Influence of ethanol on swelling and release behaviors of Carbopol®-based tablets

The aim of this work was to investigate the effect of ethanol on the in vitro swelling and release behaviors of Carbopol^®-based tablets. The swelling behavior of drug-free compacts and the release of model drugs (metformin HCl, caffeine and theophylline) from matrix tablets were evaluated in acidic and buffered media with 0, 20 and 40% (v/v) ethanol. Release data were analyzed by fitting to Higuchi and Peppas models and calculation of similarity factor (f₂). ANOVA tests were performed to determine significant factors on swelling and release. It was found that ethanol affects swelling and erosion of drug-free Carbopol^® compacts, and the effect was highly dependent on medium pH. For matrix tablets, no dose dumping due to ethanol was manifested. The release rate and mechanism, however, were significantly affected by ethanol concentration as indicated by ANOVA applied to the constant, K_H, from Higuchi model and the exponent, n, from Peppas model, respectively. The effect of ethanol on release was further confirmed by similarity factor results, which indicated that ethanol led to different release profiles (f₂ < 50) in seven of eight cases for matrices containing metformin HCl and in three of eight cases for matrices containing caffeine and theophylline.     

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.     

Zero-order release and bioavailability enhancement of poorly water soluble Vinpocetine from self-nanoemulsifying osmotic pump tablet

Abstract

Solid self-nanoemulsifying (S-SNEDDS) asymmetrically coated osmotic tablets of the poorly water-soluble drug Vinpocetine (VNP) were designed. The aim was to control the release of VNP by the osmotic technology taking advantage of the solubility and bioavailability-enhancing capacity of S-SNEDDS. Liquid SNEDDS loaded with 2.5?mg VNP composed of Maisine? 35-1, Transcutol^® HP, and Cremophor^® EL was adsorbed on the solid carrier Aeroperl^®. S-SNEDDS was mixed with the osmotic tablet excipients (sodium chloride, Avicel^®, HPMC-K4M, PVP-K30, and Lubripharm^®), then directly compressed to form the core tablet. The tablets were dip coated and mechanically drilled. A 3²*2¹ full factorial design was adopted. The independent variables were: type of coating material (X₁), concentration of coating solution (X₂), and number of drills (X₃). The dependent variables included % release at 2?h (Y₁), at 4?h (Y₂), and at 8?h (Y₃). The in vivo performance of the optimum formula was assessed in rabbits. Zero-order VNP release was obtained by the single drilled 1.5% Opadry^® CA coated osmotic tablets and twofold increase in VNP bioavailability was achieved. The combination of SNEDDS and osmotic pump tablet system was successful in enhancing the solubility and absorption of VNP as well as controlling its release.     

A novel coating concept for ileo-colonic drug targeting: Proof of concept in humans using scintigraphy

The in vivo proof of concept of a novel double-coating system, based on enteric polymers, which accelerated drug release in the ileo-colonic region, was investigated in humans. Prednisolone tablets were coated with a double-coating formulation by applying an inner layer composed of EUDRAGIT® S neutralised to pH 8.0 and a buffer salt (10% KH₂PO₄), which was overcoated with layer of standard EUDRAGIT® S organic solution. For comparison, a single coating system was produced by applying the same amount of EUDRAGIT® S organic solution on the tablet cores. Dissolution tests on the tablets were carried out using USP II apparatus in 0.1 N HCl for 2 h and subsequently in pH 7.4 Krebs bicarbonate buffer. For comparison, tablets were also tested under the USP method established for modified release mesalamine formulations. Ten fasted volunteers received the double-coated and single-coated tablets in a two-way crossover study. The formulations were radiolabelled and followed by gamma scintigraphy; the disintegration times and positions were recorded. There was no drug release from the single-coated or double-coated tablets in 0.1 N HCl for 2 h. The single-coated tablets showed slow release in subsequent Krebs bicarbonate buffer with a lag time of 120 min, while in contrast drug release from the double-coated tablets was initiated at 60 min. In contrast, using the USP dissolution method, normally employed for modified release mesalamine products, no discrimination was attained. The in vivo disintegration of the single-coated EUDRAGIT® S tablets in the large intestine was erratic. Furthermore, in 2 volunteers, the single-coated tablet was voided intact. Double-coated tablets disintegrated in a more consistent way, mainly in the ileo-caecal junction or terminal ileum. The accelerated in vivo disintegration of the double-coating EUDRAGIT® S system can overcome the limitations of conventional enteric coatings targeting the colon and avoid the pass-through of intact tablets. Moreover, Krebs bicarbonate buffer has the ability to discriminate between formulations designed to target the ileo-colonic region.     

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.     

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.     

Theophylline colon specific tablets for chronotherapeutic treatment of nocturnal asthma

The ultimate goal is to design a new chronotherapeutic system for theophylline (TPH) with high potential benefits in treating nocturnal asthma. TPH core tablets were prepared by wet granulation using a developed formula. Compression coating over core tablets containing 200?mg TPH was done using granulated chitosan with 10% PVP K30. Different formulae F1, F2 and F3 were prepared using coat weights 260, 300 and 360?mg, respectively. The in vitro release characteristics in both variant pH media mimicking the gastrointestinal media and in media containing rat cecal content were monitored. The in vivo performance of the optimum formula was compared with Avolen^® SR in Beagle dogs. F3 with high coat thickness exhibited a minimal release after 5-h release study. Both F2 and F3 showed more than 50% drug release after 4?h in the rat cecal medium. This reflects the colon selectivity of the system. The C_max values were found to be 5.49?±?0.46 and 5.12?±?0.85?μg/mL for F3 and Avolen^® SR, respectively, F3 showed higher mean plasma concentration than Avolen^® SR from the beginning and continued till 7?h post administration indicating high potential as chronotherapeutic treatment of nocturnal asthma.     

无时滞非达霉素肠溶片的制备及溶出评价

目的: 制备无时滞非达霉素肠溶片,考察其溶出特性。方法: 采用湿法制粒工艺,通过正交实验进行片芯优化,以甲基丙烯酸与丙烯酸乙酯共聚物为肠溶包衣材料,制备非达霉素肠溶片,以体外释放度为指标,考察其溶出行为。结果: 片芯中羟丙甲纤维素和交联羧甲基纤维素钠的用量分别为1.2%和4.5%,微晶纤维素和淀粉的比例为3:1,肠溶层共聚物的比例为50%时,制备的非达霉素肠溶片在pH1.0盐酸中2h释放度小于10%,在pH4.5醋酸盐缓冲液中可以崩解释放,在pH6.8磷酸盐缓冲液中快速释放,10min释放度大于60%。结论: 制备的非达霉素肠溶片与普通肠溶片相比无时滞效应,有望进行工业化生产。     

The Effect of Formulation Composition and Dissolution Parameters on the Gel Strength of Controlled Release Hydrogel Tablets

The impact of hydrogel polymers and dissolution media on tablet gel strength, Γ, of controlled release (CR) hydrogel tablets was investigated. CR tablets containing either hydroxypropyl methylcellulose (HPMC), hydroxypropyl cellulose (HPC), or carbomer were formulated with theophylline and Fast Flo® lactose, to produce tablets with a polymer content of 8, 15, and 30% w/w. Γ was measured using a previously reported method. The drug dissolution profiles were similar, irrespective of polymer type or dissolution media (DI water, 0.1 N HCl, and pH 6.8 phosphate buffer), at the same % w/w level of polymer. Γ, however, showed large and significant differences (p≤0.05) between tablets containing different polymers and between different dissolution media. Γ values were HPMC K100MP > HPC HXF > carbomer 971P (same % w/w) with absolute Γ values at 30% w/w in DI water of 6600, 4600, and 1600 ergs/cm³, respectively. Γ for HPMC based tablets was independent of changes in dissolution media, while the Γ values for HPC tablets were 18% lower in acid and buffer than in DI water. Of the polymers tested, carbomer based tablets had the lowest Γ values in all dissolution media and an unexpected 58% lower Γ in buffer compared with DI water or acid. Γ provides a quantitative measure of the effect of formulation and dissolution parameter changes on tablet gel layer strength, under in vitro stress conditions that may parallel in vivo tablet performance, but which cannot be deduced from a comparison of dissolution profiles or polymer viscosity.     

Novel time and site specific “tablets in capsule” system for nocturnal asthma treatment

The objective of present work was to develop a “tablets in capsule” system for facilitating both immediate and pulsatile drug deliveries of theophylline to mimic the circadian rhythm of nocturnal asthma. The system comprised of capsule filled with two tablets, first pulse and second pulse tablet prepared by wet granulation method. First pulse tablet was not coated and was responsible for providing loading dose whereas; second pulse tablet was coated with Eudragit L100 and Eudragit S100 to release drug in colon after specific lag time. Two independent variables, amount of polymers and coating thickness, were optimized by 3² full factorial design. The optimum formulation consisted of Eudragit L100: Eudragit S100 in 1:1.5 ratio and coating thickness of 20 % (w/w). In vitro drug release of “tablets in capsule” system in three different media (pH 1.2, pH 6.8, and pH 7.4) revealed immediate and pulsatile release patterns.     

Colon-specific drug delivery for mebeverine hydrochloride

Mebeverine Hydrochloride (MB-HCl), an effective spasmolytic drug, was formulated as CODES?. A colon-specific drug delivery technology CODES? was designed to avoid the inherent problems associated with pH- or time-dependent systems. To achieve more protection and control of drug release, MB-HCl was prepared as microspheres and compressed as core tablets of CODES? (modified CODES?). The core tablets contained the drug either in free form [Formula 1 (F₁)], or as microspheres with 2 different polymer:drug:lactulose ratios (1:1:0.5 [Formula 2 (F₂)] and 2:1:0.5 [Formula 3 (F₃)]. The release profiles of the coated CODES? systems were compared with uncoated compressed tablets. The uncoated tablet showed a drug release of 94% after 1 h in simulated gastric condition (pH = 1.2). The release characteristics of the coated systems revealed that the enteric coating (Eudragit®L₁₀₀) prevented any drug release in simulated gastric or duodenal conditions in the first 3 h (pH 1.2–6.1), after which drug was slightly liberated in simulated intestinal fluid (pH 7.4) {Phase 1 (P1)}. After 4 h the pH was adjusted to 7 and β-glucose-oxidase was added, which is an enzyme produced by enterobacteria present in the colon. The acid-soluble coat (Eudragit®E₁₀₀) dissolved and the drug release suddenly increased to reach 95, 72 and 60.4% for F₁–F₃, respectively. IR spectrum study showed a covalent bond between the drug and the polymer in the formulae F₂ and F₃ resulting in the sustained drug release from the microspheres with a significant difference (p>0.05) to F₁. The findings were confirmed by in vivo investigation using X-ray images for Guinea pigs ingested tablets containing barium sulphate (F₄), where the tablet began to disintegrate after 10 h of tablet intake. The results of the study indicated that MB-HCl CODES? colon-specific drug delivery can act as a successful trigger for drug targeting in the colon. Furthermore, a sustained release of the drug can be achieved from modified CODES containing the drug in the form of microspheres.     

Formulation of 3D Printed Tablet for Rapid Drug Release by Fused Deposition Modeling: Screening Polymers for Drug Release,Drug-Polymer Miscibility and Printability

The primary aim of this study was to identify pharmaceutically acceptable amorphous polymers for producing 3D printed tablets of a model drug, haloperidol, for rapid release by fused deposition modeling. Filaments for 3D printing were prepared by hot melt extrusion at 150°C with 10% and 20% w/w of haloperidol using Kollidon^® VA64, Kollicoat^® IR, Affinsiol^?15 cP, and HPMCAS either individually or as binary blends (Kollidon^® VA64 + Affinisol^? 15 cP, 1:1; Kollidon^® VA64 + HPMCAS, 1:1). Dissolution of crushed extrudates was studied at pH 2 and 6.8, and formulations demonstrating rapid dissolution rates were then analyzed for drug-polymer, polymer-polymer and drug-polymer-polymer miscibility by film casting. Polymer-polymer (1:1) and drug-polymer-polymer (1:5:5 and 2:5:5) mixtures were found to be miscible. Tablets with 100% and 60% infill were printed using MakerBot printer at 210°C, and dissolution tests of tablets were conducted at pH 2 and 6.8. Extruded filaments of Kollidon^® VA64-Affinisol^? 15 cP mixtures were flexible and had optimum mechanical strength for 3D printing. Tablets containing 10% drug with 60% and 100% infill showed complete drug release at pH 2 in 45 and 120 min, respectively. Relatively high dissolution rates were also observed at pH 6.8. The 1:1-mixture of Kollidon^® VA64 and Affinisol^?15 cP was thus identified as a suitable polymer system for 3D printing and rapid drug release.     

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.     

Calendar

The objective of the present study was to develop a colon targeted system of meloxicam for potential application in the prophylaxis of colorectal cancer. Efficacy of selective cyclooxygenase–2 inhibitors has been proven in colorectal cancer. Meloxicam is a selective cyclooxygenase–2 inhibitor with pH-dependent solubility. To achieve pH-independent drug release of meloxicam, pH modifying agents (buffering agents) were used. Meloxicam tablets containing polyethylene oxide were dually coated with ethyl cellulose containing hydrophilic material, polyethylene glycol as an inner coating layer and methyl acrylate, methyl methacrylate, and methacrylic acid copolymer (Eudragit^® FS 30D) as outer coating layer for colon targeting. Optimized tablet formulations demonstrated good potential to deliver the drug to the colon by successfully exhibiting a lag time of 5?h during in vitro drug release study. An in vivo evaluation study conducted to ascertain pharmacokinetic parameters in rabbits revealed that the onset of drug absorption from the coated tablets (T_{lag time}?=?4.67?±?0.58?h) was significantly delayed compared to that from the uncoated tablets. The AUC_0→t and AUC_0→∞ for coated tablets were lower than of uncoated tablets, although the difference was not significant (p?>?0.01). The roentgenography study revealed that the tablet remained intact, until it reached the colon (5?h), which demonstrates that the system can efficiently deliver the drug to the colon. This study demonstrated that a meloxicam-loaded colon targeted system exhibited promising targeting and hence may be used for prophylaxis of colorectal cancer.     

Development and bioequivalence study of potassium chloride extended release tablets

The purposes of this study are to prepare the generic extended release tablet of potassium chloride (PC) 600 mg and to compare the absorption of potassium ion from the experimental tablets to that of Kaleorid® LP 600 mg (Leo Pharmaceutical Products, Denmark). Carnauba wax was used as retardant in the matrix core tablets. The core tablets were coated with blends of ethyl cellulose (EC) and hydroxypropyl methyl cellulose (HPMC) to modulate the drug release. Results of a selective two-level, three-factor experiment design revealed that a blend of 41.75% of EC and 58.25% of HPMC at 4.5% weight gained could produce the coated tablets having dissolution profiles similar to those of Kaleorid®. A two-treatment, two-period, two-sequence crossover bioequivalence study was carried out on 24 healthy volunteers to compare the absorption of potassium ion from experimental tablets to that from Kaleorid®. The potassium ion in the urine was measured by a selective electrode of the ADVIA 1650 system (Bayer) and used to calculate cumulative urinary excretion and urinary excretion rate. Results of 90 percent confidence interval analysis showed that the limits for natural log-transformed cumulative urinary potassium excretion (Ln Ae_0-24) of test product were in the range of 3.73–3.79 mEq, corresponding to 99.08%–100.92% of Kaleorid^®, respectively, and the limits for natural log-transformed maximal potassium excretion rate (R_max) of test product were in the range of 1.72–1.82 mEq/h, corresponding to 97.34%–102.66% of reference product, respectively. Both of them fell within the bioequivalence interval (80%–125%) of reference product, proving that experimental product is bioequivalent to Kaleorid^®.     

Establishing postprandial bio-equivalency and IVIVC for generic metformin sustained release small sized tablets

The objective of current study was to develop metformin hydrochloride modified release small sized tablets, and to evaluate its bioequivalence when compared with the reference product (Glucophage^® SR). The physicochemical properties of the formulated and reference tablets were determined and compared. The in vitro dissolution profiles of formulated tablets were obtained using bio-relevant media and IVIVC was established. Bioequivalence investigation was carried out in 32 healthy male volunteers who received a single dose 1,000 mg of both test and reference products in a randomized two-way crossover design in postprandial conditions. After dosing, serial blood samples were collected for a period of 48 h. Metformin concentration was assayed by using a validated LC–MS/MS method. The log-transformed C_max and AUC were statistically compared by analysis of variance, and the 90 % confidence intervals (CI) of the ratio of the log-transformed C_max and AUC between the most promising developed formulation and the reference product were determined. It was deduced that the dissolution rate profile of the formulated modified release small sized tablets was similar to the reference product employed in the study. Their similarity and difference factors were found to be well within the established limits. In the bioequivalence study, the difference in C_max, AUC_last and AUC_inf between the test and reference product was not statistically significant, with the 90 % CI of 100.73–116.20, 86.16–97.37 and 87.12–96.99 %, respectively. The results suggested that the metformin small tablets formulated with reduced quantity of controlled release polymer were found to be bioequivalent in the postprandial state. For these small tablets, pH 5.5 acetate buffer as a bio-relevant dissolution media for the development of IVIVC.     

Controlled release reservoir mini tablets approach for controlling the drug release of Galantamine Hydrobromide

The objective of this study is to explore and investigate the reservoir mini tablets approach to control the release of Galantamine Hydrobromide in comparison to desired release profile to the Innovator formulation Razadyne^® ER capsules as disclosed in US Patent 7,160,559 which is granted to Janseen Pharmaceutica NV. The core mini tablets were prepared using the direct compression and wet granulation methods. These core mini tablets were further coated with Galantamine Hydrobromide in two different portions; 70% as controlled release and 30% as immediate release and then filled in empty hard gelatin capsule shells. The dissolution profiles of each formulation were compared to those of Razadyne^® ER capsules and the mean dissolution time (MDT), dissolution efficiency (DE%) and dissolution similarity (f2 factor) were calculated. It was observed that core formulation plays an important role in controlling the drug release as well as maintaining pH independent drug release profile. The release mechanism of GAH from reservoir mini tablet formulation follows Higuchi and first order. These results imply that controlled release reservoir mini tablets which further filled into empty hard gelatin capsule shells can be a suitable method to formulate controlled release Galantamine hydrobromide.     

Preparation of Coated Valproic Acid and Sodium Valproate Sustained-release Matrix Tablets

The aim of this research was to investigate the technique for preparation of coated valproic acid and sodium valproate sustained-release matrix tablets. Different diluents were tested and selected as the effective absorbent for oily valproic acid. Effect of the amount of absorbent and hydroxypropylmethylcellulose on drug release from valproic acid-sodium valproate matrix tablets prepared with wet granulation technique was evaluated in pH change system. Colloidal silicon dioxide effectively adsorbed liquid valproic acid during wet granulation and granule preparation. The amounts of colloidal silicon dioxide and hydroxypropylmethylcellulose employed in tablet formulations affected drug release from the tablets. The drug release was prominently sustained for over 12 h using hydroxypropylmethylcellulose-based hydrophilic matrix system. The mechanism of drug release through the matrix polymer was a diffusion control. The drug release profile of the developed matrix tablet was similar to Depakine Chrono^®, providing the values of similarity factor (f2) and difference factor (f1) of 85.56 and 2.37, respectively. Eudragit^® L 30 D-55 was used as effective subcoating material for core matrix tablets before over coating with hydroxypropylmethylcellulose film with organic base solvent. Drug release profile of coated matrix tablet was almost similar to that of Depakine Chrono^®.     

The Influence of Plasticizer on Heat-Humidity Curing of Cellulose Acetate Phthalate Coated Beads

The objectives of the present study are to investigate the effect of plasticizer type and level on the curing of cellulose acetate phthalate (CAP) coated beads with and without the presence of humidity. Theophylline beads were coated in a fluidized-bed with CAP dispersion (Aquacoat® CPD) plasticized by a water-insoluble plasticizer, diethyl phthalate (DEP), or a water-soluble plasticizer, triethyl citrate (TEC), at various levels. The coated beads were cured at a heat-only condition (50°C for 24 hr) and a heat-humidity condition (50°C/75%RH for 24 hr). Rapid drug release in the acidic media was found for both heat-only and heat-humidity cured beads when plasticizer was not used in the coating dispersion, indicating that the heat-humidity curing is ineffective without the presence of plasticizers. When plasticizer was incorporated in the coating formulations, heat-humidity curing effectively improved the acid resistance of the coated films at all plasticizer levels investigated. The minimum plasticizer level required to obtain enteric release profiles for heat-humidity cured beads coated at an outlet coating temperature of 46°C was 15%. This limit was further decreased when the beads were coated at a lower temperature due to a less plasticizer loss at the lower coating temperature. Between the two plasticizers, less TEC was lost during the coating process, and TEC was more effective compared to DEP with regards to heat-humidity curing at the 10% plasticizer level. The enteric release profiles were reproducible following a 7-day drying period at 40°C for all heat-humidity cured beads that had initially passed the enteric release dissolution test. The rapid leaching of TEC and DEP into the acidic media during the dissolution test did not impair the integrity of the heat-humidity cured films.     

Formulation and evaluation of omeprazole tablets for duodenal ulcer

Omeprazole pellets containing mucoadhesive tablets were developed by direct punch method. Three mucoadhesive polymers namely hydroxypropylemethylcellulose K4M, sodium carboxy methylcellulose, carbopol-934P and ethyl cellulose were used for preparation of tablets which intended for prolong action may be due to the attachment with intestinal mucosa for relief from active duodenal ulcer. Mucoadhesive tablets were coated with respective polymer and coated with Eudragit L100 to fabricate enteric coated tablets. The prepared tablets were evaluated for different physical parameters and dissolution study were performed in three dissolution mediums like 0.1N hydrochloric acid for 2h, pH 6.5 and pH 7.8 phosphate buffer solution for 12hr. Sodium carboxymethylcellulose showed above 95% release within 10 h where as carbopol-934P showed slow release about 88% to 92% over a period of 12 h. having excellent mucoadhesive strength but ethyl cellulose containing tablets showed less than 65% release. The release mechanism of all formulation was diffusion controlled confirmed from Higuchi's plot. Thus, the present study concluded that, carbopol-934P containing mucoadhesive tablets of omeprazole pellets can be used for local action in the ulcer disease as well as for oral controlled release drug delivery.