Enzymatic degradation of cross-linked high amylose starch tablets and its effect on in vitro release of sodium diclofenac.

The influence of several physicochemical parameters on enzymatic hydrolysis and the in vitro release of sodium diclofenac (SDic) from cross-linked high amylose starch (Contramid) (CLA) tablets was evaluated. These parameters included pH, ionic strength of the medium, enzyme concentration, compression force and incorporation of gel-forming polymers such as hydroxypropyl methylcellulose (HPMC), poly(ethylene oxide) (PEO) and poly(vinyl alcohol) into the tablet. Pure CLA tablets were incubated in phosphate buffer (pH 6.8) containing alpha-amylase and the extent of enzymatic erosion was determined by gravimetry. Release of SDic from CLA tablets, in the presence of alpha-amylase, was measured using a USP type III dissolution apparatus. For low alpha-amylase concentrations (<2250 IU/l), the drug release was mainly diffusion-controlled. At higher alpha-amylase concentrations (>4500 IU/l) both diffusion and erosion contributed to the release of SDic. The hydrolysis kinetics of CLA tablets by alpha-amylase was biphasic. During the first phase (2-4 h), the hydrolysis rate was hyperbolically related to the alpha-amylase concentration but was practically alpha-amylase concentration-independent during the second phase. Enzymatic erosion and drug release kinetics appear to be relatively independent of ionic strength, pre-incubation time in simulated gastric fluid, and compression force of the tablets (6-34 kN). Incorporation of HPMC or PEO into the tablet resulted in a significant decrease of both tablet erosion and drug release rates.     

Development of pectin matrix tablets for colonic delivery of model drug ropivacaine.

The objective of this work was to develop pectin-based matrix tablets for colonic delivery of the model drug ropivacaine, with the future perspective of radiolabelling the system by neutron activation technique for a gamma-scintigraphic study. The aim was to investigate some formulation factors that could reduce the release of the drug in the simulated gastric and intestinal fluids, increase the release in the simulated cecal fluid (with pectinolytic enzymes) and improve the poor compactibility of pectins. For dissolution studies, the flow-through apparatus with sequential dissolution liquids simulating the mouth-to-colon conditions was used. The effect of two pectin types, the incorporation of ethylcellulose as a dry matrix-additive and water or ethanol as granulation liquids were investigated in a study designed as a D-optimal mixture. Amidated pectin (Am.P) produced harder tablets than the calcium salt of pectin (Ca.P) and was more susceptible to enzymatic degradation. Addition of ethylcellulose increased the tablet strength and the dissolution rate. Furthermore, directly compressed Am.P tablets were produced by addition of coarse or micronised qualities of ethylcellulose. The latter improved the crushing strength markedly imposing a marginal release-reducing effect. Coating this formulation with Eudragit((R)) L 100 reduced the release in the simulated upper GI conditions without interference with the subsequent enzymatic activity.     

长春西汀海藻酸钠骨架片体外释药影响因素研究

目的以海藻酸钠为骨架材料 ,制备长春西汀控释骨架片 ,对影响其体外释放的多种因素进行了考察。方法以海藻酸钠为亲水骨架材料 ,粉末直接压片制备长春西汀控释片 ,采用《中华人民共和国药典》2 0 0 0年版二部收载的溶出度测定方法Ⅱ法 (桨法 ) ,测定药物在不同条件下的体外释放度 ,考察海藻酸钠用量及黏度 ,枸橼酸用量 ,释放介质离子强度和pH值对药物体外释放行为的影响。结果与结论海藻酸钠用量及黏度 ,枸橼酸用量 ,释放介质离子强度和pH值均对药物体外释放行为有显著影响。值得注意的是 ,通过调节处方中枸橼酸用量可以使释药行为达零级 ,这为制备长春西汀控释片提供指导 ,有进一步开发的价值。     

The physicodynamic properties of mucoadhesive polymeric films developed as female controlled drug delivery system

Phenoporlamine hydrochloride is a novel compound that is used for the treatment of hypertension. The purpose of this study was to develop a sustained release tablet for phenoporlamine hydrochloride because of its short biological half-life. Three floating matrix formulations of phenoporlamine hydrochloride based on gas forming agent were prepared. Hydroxypropyl methylcellulose K4M and Carbopol 971P NF were used in formulating the hydrogel drug delivery system. Incorporation sodium bicarbonate into matrix resulted in the tablet floating over simulated gastric fluid for more than 6 h. The dissolution profiles of all tablets showed non-Fickian diffusion in simulated gastric fluid. Moreover, release of the drug from these tablets was pH-dependent. In vivo evaluations of these formulations of phenoporlamine hydrochloride were conducted in six healthy male human volunteers to compare the sustained release tablets with immediate release tablets. Data obtained in these studies demonstrated that the floating matrix tablet containing more Carbopol was capable of sustained delivery of the drug for longer periods with increased bioavailability and the relative bioavailability of formulation (containing 25% Carbopol 971P NF, 8.3% HPMC K4M) showed the best bioequivalency to the reference tablet (the relative bioavailability was 1.11 ± 0.19).     

Design and characterization of a surfactant-enriched tablet formulation for oral delivery of a poorly water-soluble immunosuppressive agent.

The feasibility of incorporating significant quantities of the anionic surfactant, sodium lauryl sulfate (SDS), into an immediate release tablet formulation of a poorly water-soluble immunosuppressive agent was investigated. Despite the extremely poor compressibility of SDS and poor chemical stability of the drug, a commercializable, direct-compression tablet formulation with satisfactory mechanical properties and acceptable chemical stability was achieved. Optimal in vitro release of the drug from the tablet formulation was achieved by establishing the minimum molar uptake ratio necessary to achieve complete micellar solubilization of the drug, after which formulation studies were conducted to determine the influence of formulation and process variables on the rate and extent of drug release. A model-independent analysis of dissolution results in a reduced volume (250 ml) of modified simulated gastric fluid demonstrated that the rate and extent of drug release was highly dependent on the mean particle size of the bulk drug, but independent of compression force above that required to achieve a compact of acceptable mechanical strength. Employing the Korsmeyer-Peppas model of Fickian and non-Fickian drug release, it was further shown that release of the drug from the dosage form was governed largely by surface erosion of the surfactant-enriched tablet matrix.     

Effect of formulation variables on in vitro release of a water-soluble drug from chitosan–sodium alginate matrix tablets

The objective of this study is to investigate the feasibility of using chitosan–sodium alginate (CS–SA) based matrix tablets for extended-release of highly water-soluble drugs by changing formulation variables. Using trimetazidine hydrochloride (TH) as a water-soluble model drug, influence of dissolution medium, the amount of CS–SA, the CS:SA ratio, the type of SA, the type and amount of diluents, on in vitro drug release from CS–SA based matrix tablets were studied. Drug release kinetics and release mechanisms were elucidated. In vitro release experiments were conducted in simulated gastric fluid (SGF) followed by simulated intestinal fluid (SIF). Drug release rate decreased with the increase of CS–SA amount. CS:SA ratio had only slight effect on drug release and no influence of SA type on drug release was found. On the other hand, a large amount of water-soluble diluents could modify drug release profiles. It was found that drug release kinetics showed the best fit to Higuchi equation with Fickian diffusion as the main release mechanism. In conclusion, this study demonstrated that it is possible to design extended-release tablets of water-soluble drugs using CS–SA as the matrix by optimizing formulation components, and provide better understanding about drug release from CS–SA matrix tablets.     

pH- and flow-rate-independent release of drug from uncoated slow-release tablets

Slow-release tablets were prepared using a polyvinyl chloride--polyethylene matrix and sodium salicylate as a model drug. The in vitro release of salicylate was described adequately by a previously published equation. The release rate constant was independent of the pH of the dissolution fluid and the flow rate of the fluid past the tablet. Accordingly, the procedures used to test the in vitro drug release from this type of matrix tablet are not as critical as for conventional tablets. It may therefore be postulated that the in vivo performance of the tablet may be less subject to variations in the physiological parameters of the GI tract.     

多层片释药系统的研究进展

与单层缓控释片相比,多层片有其独特的优点,近年来得到了快速发展。根据其不同设计如层数、几何形状、各层位置等的不同,该释药系统可分为控释型、快/慢释药型、延迟缓释或脉冲释药、双峰释药及多相释药等。在多层片的制备中,工艺参数和处方因素如硬度、层与层之间的黏附力、阻滞辅料用量等对片剂的成形和药物的释放速度存在较大的影响,需严格控制。现对多层片的不同释药模式、制备工艺及参数进行综述。     

In Vitro and In Vivo Studies on HPMC-K-100 M Matrices Containing Naproxen Sodium

Controlled release (CR) matrix tablets of naproxen sodium were prepared by wet granulation using hydroxypropyl methyl cellulose (HPMC-K-100 CR) as the hydrophilic rate controlling polymer. The effect of the concentration of the polymer and different fillers on the in vitro drug release rate was studied. The studies indicated that the drug release can be modulated by varying the concentration of the polymer and the fillers. An optimized formulation subjected to accelerated stability studies for 3 months revealed that the developed CR tablets are stable. A complete cross-over bioavailability study of the optimized formulation of the developed CR tablets and marketed immediate release tablets was performed in 6 healthy male volunteers. The extent of absorption of drug from the CR tablets was significantly higher than that for the marketed naproxen sodium tablet due to lower elimination rate and longer half-life.     

In vitro and in vivo studies on HPMC-K-100 M matrices containing naproxen sodium

Controlled release (CR) matrix tablets of naproxen sodium were prepared by wet granulation using hydroxypropyl methyl cellulose (HPMC-K-100 CR) as the hydrophilic rate controlling polymer. The effect of the concentration of the polymer and different fillers on the in vitro drug release rate was studied. The studies indicated that the drug release can be modulated by varying the concentration of the polymer and the fillers. An optimized formulation subjected to accelerated stability studies for 3 months revealed that the developed CR tablets are stable. A complete cross-over bioavailability study of the optimized formulation of the developed CR tablets and marketed immediate release tablets was performed in 6 healthy male volunteers. The extent of absorption of drug from the CR tablets was significantly higher than that for the marketed naproxen sodium tablet due to lower elimination rate and longer half-life.     

Design and evaluation of bilayer floating tablets of captopril

The objective of the present investigation was to develop a bilayer-floating tablet (BFT) for captopril using direct compression technology. HPMC, K-grade and effervescent mixture of citric acid and sodium bicarbonate formed the floating layer. The release layer contained captopril and various polymers such as HPMC-K15M, PVP-K30 and Carbopol 934p, alone or in combination with the drug. The floating behavior and in vitro dissolution studies were carried out in a USP 23 apparatus 2 in simulated gastric fluid (without enzyme, pH 1.2). Final formulation released approximately 95% drug in 24 h in vitro, while the floating lag time was 10 min and the tablet remained floatable throughout all studies. Final formulation followed the Higuchi release model and showed no significant change in physical appearance, drug content, floatability or in vitro dissolution pattern after storage at 45 degrees C/75% RH for three months. Placebo formulation containing barium sulphate in the release layer administered to human volunteers for in vivo X-ray studies showed that BFT had significantly increased the gastric residence time.     

Controlled-Release Tablet Matrices from Carrageenans: Compression and Dissolution Studies

ABSTRACT

This study investigates the potential of two commercial carrageenans, Gelcarin GP-379® (i-carra-geenan) and Viscarin GP-209® (X-carrageenan) to be used for the preparation of controlled-release tablet matrices. Tablets were compressed on an instrumented Stokes single punch machine and compression characteristics of the carrageenans were analyzed. Heckel plots using out-of-die tablet densities were linear with calculated yield pressures of 81.3 MPa and 105.2 MPafor i- and X-carrageenan, respectively. Drug release from tablet formulations that contained equal amounts of the two carrageenans had near zero-order release profiles. There was little or no effect of tablet compression pressure on the drug release profiles from 70 to 175 MPa. As drug loading was increased from 5 to 20%, the diffusional exponent decreased from 1.056 to 0.678. Thirty percent drug loading resulted in breakup of tablets during dissolution and departure from zero-order release. Multiple regression analysis was used to predict the time for 50% release as a function of the concentration of the two carrageenans and a third filler material, microcrystalline cellulose. Predicted values were in good agreement with observed values and R² for the final cubic model was 0.9984.     

A comparative in vitro assessment of the drug release performance of pH-responsive polymers for ileo-colonic delivery

The aim of this study was to investigate the in vitro dissolution characteristics of pH-responsive polymers in a variety of simulated fluids. Prednisolone tablets were fabricated and coated with the following polymer systems: Eudragit S (organic solution), Eudragit S (aqueous dispersion), Eudragit FS (aqueous dispersion) and Eudragit P4135 (organic solution). Dissolution tests were conducted using a pH change method whereby tablets were transferred from acid to buffer. Three different buffer media were investigated: two compendial phosphate buffers (pH range 6.8-7.4) and a physiological buffer solution (Hanks buffer) with very similar ionic composition to intestinal fluid (pH 7.4). There was considerable drug release from tablets coated with Eudragit P4135 in acid, prompting discontinuation of further investigations of this polymer. Eudragit S (organic solution), Eudragit S (aqueous dispersion) and Eudragit FS on the other hand prevented drug release in acid, though subsequent drug release in the buffer media was found to be influenced by the duration of tablet exposure to acid. At pH 7.4 drug release rate from the polymer coated tablets was similar in the two compendial media, however in the physiological buffer, they were found to differ in the following order: Eudragit S (aqueous dispersion)>Eudragit FS>Eudragit S (organic solution). The results indicate that the tablets coated with the newer Eudragit FS polymer would be more appropriate for drug delivery to the ileo-colonic region in comparison to the more established Eudragit S. More importantly, however, dissolution in the physiological buffer was found to be markedly slower for all the coated tablets than in the two compendial buffers, a result akin to reported slower dissolution of enteric coated tablets in vivo. There is therefore the need to adequately simulate the ionic composition of the intestinal fluid in the dissolution media.     

In vitro and in vivo evaluation of a fast-disintegrating lyophilized dry emulsion tablet containing griseofulvin.

Development of a fast-disintegrating lyophilized dry emulsion (LDE) tablet that enhanced the in vitro dissolution and in vivo absorption of griseofulvin (GF) is presented. The LDE tablets were prepared by freeze-drying o/w emulsions of GF, a drug for which bioavailability is known to be enhanced by fat co-administration. Oil-in-water emulsions were prepared using a gelatin solution (2%, w/v) as the water phase and medium chain triglycerides (Miglyol) or sesame oil as the oil phase. In addition, different emulsifiers were evaluated. The influence of formulation parameters on the disintegration and in vitro dissolution of GF from LDE tablets along with other tablet characteristics were investigated. A significant influence of the emulsifier type on the tablet disintegration time was seen (p<0.01). Results obtained from dissolution studies showed that LDE tablets of GF improved the dissolution rate of the drug compared to the plain drug. The extent of absorption of GF from a selected LDE tablet formulation as compared to an immediate release conventional tablet as reference after single oral dose (125mg) administration was determined in four healthy subjects using a randomized crossover design. In this study, the rate of absorption of GF from LDE tablet was faster than that from the reference tablet and had significantly higher (p=0.02) peak plasma concentration (more than three times higher) and shortened time to C(max) by 4h (p=0.014). The extent of absorption expressed by AUC was 85% larger as compared to the commercial tablet. Stability results, after 6 months storage of LDE tablets at 25 degrees C and 60% relative humidity, showed a slight increase in disintegration time and residual moisture content, while results from dissolution studies showed slightly slower initial drug release.     

Swelling and drug release behaviour of xanthan gum matrix tablets

The swelling and drug release behaviour of xanthan gum matrix tablets were studied using three drugs having different properties, i.e., caffeine as a soluble neutral drug, indomethacin as an insoluble acidic drug, and the sodium salt of indomethacin as a soluble acidic drug. Swelling was ascertained by measuring the axial and the radial expansion of matrix tablets following exposure to media of physiological ionic strength. The mean drug dissolution time and swelling rate were calculated from dissolution and swelling experiments, respectively, and were used as responses for comparison under different experimental conditions. The dependence of drug release on the swelling of the polymer matrix and on the type of the drugs added was established. The former is mainly influenced by the ionic strength and buffer concentrations. The latter is affected by the solubility of the drug. The mechanism of matrix swelling follows Case I diffusion, whereas drug release from this polymer matrix conforms to Case II diffusion.     

Relationship between planar and all-surface rate constants for drugs formulated in nondisintegrating cylindrical slow-release tablets

The release of drug through the planar surface of a nondisintegrating tablet with an insoluble matrix has been described mathematically using the Higuchi release rate constant (kH). The release of drug through a similar all-surface tablet has been described by using a cubic equation and the all-surface rate constant (kr). Using sodium salicylate and quinidine sulfate as model drugs, the relationship between kH and kr was verified for cylindrical slow-release tablets. Accordingly, the rate constant obtained from a single exposed planar surface can be used to predict the rate constant (kr) when all surfaces of the tablet are exposed to dissolution fluid.     

Preparation and in vitro evaluation of enteric-coated tablets of rosiglitazone sodium

The aim of this study was to prepare the rosiglitazone sodium enteric-coated tablets and investigate its release rate. The rosiglitazone sodium enteric-coated tablet was prepared by single punch tablet press using substituted hydroxypropyl cellulose and polyvinylpyrrolidone (PVP). The release rate from the enteric-coated tablet of rosiglitazone sodium was evaluated. The release rate study showed that few rosiglitazone sodium was released from enteric coated formulation within 2 h in simulated gastric juice, while it released more than 80% of the labeled amount in 30 min in simulated intestinal juice. The preparing method of rosiglitazone sodium enteric-coated tablets was simple and had a good reproducibility. The release condition and determined methods could be used for the routine determinations of rosiglitazone sodium enteric-coated tablets.     

黄藤素缓释片制备工艺及其体外释放特性的考察

目的:确定黄藤素缓释片的制备工艺,并进行其释放特性的研究。方法:用f2因子法确定对黄藤素缓释片释放度影响较大的几个因素,用正交设计对黄藤素缓释片的处方进行筛选与优化,确定最佳处方,并应用多元线性回归法考察了影响因素与释放度之间的线性相关关系。结果:所制缓释片剂质量稳定,体外释放性能好,持续释药达12h,符合设计要求。结论:该片剂处方设计合理,工艺简单,适于工业化生产。     

The effect of tablet formulation and hardness on in vitro release of cephalexin from Eudragit L100 based extended release tablets

Eighteen batches of cephalexin extended release tablet were prepared by wet granulation method by using Eudragit L100. The effect of the concentration of Eudragit L100, microcrystalline cellulose and tablet hardness on cephalexin release was studied. The formulated tablets were also characterized for physical and chemical parameters. The dissolution results showed that a higher amount of Eudragit in tablet composition and higher tablet hardness resulted in reduced drug release. An increased amount of microcrystalline cellulose in tablet composition resulted in enhanced drug release. Tablet composition of 13.3% w/w Eudragit L100 and 6.6 to 8% w/w microcrystalline cellulose with hardness of 7-11 kg/cm2 gave predicted release for 6 h. The in vitro release was compared with a marketed tablet. Physical and chemical parameters of all formulated tablets were within acceptable limits. The effect of storage on in vitro release and physicochemical parameters of tablets was evaluated and two batches among formulated eighteen batches found to be in acceptable limits.     

In vitro release of valerenic and hydroxyvalerenic acids from valerian tablets

Although most commercial valerian formulations are coated tablets not any comparison study of their drug release profiles has been published so far. The main objective of this work is to establish a drug release test suitable for studying and comparing different valerian tablets. Thus, hydroxyvalerenic and valerenic acid concentrations were assayed by HPLC using a C18 Kromasil (200 x 4.6 mm, 5 microm) column and a mobile phase containing methanol and an orthophosphoric acid solution 0.5% v/v in water at a ratio of 75:25 at a constant flow rate of 1 ml/min. Saturation solubilities for hydroxyvalerenic and valerenic acid at pH 6.8 were 26 +/- 5.1 and 1 +/- 0.6 microg/ml, respectively. Usually for drugs with such low solubility values, their oral absorption and hence bioavailability are limited by their dissolution characteristics. A dissolution test was conducted according to the general method 2 (paddles) of USP 24 using 500 ml buffer medium (pH 6.8) at 50 rpm. Five different formulations were studied and compared: one uncoated tablet formulation and four marketed coated tablets. The uncoated tablet formulation had the fastest release profile, whereas the coated tablets manifested very different release patterns, depending on the type of formulation. Because of these differences in drug release pattern not every tablet formulation may be appropriate for the same clinical indications. Clinical data are required to confirm the correlation between drug release pattern and the therapeutically value of each formulation.