Preparation and characterization of spray-dried valsartan-loaded Eudragit® E PO solid dispersion microparticles

The purpose of this study was to develop the immediate release stomach-specific spray-dried formulation of valsartan (VAL) using Eudragit^® E PO (EPO) as the carrier for enhancing dissolution rate in a gastric environment. Enhanced solubility and dissolution in gastric pH was achieved by formulating the solid dispersion using a spray drying technique. Different combinations of drug–polymer–surfactant were dissolved in 10% ethanol solution and spray-dried in order to obtain solid dispersion microparticles. Use of the VAL–EPO solid dispersion microparticles resulted in significant improvement of the dissolution rate of the drug at pH 1.2 and pH 4.0, compared to the free drug powder and the commercial product. A hard gelatin capsule was filled with the VAL–EPO solid dispersion powder prior to the dissolution test. The increased dissolution of VAL from solid dispersion microparticles in gastric pH was attributed to the effect of EPO and most importantly the transformation of crystalline drugs to amorphous solid dispersion powder, which was clearly shown by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and powder X-ray diffraction (P-XRD) studies. Thus, VAL, a potential antihypertensive drug in the form of a solid dispersion microparticulate powder, can be effectively delivered in the immediate release dosage form for stomach-specific drug delivery.     

冷冻干燥法制备甲苯磺酸拉帕替尼固体分散体及其大鼠药动学评价

目的用冷冻干燥技术制备甲苯磺酸拉帕替尼固体分散体,以提高其生物利用度。方法以PVPS630和soluplus^■为载体,采用冷冻干燥法制备甲苯磺酸拉帕替尼固体分散体,通过SEM、DSC、XRPD等手段对固体分散体进行表征,通过表观溶解度、溶出度和大鼠体内药动学测定,评价固体分散体的增溶效果和生物利用度的改善情况。结果在相同药载比的条件下,PVPS630组的溶出度和表观溶解度均优于soluplus^■组。DSC、XRPD、SEM等表征结果显示,PVPS630为载体的固体分散体中,原料均以非晶态存在,而以soluplus^■为载体时,只有药载比为1∶3条件下,原料才呈现非晶态特征。大鼠药动学测定结果表明,固体分散体(甲苯磺酸拉帕替尼-PVPS630为1∶3)较上市药品AUC提高23.64%。结论载体PVPS630与甲苯磺酸拉帕替尼的相容性更理想;固体分散技术有助于本品提高生物利用度。     

Properties of theophylline tablets dry powder coated with Eudragit® E PO and Eudragit® L 100-55

The aim of the present study was to investigate the influence of Eudragit^® E PO on the drug release mechanism of Eudragit^® L 100-55 film coatings applied to theophylline tablets by a dry powder coating technique. The process was entirely liquid-free. Calculation of the Flory-Huggins interaction parameter based on solubility parameters suggested immiscibility of the two copolymers. MDSC thermograms were characterized by two glass transitions for the investigated Eudragit^® E PO/Eudragit^® L 100-55 ratios and confirmed incomplete miscibility of the copolymers at processing conditions. FT-IR analysis was employed to study binding interactions of the polymers. Due to the higher affinity of the plasticizer, triethyl citrate, for Eudragit^® E PO compared to Eudragit^® L 100-55, redistribution of the plasticizer was observed during the curing phase of the process. Plasticizer migration also affected the initial phase of drug release from powder-coated theophylline tablets that were stored for four weeks. Drug release from powder-coated tablets was dependent on the polymer blend ratio, coating thickness, and the pH of the dissolution medium. A broad range of pH dependent theophylline release profiles were obtained as a function of the polymer blend ratio. The particle size of the coating powder influenced the microstructure of the film coating.     

Development of a novel tablet-in-capsule formulation of mesalamine for inflammatory bowel disease

Objective: The objective of the present work was to develop a tablet-in-capsule type of multiunit system, which releases the drug in a controlled manner at pre-programmed time intervals.

Methods: The system consists of an enteric-coated hydroxypropyl methylcellulose capsule filled with four units of mesalamine minitablets, each of which was further coated with different ratios of Eudragit^® E100 and Eudragit^® RS100.

Results: In vitro evaluation of tablets coated with Eudragit^® E100 and Eudragit^® RS100 at different pH conditions revealed that at lower pH levels (2.0, 3.6 and 5.5 pH), the drug release is mainly governed by the dissolution of Eudragit^® E100 from the Eudragit^® E100 and Eudragit^® RS100 coat. In vitro evaluation of capsules enteric coated with Eudragit^® L100 and Eudragit^® S100 revealed that a maximum lag time of 3?h and 4?h was obtained, respectively. In vivo roentgenographic evaluation in rabbits revealed that the developed system remained intact until it reaches the targeted region of the gastrointestinal tract, i.e. ileum and colon, where the tablets were released after the dissolution of the enteric coat Eudragit^® L100 and Eudragit^® S100, respectively.

Conclusion: The developed system exhibited a promising targeting behavior and hence may be used for the treatment of inflammatory bowel disease.     

A new self-emulsifying formulation of mefenamic acid with enhanced drug dissolution

To enhance the dissolution of poorly soluble mefenamic acid, self-emulsifying formulation (SEF), composing of oil, surfactant and co-surfactant, was formulated. Among the oils and surfactants studied, Imwitor^® 742, Tween^® 60, Cremophore^® EL and Transcutol^® HP were selected as they showed maximal solubility to mefenamic acid. The ternary phase diagram was constructed to find optimal concentration that provided the highest drug loading. The droplet size after dispersion and drug dissolution of selected formulations were investigated. The results showed that the formulation containing Imwitor^® 742, Tween^® 60 and Transcutol^® HP (10:30:60) can encapsulate high amount of mefenamic acid. The dissolution study demonstrated that, in the medium containing surfactant, nearly 100% of mefenamic acid were dissolved from SEF within 5 min while 80% of drugs were dissolved from the commercial product in 45 min. In phosphate buffer (without surfactant), 80% of drug were dissolved from the developed SEF within 5 min while only about 13% of drug were dissolved in 45 min, from the commercial product. The results suggested that the SEF can enhance the dissolution of poorly soluble drug and has a potential to enhance drug absorption and improve bioavailability of drug.     

Improvement of dissolution rate of tacrolimus by solid dispersion technique

Tacrolimus has a poor solubility in water ranging from 4 to 12 μg mL^?1. The mean bioavailability is ~21 %.The present study was carried out with a view to enhance the dissolution rate of poorly water-soluble drug tacrolimus using Gelucire 44/14^® and Gelucire 50/13^® as carriers and lactose monohydrate as an adsorbent. A combination of melt and adsorption techniques was employed for the preparation of solid dispersions (SD) to make final product easy for handling. Phase solubility study was conducted to evaluate the effect of carriers on aqueous solubility of tacrolimus. In order to elucidate the mechanism of dissolution enhancement, solid state characteristics were investigated using Fourier transform infrared spectroscopy, differential scanning calorimetry and powder X-ray diffraction. Mathematical modeling of in vitro dissolution data indicated the best fitting with Korsemeyer–Peppas model and the drug release kinetics primarily as Fickian/anomalous diffusion. All prepared solid dispersions showed dissolution improvement compared to pure drug, with Gelucire 50/13^® as the superior carrier over Gelucire 44/14^®. Almost similar dissolution profile was obtained as a function of storage time; this can be explained by no change in XRD and DSC pattern after 45 days storage period.     

Enhancement of solubility and dissolution of Coenzyme Q10 using solid dispersion formulation

This study aimed to develop a stable solid dispersion of Coenzyme Q₁₀ (CoQ₁₀) with high aqueous solubility and dissolution rate. Among various carriers screened, poloxamer 407 was most effective to form a superior solid dispersion of CoQ₁₀ having significantly enhanced solubility. Particularly, solid dispersion of CoQ₁₀ with poloxamer 407 in the weight ratio of 1:5 prepared by melting method enhanced the solubility of CoQ₁₀ to the greatest extent. However, it exhibited poor stability and hence Aerosil^® 200 (colloidal silicon dioxide) was incorporated into the solid dispersion as an adsorbent to inhibit the recrystallization process. The solid dispersion of CoQ₁₀, poloxamer 407 and Aerosil^® 200 in the weight ratio of 1:5:6 exhibited improved stability with no significant change in solubility during the 1-month stability test. Moreover, the solid dispersion formulation containing Aerosil^® 200 significantly enhanced the extent of drug release (approx. 75% release) as well as the dissolution rate of CoQ₁₀. In conclusion, the present study has developed the stable solid dispersion formulation of CoQ₁₀ with poloxamer 407 and Aerosil^® 200 for the enhanced solubility and dissolution of CoQ₁₀, which could also offer some additional advantages including ease of preparation, good flowability and cost-effectiveness.     

Antioxidant activity and photostability assessment of trans-resveratrol acrylate microspheres

Trans-resveratrol (RSV) was microencapsulated in Eudragit^® RS100 and RL100 resin blends. Lyophilized microspheres were characterized in the solid state for their micromeritic properties and drug loading. FT-IR, PXRD, and DSC analyzes suggested that RSV formed an intimate microcrystalline dispersion within the polymer network, also confirmed by SEM analysis. This produced a reduced degradation of RSV after storage at 40?°C, compared to the neat drug, and a protection of the drug from UV light-induced trans-cis isomerization (60% intact drug was found after 60?s irradiation at 350?nm, compared to 37% for the pure drug). Solubility and in vitro dissolution studies indicated that microencapsulation did not improve the dissolution pattern of RSV in simulated gastric and intestinal aqueous fluids. Evaluation of the in vitro antioxidant activity showed that, compared to the neat drug in aqueous solution, RSV loaded in the microspheres retained for a longer time, up to 22 days of incubation, the initial ORAC capacity. The present study thus demonstrated that Eudragit^® Retard resins can be used to easily produce micro-sized solid dispersions with RSV, for potential oral administration, contributing to ameliorate the physico-chemical stability and antioxidant activity of this compound.     

Preparation and evaluation of tamsulosin hydrochloride sustained-release pellets modified by two-layered membrane techniques

The aim of the present study was to develop tamsulosin hydrochloride sustained-release pellets using two-layered membrane techniques. Centrifugal granulator and fluidized-bed coater were employed to prepare drug-loaded pellets and to employ two-layered membrane coating respectively. The prepared pellets were evaluated for physicochemical characterization, subjected to differential scanning calorimetry (DSC) and in vitro release of different pH. Different release models and scanning electron microscopy (SEM) were utilized to analyze the release mechanism of Harnual^® and home-made pellets. By comparing the dissolution profiles, the ratio and coating weight gain of Eudragit^® NE30D and Eudragit^® L30D55 which constitute the inside membrane were identified as 18:1 and 10%–11%. The coating amount of outside membrane containing Eudragit^® L30D55 was determined to be 0.8%. The similarity factors (f₂) of home-made capsule and commercially available product (Harnual^®) were above 50 in different dissolution media. DSC studies confirmed that drug and excipients had good compatibility and SEM photographs showed the similarities and differences of coating surface between Harnual^® and self-made pellets before and after dissolution. According to Ritger-Peppas model, the two dosage form had different release mechanism.     

Formulation of highly purified fenugreek gum based silica lipid drug delivery system for simvastatin with enhanced dissolution rate and in vitro characterization

In current study, highly purified fenugreek gum (HPFG) isolated by patented method explored as emulsifier and hydrophilic solid carrier in drug delivery system. Anti-hyperlipidemic drug simvastatin (SIM) was selected as drug model for the study as it is associated with poorly water solubility and low bioavailability problems (<5 %). A suitable HPFG-based silica lipid system composed of SIM (1.5 %), medium chain triglyceride Capmul^® MCM (10 %) as lipid phase, 0.6 % HPFG as emulsifier and HPFG 2.5 %, different grades colloidal silica (7.5 %) (Aerosil^® 300 Pharma, Aerosil^® 380 Pharma and Aeroperl^® 300 Pharma) as hydrophilic solid carriers was developed. The optimized HPFG-based silica lipid systems were characterized for physical characteristics like flow ability, compressibility, redispersiblity, solubility and in vitro drug release using USP apparatus II in pH 6.8 phosphate buffer. The system was also characterized for Fourier transform infrared spectroscopy, powder X-ray diffractometry (PXRD), differential scanning calorimetry (DSC) and scanning electron microscopy (SEM). The developed formulation was found to have excellent flow property, readily redispersiblity, better aqueous solubility and showed 3–4-fold increase in dissolution rate as compared to plain drug and marketed formulation (Simlo^® 10). Transition of crystalline drug to amorphous state was confirmed by DSC, PXRD and SEM studies. Enhanced dissolution rate and solubility possibly attributed to improved wetting, amorphous drug state and facilitated diffusion from lipid-based system. Thus developed HPFG-based silica lipid system provides an alternative means for SIM with enhanced dissolution rate and stability in oral solid dosage form.     

Preparation and in vivo evaluation of immediate-release pellet containing celecoxib solid dispersion

The aim of this study was to make use of small size of immediate-release (IR) pellet and amorphous state of solid dispersion to increase solubility of celecoxib (CLX), a drug in BCS class II. Primary, binary and ternary solid dispersions were developed to choose the final components for solid dispersion. A ternary novel solid dispersion was prepared by incorporation of one aqueous soluble polymer (povidone k17; PVP 17PF), Methacrylate copolymer-based gastric soluble polymer (Eudragit^? EPO) and one pH modulator (MgO). This combination was effective to increase solubility in pH 1.2 up to 25?C30?%. The mechanism of solubility enhancement was proven by DSC, PRXD, and FT-IR. Accordingly, hydrogen bonding or electrostatic interaction of CLX with PVP/Eudragit^? EPO was the main cause to form the amorphous state of CLX within polymer cluster which increasing solubility of drug. Besides, MgO played an important role to change microenviroment for solid dispersion. Pellets containing this solid dispersion were prepared by extrusion and spheronization technique. Effect of four kinds of additive (calcium hydrogen phosphate dihydrate, NaHCO₃, crospovidone, and sodium dodecyl sulfate) on dissolution of CLX from IR pellet was also determined. Because of highest dissolution rate, formulation using sodium dodecyl sulfate was used for pharmacokinetics study. Solid dispersion-IR pellet formulation presented bioequivalence and lower variability in comparison with reference product.     

Fabrication of Eudragit polymeric nanoparticles using ultrasonic nebulization method for enhanced oral absorption of megestrol acetate

Abstract

Megestrol acetate (MGA) is used as a progestagen to treat advanced cancers in the breast or uterus and anorexia-cachexia syndrome in cancer patients. Due to its low solubility (BCS class II), MGA bioavailability needs to be enhanced for efficacy and safety. We developed MGA-encapsulated Eudragit^® L100 (EUD) nanoparticles (MGA-EUD (1:1) and MGA-EUD (2:1)) using an ultrasonic nebulization method. MGA-EUD (1:1) and MGA-EUD (2:1) consisted of MGA and EUD at the mass ratios of 1:1 and 2:1. Their physicochemical properties, i.e. particle size, loading efficiency, morphology, and crystallinity were determined. Dissolution tests were performed using USP method II. For pharmacokinetics, they were orally administered at 50?mg/kg to mice. Microcrystalline MGA suspension (MGA-MC, Megace^®, BMS) was used as control. MGA-EUD (1:1) and MGA-EUD (2:1) had a smooth and spherical shape of 0.70 and 1.05?µm in diameter with loading efficiencies of 93 and 95% showing amorphous states of MGA. They significantly enhanced the dissolution potential of MGA. Oral bioavailability of MGA-EUD (1:1) and MGA-EUD (2:1) increased 2.0- and 1.7-fold compared to that of MGA-MC. It suggests that ultrasonic nebulization method for the fabrication of polymeric nanoparticles is a promising approach to improve the bioavailability of poorly soluble drugs.     

Preparation and characterisation of lornoxicam solid dispersion systems using hot melt extrusion technique

The aim of the research study was to investigate the ability of Soluplus^® and surfactant individually as well as in combination to improve the solubility, subsequently the dissolution profile of lornoxicam (LORX). A laboratory size single screw rotating extruder with temperature and speed control parameters employed during hot melt extrusion (HME) processing of LORX along with polymer-surfactant blends. Soluplus^® used as primary solubilizing agent for preparing solid dispersion (SD). Along with Soluplus^® different concentrations of surfactants such as PEG 400, Lutrol F127, Lutrol F68 were used to solve the permeability issues related to LORX. Encapsulation of LORX particles inside the molten matrix of polymer-excipient blend was confirmed by DSC, XRD and FT-IR. Drug excipient microscopic interaction was further confirmed by scanning electron microscopy (SEM). Depending upon the ratio of the polymer and surfactants used, the solubility of the hot melt extruded LORX was improved and found to be in the range 35–86 μg/ml (actual aqueous solubility of LORX was found to be 0.0083 μg/ml). Dissolution profile of the extruded SD was improved and was found to be in the range of 98–104 % within 20 min (actual dissolution profile of LORX was found to be 8 % at the end of 1 h). SEM and Raman images suggest the formation of amorphous dispersion systems. SD was subjected to stability studies as per ICH guidelines and found to be stable after 6 months when analyzed by HPLC. SD prepared from HME significantly improves the solubility and dissolution profile of LORX—a BCS class II drug.     

Enhanced oral delivery of risperidone through a novel self-nanoemulsifying powder (SNEP) formulations: in-vitro and ex-vivo assessment

Context: The oral delivery of risperidone encounters a number of problems, such as pH dependent solubility and low bioavailability, due to its lipophilicity and aqueous insolubility.

Objective: To improve the solubility, dissolution and intestinal permeation thereby bioavailability of risperidone through a novel self-nanoemulsifying powder (SNEP) formulations.

Materials and methods: Oleic acid, Tween^® 20, PEG 600 and Aerosil^® 200 were chosen as oil, surfactant, co-surfactant and carrier, respectively from solubility and emulsification studies. Ternary phase diagram was constructed to determine emulsifying region.

Results and discussion: The Z-average and polydispersity Index of developed formulation was 83.1?nm and 0.306, respectively. Ex vivo permeation studies on isolated rat intestine indicated that the amount of risperidone permeated from SNEP formulation was increased around 4- and 1.8-fold than that of pure drug and marketed formulation, respectively.

Conclusion: This developed SNEP formulations can be regarded as novel and commercially feasible alternative to the current risperidone formulations.     

On the inherent properties of Soluplus and its application in ibuprofen solid dispersions generated by microwave-quench cooling technology

Abstract

Polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol graft copolymer, or Soluplus^®, is a relatively new copolymer and a promising carrier of amorphous solid dispersions. Knowledge on the inherent properties of Soluplus^® (e.g. cloud points, critical micelle concentrations, and viscosity) in different conditions is relatively inadequate, and the application characteristics of Soluplus^®-based solid dispersions made by microwave methods still need to be clarified. In the present investigation, the inherent properties of a Soluplus^® carrier, including cloud points, critical micelle concentrations, and viscosity, were explored in different media and in altered conditions. Ibuprofen, a BCS class II non-steroidal anti-inflammatory drug, was selected to develop Soluplus^®-based amorphous solid dispersions using the microwave-quench cooling (MQC) method. Scanning electronic microscopy (SEM), differential scanning calorimetry (DSC), powder X-ray diffraction (PXRD), Raman spectroscopy (RS), and Fourier transform infrared spectroscopy (FT-IR) were adopted to analyze amorphous properties and molecular interactions in ibuprofen/Soluplus^® amorphous solid dispersions generated by MQC. Dissolution, dissolution extension, phase solubility, equilibrium solubility, and supersaturated crystallization inhibiting experiments were performed to elucidate the effects of Soluplus^® on ibuprofen in solid dispersions. This research provides valuable information on the inherent properties of Soluplus^® and presents a basic understanding of Soluplus^® as a carrier of amorphous solid dispersions.     

Combination of a hot-melt subcoating and an enteric coating for moisture protection of hygroscopic Sennae fructus tablets

The objective of this study was to investigate the efficiency of moisture protection of hot-melt coatings solely and in combination with an enteric coating on hygroscopic tablet cores containing a spray-dried Sennae fructus extract. Tablet cores were subcoated with different hot-melt coating materials: medium chain tryglycerides, stearic acid, Precirol^® ATO 5, and Compritol^® 888 ATO, at varying amounts and coated with Eudragit^® L 30D-55 for enteric resistance. Subcoating penetration, tablet disintegration, dissolution times, tablet hygroscopicity, and tablet properties such as weight, height, diameter, and hardness were analyzed. 3?mg/cm² of tablet surface seemed to be sufficient if sustained release is not required. Thereby, hot-melt coating did not adversely affect the tablet properties with regard to subsequent processing steps. Compared to the tablet cores it was possible to reduce the moisture uptake by 85% at 75% relative humidity with tablets coated with a combination of Precirol^® ATO 5 and Eudragit^® L 30D-55. This combination was more efficient than high amounts of Eudragit^® L 30D-55. Hot-melt coating proved to be a suitable technique for the application of subcoating material to tablet cores serving as a barrier against water permeation into hygroscopic tablet cores without exceeding the required disintegration times.     

Preparation, Characterization, and In Vitro Evaluation of Ezetimibe Binary Solid Dispersions with Poloxamer 407 and PVP K30

Ezetimibe (EZE), a water insoluble drug, depicts variable bioavailability. The objective of the present investigation was to improve dissolution characteristics of EZE, which might offer improved bioavailability. The solid dispersions were prepared using poloxamer 407 (L 127) and polyvinyl pyrrolidone by melt and solvent method, respectively. Phase solubility studies indicated linear relationship between drug solubility and carrier concentration. In vitro release studies revealed improvement in the dissolution characteristics of EZE in solid dispersions. Solid dispersion with L 127 gave better rate and extent of dissolution. The best fit model indicating the probable mechanism of drug release from solid dispersions was found to be Korsemeyer–Peppas. The results of characterization of solid dispersions by Fourier transform infrared spectroscopy, differential scanning calorimetry, and powder X-ray diffraction revealed reduction in drug crystallinity which might be responsible for improved dissolution properties. The tablets of solid dispersion, containing L 127 prepared by direct compression, exhibited better drug release as compared to marketed formulation.     

Application of viscometry and solubility parameters in miconazole patches development

Nine binary mixtures of seven different methacrylic copolymer systems (Plastoid^® E 35 L (PLE) and Plastoid^® L 50 (PLL); Eudragit^® (Eu) NE, RL, RS, L, S) were tested as components of monolayer patches containing miconazole. Only three mixtures (PLE:EuNE, PLE:EuRL and PLE:EuRS) were suitable for the preparation of placebo matrices. Miconazole patches with good technological characteristics were obtained by using mixtures of PLE:EuNE and PLE:EuRL. The in vitro miconazole release rate from the two patches and from the patch prepared using only PLE were significantly different. The amounts of drug released in 24 h were quite satisfactory. A mathematical model based on capillary viscometry data was used for the evaluation of interactions between copolymers. This was useful to predict and understand the mechanisms related to the instability of the prepared mixture. The solubility parameters of the drug and of the matrix were also calculated. Miconazole release was faster when the difference between the solubility parameters of the matrix and of the drug was higher. A relationship between miconazole release rate and the difference of drug and matrix solubility parameters was found. Therefore, the solubility parameter could be applied in formulation studies of patches.     

微管蛋白抑制剂SUD-35固体分散体的制备、鉴定及初步体外药效学研究

目的将难溶性微管蛋白抑制剂SUD-35制备成固体分散体,以增加其溶解度及溶出速率。方法以聚乙二醇6000为载体,溶剂-熔融法制备SUD-35固体分散体。采用差示扫描量热分析与X-射线衍射观察药物在载体中的存在状态,并进行溶解度和体外溶出度研究。采用MTT法对SUD-35固体分散体对小鼠白血病L1210细胞药效进行测定。结果 SUD-35固体分散体中SUD-35的溶解度和溶出速率相对原料药和物理混合物均有明显提高,差示扫描量热分析与X-射线衍射结果显示SUD-35以无定型状态存在于固体分散体中,细胞药效结果显示SUD-35固体分散体对小鼠白血病L1210细胞增殖抑制率强于SUD-35纯药。结论聚乙二醇6000为载体制备SUD-35固体分散体,可显著提高SUD-35的溶解度及溶出速率。     

Fabrication and evaluation of Eudragit® polymeric films for transdermal delivery of piroxicam

The aims of this work were to develop and characterize the prolonged release piroxicam transdermal patch as a prototype to substitute oral formulations, to reduce side effects and improve patient compliance. The patches were composed of film formers (Eudragit^®) as a matrix backbone, with PVC as a backing membrane and PEG200 used as a plasticizer. Results from X-ray diffraction patterns and Fourier transform-infrared spectroscopy indicated that loading piroxicam into films changed the drug crystallinity from needle to an amorphous or dissolved form. Piroxicam films were prepared using Eudragit^® RL100 and Eudragit^® RS100 as film formers at various ratios from 1:0 to 1:3. Films prepared solely by Eudragit^® RL100 showed the toughest and softest film, while other formulations containing Eudragit^® RS100 were hard and brittle. Drug release kinetic data from the films fitted with the Higuchi model, and the piroxicam release mechanism was diffusion controlled. Among all formulation tested, Eudragit^® RL100 films showed the highest drug release rate and the highest drug permeation flux across human epidermal membrane. Increasing drug loading led to an increase in drug release rate. Eudragit^® can be used as a film former for the fabrication of piroxicam films.