In Vitro and in Vivo Evaluation of Whole and Half Tablets of Sustained-Release Adinazolam Mesylate

The mechanism of release from sustained-release adinazolam mesylate tablets was assessed by the Higuchi equation and by analysis of drug release profiles through 60% released using the Peppas equation. Computed values of the diffusional exponent, n, ranged from 0.59 to 0.66. Values of n in this range are consistent with a mixed mechanism of release, with diffusion of drug through the hydrated polymer matrix and relaxation of this matrix being the principal processes controlling release. The rate of in vitro drug release was increased for half tablets relative to whole tablets and is attributed to an increase in the surface to volume ratio of half tablets of about 16%. This increase in surface-to-volume ratio of half tablets was reflected by an increase in the constant, k, from the Peppas equation of 20–23% and by an increase in the slope of Higuchi plots of 12–18% for four lots of tablets. In vivo/in vitro relationships from two bioavailability studies were thoroughly evaluated. Using either a linear or a quadratic relationship, an in vivo/in vitro correlation exists for sustained-release adinazolam mesylate tablets.     

Diffusion in HPMC Gels. I. Determination of Drug and Water Diffusivity by Pulsed-Field-Gradient Spin-Echo NMR

Purpose. This work describes diffusivity measurements of drug (adinazolam mesylate) and water in a variety of solutions including polymer gels. Methods. Pulsed-field-gradient spin-echo (PFGSE) NMR methods were employed to measure the diffusivity. Results. In binary component solutions, adinazolam diffusivity is generally found to exhibit an exponential dependence on the concentration of the viscosity-inducing agent (VIA), which is glucose, lactose, maltoheptaose, hydroxypropyl methylcellulose (HPMC) or drug itself. An increasing obstruction power to drug diffusion from glucose to HPMC is observed, which can be related to the polymerization degree of the VIA. In contrast, adinazolam diffusivity in HPMC gels shows little dependence upon the polymer viscosity grades examined (K100LV, K4M, and K15M). The temperature dependence of adinazolam diffusivity in dilute VIA solutions reveals that the diffusion barrier for the drug is similar to that for self-diffusion of water. Conclusions. The retarding effect from the VIA for drug diffusion is concluded to be primarily associated with a steric obstruction mechanism. In multicomponent gels with varied concentrations of drug, lactose and HPMC, the drug diffusivity can be approximately described as an exponential function of the summation of the products of the proportionality constant (K_i) and concentration for each VIA component. In contrast, water diffusion behavior shows an universal exponential dependence upon the VIA concentration and small dependence upon the nature of the VIA. The interpretation of the diffusivity data is discussed and compared to two existing diffusion models (Yasuda and Mackie-Meares models).     

Effect of formulation variables on drug and polymer release from HPMC-based matrix tablets

The objective of this work was to assess the effect of two formulation variables, hydroxypropylmethylcellulose (HPMC)/lactose ratio and HPMC viscosity grade, on the release of a model drug and HPMC, as well as the mechanism of drug release from HPMC-based matrix tablets. A water-soluble compound, adinazolam mesylate, was used as the model drug. Both drug and HPMC release were found to be a function of the formulation variables, with higher drug and HPMC release rates for formulations with lower HPMC/lactose ratios and lower HPMC viscosity grades. However, the K15M and K100M formulations had identical drug release profiles. All the drug release data fit well to the Higuchi expression. By comparing the drug and HPMC release data, it was concluded that diffusion of drug through the hydrated gel layer was the predominant drug release mechanism for most of the formulations studied.     

Comparison of the spectrum of cognitive effects of alprazolam and adinazolam after single doses in healthy subjects

Single doses of alprazolam (0, 0.5, 1.5 mg) or adinazolam mesylate sustained release tablets (SR) (0, 15, 45 mg) were administered to separate groups of 12 healthy men in a crossover design. Psychomotor performance was assessed by digit symbol substitution (DSST), and memory was assessed using a test battery which reflects various aspects of memory, including attention/working memory, explicit memory (recall of categorically related words), semantic memory (fragmented picture recognition, generation of category exemplars), and implicit memory (time saved in resolving fragmented pictures on the second exposure). Maximal psychomotor performance and memory decrements for the highest active doses were significantly different from placebo for all tasks at some time after dosing. The maximum decrement in DSST was not significantly different between drugs at the high dose (P=0.288). Maximum attention/working memory decrements were significantly different between the high doses of the active compounds (P=0.031), and the difference in maximum category recall decrement was marginally significant (P=0.067). Access to knowledge memory was not significantly altered by these drugs; these results are similar to those obtained for other benzodiazepines. Both drugs exhibited slight effects on implicit memory. The results suggest that the sedative and memory effects of these triazolobenzodiazepines may not be closely related and suggest that adinazolam has a somewhat different spectrum of cognitive effects relative to alprazolam.     

Pharmacokinetic and Pharmacodynamic Comparison of Immediate-Release and Sustained-Release Adinazolam Mesylate Tablets After Single- and Multiple-Dose Administration

The effect of adinazolam release rate on psychomotor performance and sedation was assessed by administering 40 mg adinazolam mesylate immediate-release (CT) tablets, 60 mg sustained-release (SR) tablets, and placebo in a double-blind crossover study in 15 healthy male subjects. A separate panel of 16 subjects received the above single doses and multiple-dose regimens of 40 mg CT tablets every 8 hr and 60 mg SR tablets every 12 hr according to a crossover design. Psychomotor performance was assessed by digit symbol substitution test, card sorting tasks, and sedation ratings. Following single-dose administration, dose-corrected adinazolam and N-desmethyladinazolam (NDMAD) AUC values were equivalent for SR and CT tablets. Peak adinazolam and NDMAD levels were lower and occurred later for the SR tablets. Decrements in card sorting were 50 and 3% at 1 hr and 17 and 20% at 6 hr for the CT and SR tablets, respectively. Maximal sedation scores were lower for the SR tablets compared to the CT. Dose-corrected AUC was comparable between single and multiple doses for both adinazolam and NDMAD; no differences were observed in 24-hr AUC at steady-state between CT and SR tablets. Fluctuation ratios were reduced for both adinazolam and NDMAD following SR tablets. Psychomotor and sedative effects were attenuated upon multiple dosing. Thus, the reduction in peak plasma NDMAD following SR tablet administration results in a lesser sedation and psychomotor impairment on acute administration, and tolerance to these effects occurs on mulitiple dosing.     

Double-blind comparison of alprazolam and adinazolam for panic and phobic disorders

Subjects primarily suffering from DSM-III panic disorders (agoraphobia with panic attacks, 13 subjects; panic disorder, one subject) were tested with two drug treatments after a baseline was established using single-blind placebo capsules three times daily for 1 week. Double-blind, 4-week crossover treatments were given with alprazolam, 0.5-6.0 mg/day, and adinazolam mesylate, 10-120 mg/day. Mean final doses in mg/day were 3.1 for alprazolam and 95.5 for adinazolam mesylate. Both were broadly effective in comparison with the baseline condition. Measures included self-rated symptoms and global impressions, physician-rated global impressions, and two forms of challenges, agoraphobic and noradrenergic. The two active drugs were highly similar in overall efficacy across the sample, but alprazolam was favored globally in six subjects, and adinazolam was favored globally in another six subjects. Only two subjects obtained maximal improvement ratings without side effects with both drugs. No diagnostic or demographic factor correlated with the differential in responses to the two active treatments. No clinically significant laboratory abnormalities occurred with either drug.     

Formulation development and optimization of bilayer tablets of aceclofenac

Objective: The objective of the present study was to develop bilayer tablets of aceclofenac that are characterized by initial burst drug release followed by sustained release of drug.

Methods: The fast-release layer of the bilayer tablet was formulated using microcrystaline cellulose (MCC) and HPMC K4M. The amount of HPMC E4M (X₁) and MCC (X₂) was used as independent variables for optimization of sustained release formulation applying 3² factorial design. Three dependent variables were considered: percentage of aceclofenac release at 1 h, percentage of aceclofenac release at 12 h, and time to release 50% of drug (t_50%). The composition of optimum formulation of sustained release tablets were employed to formulate double layer tablets.

Results: The results indicate that X₁ and X₂ significantly affected the release properties of aceclofenac from sustained release formulation. The double layer tablets containing fast-release layer showed an initial burst drug release of more than 30% of its drug content during first 1 h followed by sustained release of the drug for a period of 24 h.

Conclusion: The double layer tablets for aceclofenac can be successfully employed as once-a-day oral-controlled release drug delivery system characterized by initial burst release of aceclofenac for providing the loading dose of drug.     

Kinetics and dynamics of intravenous adinazolam, N-desmethyl adinazolam, and alprazolam in healthy volunteers

The pharmacokinetics and pharmacodynamics of adinazolam mesylate (10 mg), N-desmethyl adinazolam mesylate (NDMAD, 10 mg), and alprazolam (1 mg) were investigated in 9 healthy male subjects in a randomized, blinded, single-dose, 4-way crossover study. All drugs were intravenously infused over 30 minutes. Plasma adinazolam, NDMAD, and alprazolam concentrations, electroencephalographic (EEG) activity in the beta (12-30 Hz) range, performance on the Digit Symbol Substitution Test (DSST), and subjective measures of mood and sedation were monitored for 12 to 24 hours. Mean pharmacokinetic parameters for adinazolam, NDMAD, and alprazolam, respectively, were as follows: volume of distribution (L), 106, 100, and 77; elimination half-life (hours), 2.9, 2.8, and 14.6; and clearance (mL/min), 444, 321, and 84. More than 80% of the total infused adinazolam dose was converted to systemically appearing NDMAD. All 3 benzodiazepine agonists significantly increased beta EEG activity, with alprazolam showing the strongest agonist activity and adinazolam showing the weakest activity. Alprazolam and NDMAD significantly decreased DSST performance, whereas adinazolam had no effect relative to placebo. Adinazolam, NDMAD, and alprazolam all produced significant observer-rated sedation. Plots of EEG effect versus plasma alprazolam concentration demonstrated counterclockwise hysteresis, consistent with an effect site delay. This was incorporated into a kinetic-dynamic model in which hypothetical effect site concentration was related to pharmacodynamic EEG effect via the sigmoid E(max) model, yielding an effect site equilibration half-life of 4.8 minutes. The exponential effect model described NDMAD pharmacokinetics and EEG pharmacodynamics. The relation of both alprazolam and NDMAD plasma concentrations to DSST performance could be described by a modified exponential model. Pharmacokinetic-dynamic modeling was not possible for adinazolam, as the data did not conform to any known concentration-effect model. Collectively, these results indicate that the benzodiazepine-like effects occurring after adinazolam administration are mediated by mainly NDMAD.     

丁卡因口腔粘附片的研制

目的：研制丁卡因口腔粘附片。考察不同辅料的体外膨胀行为及释药性能。方法：采用聚维酮（PVP），羟丙甲纤维素（HPMC），羟丙纤维素（L-HPC）及卡波姆934（CP934）为生物粘附材料，以不同配比制备丁卡因口腔粘附片，桨板法测定其释放度。结果：采用CP/HPC，CP/HPMC配比作为粘附材料取得良好效果。     

The pharmacokinetics and pharmacodynamics of adinazolam: multi-ethnic comparisons

The pharmacokinetics and pharmacodynamics of adinazolam and N-demethyladinazolam (NDMAD), its major active metabolite, were compared in 39 healthy male volunteers (13 Asian, 12 Caucasian and 14 African-American). In a four-way, double-blind crossover design, subjects were administered (1) 30 mg oral adinazolam mesylate SR tablets, (2) 10 mg parenteral (IV) adinazolam mesylate, (3) 30 mg IV NDMAD and (4) placebo. Venous blood samples were collected at specific time intervals after drug administration and assayed for adinazolam and NDMAD concentrations. Sedation was rated at the time of each blood draw according to the Nurse-Rated Sedation Scale, and the digit-symbol substitution test was administered to evaluate psychomotor performance. After IV administration of adinazolam, Asians manifested significantly higher C_max, larger AUC and lower CL of both adinazolam and NDMAD than their Caucasian and African-American counterparts. Likewise, after IV NDMAD Asians had significantly higher NDMAD C_max and AUC than Caucasians and African-Americans. Most of these differences remained statistically significant after controlling for body surface area. With PO adinazolam, Asians also manifested substantially higher C_max, larger AUC and lower CL for both adinazolam and NDMAD; however, with the exception of C_max, these differences did not reach statistical significance. These results are in accordance with previous observations for ethnic-related differences in drug pharmacokinetics. In contrast, pharmacodynamic differences were not noted among the three study groups. Received: 19 June 1996/Final version: 17 September 1996     

Correlation between the viscoelastic properties of the gel layer of swollen HPMC matrix tablets and their in vitro drug release

Abstract

Drug release from hydroxypropyl methylcellulose (HPMC) hydrophilic matrix tablets is controlled by drug diffusion through the gel layer of the matrix-forming polymer upon hydration, matrix erosion or combination of diffusion and erosion mechanisms. In this study, the relationship between viscoelastic properties of the gel layer of swollen intact matrix tablets and drug release was investigated. Two sets of quetiapine fumarate (QF) matrix tablets were prepared using the high viscosity grade HPMC K4M at low (70?mg/tablet) and high (170?mg/tablet) polymer concentrations. Viscoelastic studies using a controlled stress rheometer were performed on swollen matrices following hydration in the dissolution medium for predetermined time intervals. The gel layer of swollen tablets exhibited predominantly elastic behavior. Results from the in vitro release study showed that drug release was strongly influenced by the viscoelastic properties of the gel layer of K4M tablets, which was further corroborated by results from water uptake studies conducted on intact tablets. The results provide evidence that the viscoelastic properties of the gel layer can be exploited to guide the selection of an appropriate matrix-forming polymer, to better understand the rate of drug release from matrix tablets in vitro and to develop hydrophilic controlled-release formulations.     

HPMC-Matrices for Controlled Drug Delivery: A New Model Combining Diffusion,Swelling, and Dissolution Mechanisms and Predicting the Release Kinetics

Purpose. The purpose of this study was to investigate the drug release mechanisms from hydroxypropyl methylcellulose (HPMC)-matrices, and to develop a new model for quantitative predictions of controlled drug delivery. Methods. The dissolved mass of pure HPMC-matrices and the drug release rate from propranolol HCl-loaded HPMC-matrices were determined experimentally. Based on Fick's second law of diffusion for cylinders, the transport of water and drug were modeled considering (i) both radial and axial diffusion, (ii) concentration-dependent drug diffusivities, (iii) matrix swelling and (iv) HPMC dissolution. Results. Good agreement between theory and experiment (dissolved mass and drug release studies) was obtained, proving the validity of the presented model. The water and drug diffusivities are strongly dependent on the matrix swelling ratio. Diffusion, swelling and dissolution are the governing mechanisms involved in the overall drug release process. Conclusions. The practical benefit of the presented model is to identify the required shape and dimensions of drug-loaded HPMC-matrices in order to achieve desired release profiles, thus facilitating the development of new controlled drug delivery products. This will be demonstrated in a future study.     

二甲双胍亚硝胺杂质研究及亲水凝胶骨架材料的筛选

目的 探讨不同亲水凝胶骨架材料与盐酸二甲双胍(metformin hydrochloride,MET)降解生成N-二甲基亚硝胺(N-dimethylnitrosamine,NDMA)之间的相关性,筛选合适的骨架材料用于制备MET缓释片。方法 以高效液相色谱-三重四极杆串联质谱为NDMA监测手段,通过原辅料相容性考察确定产生NDMA风险较低的骨架材料,而后考察溶胀性能,确定溶胀作用与参比制剂相似的骨架材料,将筛选出的骨架材料制备缓释片后考察其体外溶出和剂量倾泻的行为。结果 原辅料相容性考察发现羟丙甲纤维素(hypromellose,HPMC)是引起MET降解产生NDMA的主要原因,并筛选出溶胀作用与HPMC相似的卡波姆,以其为骨架材料制备缓释片可获得与参比制剂相似的溶出曲线,且剂量倾泻风险较低,产品稳定性良好。结论 卡波姆可作为HPMC的替代材料,用于制备MET缓释片。     

利格列汀双层缓释片的制备及体外释放研究

目的 制备一种新型利格列汀双层缓释片，并考察其体外释放行为。方法 以羟丙基甲基纤维素（hydroxyl propyl methyl cellulose，HPMC）为骨架材料、黄原胶为黏合剂，采用单因素设计筛选处方，进行利格列汀双层缓释片的制备，并绘制处方在pH 6.80介质中的体外溶出曲线；采用常规Ritger-Peppas、Higuchi、一级、零级释放曲线方程进行拟合，分析样品释药原理。结果 经优化后的样品由含药缓释层和含药速释层构成。缓释层由主成分利格列汀3 mg、缓释骨架材料HPMC（型号：K4M及K100M，用量均50 mg）、填充剂微晶纤维素100 mg、凝胶缓释基质黄原胶15 mg、润滑剂硬脂酸镁1 mg组成；速释层由主成分利格列汀2 mg、填充剂微晶纤维素10 mg、崩解剂交联聚乙烯吡咯烷酮15 mg、润滑剂硬脂酸镁1 mg组成。最终结果与零级释放方程匹配度最高，极具相关性，拟合结果r²无限接近于1。结论 成功制得利格列汀双层缓释片，并实现零级释放。     

The lack of effect of smoking on the pharmacokinetics and pharmacodynamics of adinazolam and N-demethyladinazolam

The pharmacokinetics and pharmacodynamics of adinazolam and N-demethyladinazolam (NDMAD) were evaluated in twelve healthy non-smokers (NS) and twelve smokers (S, ? 20 cigarettes/day) following a single 60 mg dose of adinazolam mesylate sustained-release tablets in an open-label, parallel-group design. Venous blood samples were collected for up to 36 h following drug administration and assayed for adinazolam and NDMAD by HPLC. Urine samples were also collected and assayed for NDMAD by HPLC. Psychomotor performance was measured using the Neurobehavioral Evaluation System. No significant differences were observed in adinazolam oral clearance (51.8±25.8 versus 48.2±14.01 h^?1) or peak adinazolam plasma concentrations (C_max) (93.3±31.8 versus 90.4±18.0 ng ml^?1) between groups. NDMAD AUC (2541.457 versus 2798±447 ng h ml^?1) and C_max (173±30.3 versus 175±26.9 ng ml^?1) did not differ significantly between groups. NDMAD renal clearance was significantly lower in smokers than non-smokers (8.7±0.7 versus 10.7±2.71 h^?1; p<0.05), but the clinical significance of this observation is unclear. Marginally significant differences were seen between groups in the symbol-digit substitution and digit span (forward) tasks. The results suggest that smoking has little effect on adinazolam and NDMAD pharmacokinetics or psychomotor effects but that smoking may slightly decrease renal clearance of NDMAD.     

Effect of food on the bioavailability of adinazolam from a sustained release formulation: effect of meal timing and lack of dose dumping

Food effects on adinazolam absorption from sustained release (SR) adinazolam mesylate tablets were assessed in 28 healthy male volunteers. Subjects received 15 mg SR tablets, 15 mg immediate release tablets, 15 mg oral solution, administered after an overnight fast, and 15 mg SR tablets after a high fat breakfast. Treatments were administered in a crossover design. Plasma adinazolam and N-desmethyladinazolam (NDMAD) concentrations were determined by HPLC. Adinazolam and NDMAD AUC values were unaffected by food. Cmax for SR tablets was increased 33 per cent and 18 per cent for adinazolam and NDMAD, respectively, when administered postprandially. Tmax occurred later in the fed state; no dose dumping was observed. Meal timing effects on adinazolam absorption from SR tablets were assessed in 24 healthy subjects, who received 30 mg SR tablets 1 h before, 0.5 h after, 2 h after a high fat meal, and in the fasted state. Postprandial administration had no effect on AUC, but resulted later and higher adinazolam and NDMAD Cmax. Differences in these values were less than 11 per cent. Administration of SR tablets before meals yielded Cmax and Tmax values which were similar to the fasted state. Results suggest that meal timing does not substantially affect adinazolam absorption from the SR tablet.     

In vitro characterization and release study of Ambroxol hydrochloride matrix tablets prepared by direct compression

A series of either hydrophilic or hydrophobic polymers were used to prepare controlled release Ambroxol hydrochloride (AMX) matrix tablets by direct compression. Both the compatibility and flow properties of AMX/polymer mixtures were investigated. The effect of the amount and type of polymer on the physical properties and in vitro drug release was studied and compared to commercially available Ambroxol^® SR capsules. A kinetic study of the release profile of AMX from the prepared matrix tablets was performed. All excipients used in the study were compatible with the model drug. AMX/drug mixtures containing sodium alginate (NA) and hydroxypropylmethyl cellulose (HPMC) showed better flow properties than other polymers used in the study. The in vitro drug release studies showed that matrix tablets formulae containing 10% HPMC (S7) or a combination of 30% NA and 5% HPMC (Ah) exhibited a higher ability to control the release of AMX. The kinetic study revealed that a diffusion controlled mechanism prevailed except when carbopol was used. Formula Ah followed a non-fickian diffusion mechanism similar to Ambroxol^® SR capsules. Both formulae S7 and Ah could be considered as potential candidates for formulation of AMX controlled release matrix tablets.     

Characterization of 5-Fluorouracil Release from Hydroxypropylmethylcellulose Compression-Coated Tablets

Hydrogel compression-coated tablets are able to release the core drug after a period of lag time and have potential for colon-specific drug delivery based on gastrointestinal transit time concept. This study investigated the factors influencing in vitro release characteristics of a model drug 5-fluorouracil from hydroxypropylmethycellulose (HPMC) compression-coated tablets. The core tablet, prepared by a wet granulation compression method, was designed to disintegrate and dissolute quickly. To prepare the compression-coated tablets, 50% of the HPMC/lactose coat powder was precompressed first, followed by centering the core tablet and compressing with the other 50% of the coat powder. Release characteristics were evaluated in distilled water by using a Chinese Pharmacopoeia rotatable basket method. Effect of HPMC viscosity, lactose content in outer shell, and overall coating weight of outer shell on release lag time (T_lag), and zero-order release rate (k) were studied. Release of drug from compression-coated tablets began after a time delay as a result of hydrogel swelling/retarding effect, followed by zero-order release for most of the formulations studied. HPMC of higher viscosity (K4M and K15M) provided better protection of the drug-containing core, showing increased release lag time and slower release rate. Incorporating lactose in outer shell led to decrease of T_lag and increase of k. T_lag and k are exponentially and linearly correlated to lactose content, expressed as weight percentage of the outer shell. Larger coating weight (W) of outer shell produced larger coating thickness (D) around core tablet, which resulted in increase in T_lag and decrease in k. There was good fitting of a linear model for each of the four variables W, D, T_lag, and k. Hardness of the compression-coated tablets and pHs of the release media had little effect on drug release profile. It is concluded that the release lag time and release rate are able to be tailored through adjusting the formulation variables to achieve colon-specific drug delivery of 5-fluorouracil.     

Formulation and optimization of a sustained-release tablet of ketorolac tromethamine

The objective of our study was to formulate a sustained-release tablet of Ketorolac tromethamine, which is a nonsteroidal anti-inflammatory agent. A 2 3 full factorial design (8 runs) was selected. The variables studied were the amount of drug (30 and 40 mg), ratio of hydroxypropyl methylcellulose (HPMC)/sodium carboxymethylcellulose (NaCMC) (240/40 and 140/140 mg), and amount of ethylcellulose (140 and 180 mg). Swelling-controlled matrix tablets were manufactured by direct compression of formulation ingredients using a Stokes single punch tablet press. Dissolution tests were performed using USP apparatus 3 (Bio-Dis II), at various pHs to mimic the conditions that exist in the gastrointestinal tract. Responses studied included time for 50% of the drug to dissolve ( T 50 ), diffusional exponent ( n ) that characterizes the release mechanism, and percent friability of the tablets. Analysis of variance indicated that the release rate ( T 50 ) was affected by the HPMC/NaCMC ratio, amount of drug, and two-way and three-way interactions; whereas the amount of drug, HPMC/NaCMC ratio, ethylcellulose, and the interaction between drug and HPMC/NaCMC and HPMC/NaCMC and ethylcellulose and also three-way interactions were significantly affecting the diffusional exponent ( n ). The release mechanism was found to be super-case II transport. The friability of the tablets was significantly affected by all three factors: amount of drug, HPMC/NaCMC ratio, and amount of ethylcellulose. The formulation giving the best release characteristics was identified.     

Formulation and Optimization of a Sustained-Release Tablet of Ketorolac Tromethamine

The objective of our study was to formulate a sustained-release tablet of Ketorolac tromethamine, which is a nonsteroidal anti-inflammatory agent. A 2 3 full factorial design (8 runs) was selected. The variables studied were the amount of drug (30 and 40 mg), ratio of hydroxypropyl methylcellulose (HPMC)/sodium carboxymethylcellulose (NaCMC) (240/40 and 140/140 mg), and amount of ethylcellulose (140 and 180 mg). Swelling-controlled matrix tablets were manufactured by direct compression of formulation ingredients using a Stokes single punch tablet press. Dissolution tests were performed using USP apparatus 3 (Bio-Dis II), at various pHs to mimic the conditions that exist in the gastrointestinal tract. Responses studied included time for 50% of the drug to dissolve (T 50), diffusional exponent (n) that characterizes the release mechanism, and percent friability of the tablets. Analysis of variance indicated that the release rate (T 50) was affected by the HPMC/NaCMC ratio, amount of drug, and two-way and three-way interactions; whereas the amount of drug, HPMC/NaCMC ratio, ethylcellulose, and the interaction between drug and HPMC/NaCMC and HPMC/NaCMC and ethylcellulose and also three-way interactions were significantly affecting the diffusional exponent (n) . The release mechanism was found to be super-case II transport. The friability of the tablets was significantly affected by all three factors: amount of drug, HPMC/NaCMC ratio, and amount of ethylcellulose. The formulation giving the best release characteristics was identified.