concentrations of pH modifiers in conventional matrix tablets based on hydroxypropylmethylcellulose. Owing to its high acidic strength and low aqueous solubility, fumaric acid resulted in simultaneous release and maintained a constant acidic pHM. Secondly, press-coated matrix tablets, comprising an acidic reservoir, were found to be a valuable approach for retarding the diffusion of more water-soluble acids. Using the power law expression (Mt/Minfinity = ktn) it became evident that the inclusion of acids increased drug release. Higher acid concentrations tended to decrease n standing for the slope, whereas the release constant k increased. Furthermore, the medial check term parameters depended on the type of pH modifier used.     

Microenvironmental pH modulation in solid dosage forms

There are many reports in the literature referring to the effect of microenvironmental pH on solid dosage form performance, particularly stability and dissolution profiles. Several techniques have been proposed for the measurement of the microenvironmental pH. Those techniques use certain assumptions and approximations and many of them employ a solution calibration curve of a probe to predict hydrogen ion activity in a substantially dry solid. Despite the limitation of the methodology, it is clear from the literature that microenvironmental pH has a significant impact on stability of compounds which demonstrate pH dependent stability in solution. Degradation kinetics of such compounds, and in some cases degradation profile as well, are dependent on the microenvironmental pH of the solid. Modulation of the microenvironmental pH through the use of pH modifiers can hence prove to be a very effective tool in maximizing solid dosage form stability. Judicial selection of the appropriate pH modifier, its concentration and the manufacturing process used to incorporate the pH modifier is necessary to enhance stability. Control of microenvironmental pH to maximize stability can be achieved without the use of pH modifier in some cases if an appropriate counter ion is used to provide an inherently optimal pH for the salt. Microenvironmental pH modulation was also shown to control the dissolution profile of both immediate and controlled release dosage forms of compounds with pH dependent solubility. The pH modifiers have been used in conjunction with high energy or salt forms in immediate release formulations to minimize the precipitation of the less soluble free form during initial dissolution. Additionally, pH modifiers were utilized in controlled release dosage forms of weakly basic drugs which exhibit diminished release in dissolution media with high pH. The incorporation of acidic pH modifiers in the controlled release formulation increases the solubility of the basic drug even as the high pH dissolution medium enters into the dosage form hence increasing drug release rate.     

Sustained-release matrix tablets of metformin hydrochloride in combination with triacetyl-beta-cyclodextrin.

The low bioavailability and short half-life of metformin hydrochloride (MH) make the development of sustained-release forms desirable. However, drug absorption is limited to the upper gastrointestinal (GI) tract, thus requiring suitable delivery systems providing complete release during stomach-to-jejunum transit. This study was undertaken to develop a MH sustained-release formulation in compliance with these requirements. The strategy proposed is based on direct-compressed matrix tablets consisting of a combination of MH with the hydrophobic triacetyl-beta-cyclodextrin (TAbetaCD), dispersed in a polymeric material. Different polymers were tested as excipients, i.e. hydroxypropylmethylcellulose, xanthan gum, chitosan, ethylcellulose, Eudragit L100-55, and Precirol. Compatibility among the formulation components was assessed by DSC analysis. All the tablets were examined for drug release pattern in simulated gastric and jejunal fluids used in sequence to mimic the GI transit. Release studies demonstrated that blends of a hydrophobic swelling polymer (hydroxypropylmethylcellulose or chitosan) with a pH-dependent one (Eudragit L100-55) were more useful than single polymers in controlling drug release. Moreover, the main role played by the MH-TAbetaCD system preparation method (i.e. grinding or spray-drying) in determining the behaviour of the final formulation was evidenced. In fact, for a given matrix-tablet composition, different sustained-release effects were obtained by varying the relative amounts of MH-TAbetaCD as ground or spray-dried product. In particular, the 1:1 (w/w) blend of such systems, dispersed in a Eudragit-chitosan polymeric matrix, fully achieved the prefixed goal, giving about 30% released drug after 2h at gastric pH, and overcoming 90% released drug within the subsequent 3h in jejunal fluid.     

Modified release of coated sugar spheres using drug-containing polymeric dispersions

A drug-containing polymeric dispersion was applied onto nonpareil sugar spheres (18/20 mesh) using a fluid-bed spray coater. Eudragit RS30D was selected as the polymeric coating material. Melatonin secreted by the pineal gland in a circadian rhythm was used as a model drug. The release behaviors of the coated sugar spheres were investigated in gastric fluid (pH 1.4) for 2 h, and then continuously in intestinal fluid (pH 7.4) for 14 h. The release rate of the coated sugar spheres decreased with increasing coating levels. The solvent (ethanol) in the coating dispersions significantly decreased the release of the drug due to the good dispersion of the low solubility melatonin in the polymeric films. The polymer (polyvinylpyrrolidone, PVP) and drug contents in the coating dispersions did not affect the release rate. Most of all, the release profiles were drastically changed according to the type and concentration of plasticizers used. The current coating methods that use drug-containing polymeric dispersions could be useful for simultaneous drug loadings and their modified release. The solubilization and controlled release of poorly water-soluble drugs can be achieved as both the solubilizers and drugs are present in the drug-containing polymeric dispersions.     

Relationship of film properties to drug release from monolithic films containing adjuvants.

The rate of drug release from a polymeric matrix system was influenced by the physical and chemical properties of the monolithic films. The model drugs, salicylic acid and chlorpheniramine maleate, and two poly(methyl methacrylate) copolymers of different permeabilities (Eudragit RL and Eudragit RS), with and without additional adjuvants, were used to form monolithic matrix films for controlled drug release. Adjuvants, including polyethylene glycols (PEG 400 and PEG 8000) and poly(vinylpyrrolidones) (PVP-K15 and PVP-K90), were incorporated into films of Eudragit RL PM and Eudragit RS PM. The moisture permeation constant, glass transition temperature (Tg), tensile strength, and drug release profiles were determined for each acrylic resin slab to correlate the physicochemical and physicomechanical film properties to observed drug release. Faster rates of drug diffusion were observed with the addition of PEG 400 to the films, because of its plasticizing effect and the resultant increased moisture permeability of the matrix. An exception existed with the Eudragit RL PM film containing salicylic acid where drug-polymer interactions inhibited drug diffusion. The small changes in moisture permeability, Tg, and tensile strength observed with incorporation of the PVPs had an insignificant influence on the dissolution results for salicylic acid from Eudragit RS PM films. Increases in the tensile strength and Tg after addition of PVP to the Eudragit RS PM matrix support the observed decreased rate of diffusion for chlorpheniramine maleate. The pores formed by migration of the hydrophilic adjuvants from the films altered the diffusion kinetics of the matrix, compared with that of the nonporous polymer, when only the antihistamine was present.     

Influence of processing parameters and formulation factors on the drug release from tablets powder-coated with Eudragit L 100-55.

The aim of this study was to develop a dry powder coating process for chlorpheniramine maleate (CPM) tablets using Eudragit L 100-55 as the delayed release polymer. Powder coating, a water and organic solvent-free process, was investigated as a method to prevent the migration of an ionizable, highly water soluble model drug into the polymeric film during the coating process. Eudragit L 100-55 was pre-plasticized with triethyl citrate (TEC) using hot-melt extrusion at levels of 20%, 30%, and 40%, based on the polymer weight. The extrudate was subsequently cut into pellets and cryogenically ground into a fine powder. Talc was incorporated into the coating powder as an anti-tack agent. PEG 3350 was used as a primer for the powder coating of tablets with pre-plasticized Eudragit L 100-55. The addition of polyethylene glycol 3350 (PEG 3350) to the pre-plasticized Eudragit L 100-55 was necessary to enhance the adhesion of the coating powder to the tablet cores. PEG 3350 also improved film formation and coalescence of the polymeric particles due to its plasticization effects on the acrylic polymer. For comparison, theophylline tablets were also coated with pre-plasticized Eudragit L 100-55. Theophylline was selected as a less water soluble model drug. The powder coating process was performed in a modified laboratory scale spheronizer. The drug release rate was dependent both on TEC content and the coating level. The stability of the powder-coated CPM tablets was confirmed at 25 degrees C/60% RH over a storage time of 12 weeks.     

Swellable matrices for the controlled-release of diclofenac sodium: formulation and in vitro studies

Oral administration has been the most usual and convenient employed route of drug delivery systems. Particularly, oral sustained-release systems for the delivery of drugs by a process of continuous swelling of the polymeric carrier have been investigated. Thus, the goal of this study was to evaluate the effects of hydroxypropyl methylcellulose (HPMC) and carboxypolymer (Carbopol 934) on the release behavior of diclofenac sodium (DS) from a swellable matrix tablet system. Nine different DS controlled-released tablets were compressed by using the wet-granulation technology. The influence of the polymer content, the polymer ratio, the polymeric swelling behavior, and the pH changes on the release rate of DS was investigated. There was no significant difference in drug release when total polymer concentration was 10%. When the tablets were formulated having 20% or 30% of HPMC/carbomer, it was observed that a more rapid release of DS occurred as the carboxypolymer ratio within the matrices increased. In agreement with previous results, the dissolution studies demonstrated that the combination of these two polymeric matrix formers resulted in near zero-order release rate of DS. The DS release from all these matrix tablets was pH dependent, being markedly reduced at lower pH, and could be attributed to the poor solubility of DS at this pH value. In HCl 0.1 N solution, HPMC controlled drug release because the carbomer has a low solubility at this pH. As the pH increased, the carbomer became ionized, being able to interact with HPMC to control the drug release.     

青蒿琥酯肠溶纤维的制备及体外释放研究

目的 制备青蒿琥酯肠溶纤维,考察其体外释放行为。方法 以尤特奇S100和L100-55为聚合物基质,添加一定量的青蒿琥酯,通过静电纺丝方法制备得到一系列载有青蒿琥酯的尤特奇纤维S100/ART和L100-55/ART。以紫外-可见分光光度法测定青蒿琥酯含量,计算S100/ART和L100-55/ART纤维的载药量和包封率,用SEM、TG和FTIR对其形貌、热稳定性和药物在纤维载体中状态进行表征,用溶出度测定仪以桨法测定其体外药物释放。结果 载药尤特奇纤维S100/ART和L100-55/ART结构均一,热稳定性良好,载药量可控,包封率高,药物以非晶态分散在纤维中;在pH=1.2人工胃液中释放的药物量较少,而在pH=6.8人工肠液中释放出大部分药物。在pH=1.2环境下S100/ART比L100-55/ART释放出更少的青蒿琥酯,在pH=6.8时释放出更多的青蒿琥酯。S100/ART和L100-55/ART亦具有一定的青蒿琥酯缓释作用。结论 载药尤特奇纤维S100/ART和L100-55/ART可以用作青蒿琥酯肠溶制剂,作为青蒿琥酯肠溶纤维,S100/ART比L100-55/ART效果更好。制备得到的青蒿琥酯肠溶纤维,可以用于青蒿琥酯的肠道靶向递送和释放,并有望提高青蒿琥酯的口服生物利用度。     

Characterization of the interactions between polymethacrylate-based aqueous polymeric dispersions and aluminum lakes.

Instability in film coating formulations can arise from interactions between aluminum lake pigments and aqueous polymeric dispersions. The purpose of this study was to characterize the interactions between three polymethacrylate-based aqueous polymeric dispersions (Eudragit RS 30 D, Eudragit L 30 D-55, and Eudragit NE 30 D) and aluminum lakes. Particle size measurements, pH stability profiles, zeta potential measurements, and microscopy were used to study mixed dispersions of the polymeric latices and the lakes. Interactions leading to dispersion instability were related to the surface charge of the components in the formulation. Interactions between the ionic polymers and the lakes arose from instability of the lakes outside a certain pH range resulting in the release of electrolytes, which led to aggregation of the polymeric particles. Interactions between the nonionic polymer and the lakes were related to the polymer modifying the surface charge of the lakes, resulting in aggregation of the pigment particles.     

Evaluation of the deformation behavior of binary systems of methacrylic acid copolymers and hydroxypropyl methylcellulose using a compaction simulator

Methacrylic acid copolymers have been shown to enhance release of weakly basic drugs from rate controlling polymer matrices through the mechanism of microenvironmental pH modulation. Since these matrices are typically formed through a compaction process, an understanding of the deformation behavior of these polymers in there neat form and in combination with rate controlling polymers such as HPMC is critical to their successful formulation. Binary mixes of two methacrylic acid copolymers, Eudragit L100 and L100-55 in combination with HPMC K4M were subjected to compaction studies on a compaction simulator. The deformation behavior of the powder mixes was analyzed based on pressure-porosity relationships, strain rate sensitivity (SRS), residual die wall force data and work of compaction. Methacrylic acid copolymers, L100-55 and L-100 and the hydrophilic polymer, HPMC K4M exhibited Heckel plots representative of plastic deformation although L-100 exhibited significantly greater resistance to densification as evident from the high yield pressure values ( approximately 120MPa). The yield pressures for the binary mixes were linearly related to the weight fractions of the components. All powder mixes exhibited significant speed sensitivity with SRS values ranging from 21.7% to 42.4%. The residual die-wall pressures indicated that at slow speeds (1mm/s) and at lower pressures (<150MPa), HPMC possesses significant elastic behavior. However, the good compacts formed at this punch speed indicate significant plastic deformation and bond formation which is able to predominate over the elastic recovery component. The apparent mean yield pressure values, the residual die-wall forces and the net work of compaction exhibited a linear relationship with mixture composition, thereby indicating predictability of these parameters based on the behavior of the neat materials.