Effect of sodium bicarbonate on the properties of metronidazole floating matrix tablets

The effect of sodium bicarbonate (SB) on the swelling behavior and the sustained release of floating systems was studied with varied proportions of this excipient and metronidazole. Two polymers with different hydration characteristics, Methocel K4M and Carbopol 971P NF, were used to formulate the matrices. Under in vitro dissolution conditions, the addition of SB to metronidazole sustained-release tablets modifies the matrix hydration volume, increasing at the beginning, reaching a maximum, and then declining. Pure Carbopol matrices show a rapid hydration with a limited further effect of the SB and metronidazole loads. Methocel show a significant increase of the apparent hydration volume due to SB addition with no further notable change due to metronidazole load. Increasing the metronidazole load reduces the floating time of Carbopol matrices while no effect on Methocel matrices could be observed within 8 hours dissolution. Matrices show increasing release constant values (k) as the metronidazole load increases. Methocel matrices release the drug 10% to 15% faster than Carbopol matrices. SB increases the cumulative amount of drug released from Methocel but not that releasing from Carbopol. These results are attributed to the intrinsic polymer properties, the barrier effect of CO₂ bubbles, and the matrix volume expansion produced after addition of SB.     

Effect of Added Pharmatose DCL11 on the Sustained-Release of Metronidazole From Methocel K4M and Carbopol 971P NF Floating Matrices

ABSTRACT

In vitro dissolution of metronidazole from sustained release floating tablets was studied with varied proportions of sodium bicarbonate (SB) and Pharmatose DCL 11. Two polymers with different hydration characteristics, Methocel K4M and Carbopol 971P NF, were used to formulate the matrices. The variables studied include the matrices' release profile, hydration volume, and floating behavior. All Methocel matrices floated more than 8 h with SB proportions up to 24%, while Carbopol matrices floated more than 8 h with SB proportions only up to 12%. Matrices' hydration increased with time until reaching a peak and declining thereafter. Methocel matrices showed greater hydration volumes and greater drug dissolution compared to Carbopol matrices. After adding increasing quantities of Pharmatose to matrices containing 12% SB, hydration volume decreased while dissolution increased. These results were attributed to water-filled pores that formed following the Pharmatose dissolution and to reduced polymer proportions. Carbopol matrices showed greater susceptibility to the added Pharmatose, becoming more erodible and releasing higher quantities of metronidazole. The greater Carbopol susceptibility to added Pharmatose was attributed to its faster hydration. Methocel matrices hydrate rapidly only at the surface, delaying hydration and Pharmatose dissolution.     

Effect of added Pharmatose DCL11 on the sustained-release of metronidazole from Methocel K4M and Carbopol 971P NF floating matrices

In vitro dissolution of metronidazole from sustained release floating tablets was studied with varied proportions of sodium bicarbonate (SB) and Pharmatose DCL 11. Two polymers with different hydration characteristics, Methocel K4M and Carbopol 971P NF, were used to formulate the matrices. The variables studied include the matrices' release profile, hydration volume, and floating behavior. All Methocel matrices floated more than 8 h with SB proportions up to 24%, while Carbopol matrices floated more than 8 h with SB proportions only up to 12%. Matrices' hydration increased with time until reaching a peak and declining thereafter. Methocel matrices showed greater hydration volumes and greater drug dissolution compared to Carbopol matrices. After adding increasing quantities of Pharmatose to matrices containing 12% SB, hydration volume decreased while dissolution increased. These results were attributed to water-filled pores that formed following the Pharmatose dissolution and to reduced polymer proportions. Carbopol matrices showed greater susceptibility to the added Pharmatose, becoming more erodible and releasing higher quantities of metronidazole. The greater Carbopol susceptibility to added Pharmatose was attributed to its faster hydration. Methocel matrices hydrate rapidly only at the surface, delaying hydration and Pharmatose dissolution.     

Effect of formulation and process variables on the release behavior of amoxicillin matrix tablets

The sustained release of amoxicillin is desired to be confined to the upper gastrointestinal tract to treat certain kind of infections. In vitro dissolution, at pH 1.2, of amoxicillin sustained release tablets has been studied varying the proportion of Carbopol 971P NF and sodium alginate as well as the ethanol/water proportion in the granulation fluid. M_t, the amount of drug released at time (t) and defined in terms of the total drug released over a long time period (M_inf), was described by M_t/M_inf = ktⁿ. Matrices with increasing proportions of sodium alginate showed increasing values of the exponent indicative of the release mechanism (n) and increasing release constant values (k). This is attributed to a drop in the coherence of the polymeric matrix with increasing alginate proportions that produces an increasing polymer relaxation and erosion. Decreasing Carbopol 971P NF proportions reduce the amount of dissolved polymer during granulation, producing a lesser obstruction of amoxicillin dissolution. Alginate proportions of 80% produce near zero order release profiles. Granules obtained with increasing ethanol proportions showed increasing release constant values and a minor change in the exponent (n) values. This is considered a result of lower polymer dissolution during granulation that allows a lesser matrix coherence and a greater amoxicillin dissolution. Alginate matrices granulated with different ethanol/water proportions showed no significant changes in the amoxicillin release profile. There is a trend toward increasing floating times with increasing Carbopol 971P NF proportions.     

The Influence of Hydro-Alcoholic Media on Hypromellose Matrix Systems

Hydrophilic matrices are widely used for extended release drug delivery, with hypromellose (HPMC) being a popular rate-controlling carrier. The FDA has recently issued an alert regarding the potential negative influence of alcohol on extended release dosage forms.

The aim of this study was to investigate the hydroalcoholic solution effect on hydration, gel formation and drug release from HPMC matrices. None of the investigated matrix formulations (felodipine, gliclazide, and metformin hydrochloride) resulted in dose-dumping when exposed to ethanol solutions.

HPMC compacts made of three different viscosity grades of Methocel showed consistent swelling and gel formation when exposed to hydroalcoholic media.     

The influence of hydro-alcoholic media on hypromellose matrix systems

Hydrophilic matrices are widely used for extended release drug delivery, with hypromellose (HPMC) being a popular rate-controlling carrier. The FDA has recently issued an alert regarding the potential negative influence of alcohol on extended release dosage forms.

The aim of this study was to investigate the hydroalcoholic solution effect on hydration, gel formation and drug release from HPMC matrices. None of the investigated matrix formulations (felodipine, gliclazide, and metformin hydrochloride) resulted in dose-dumping when exposed to ethanol solutions.

HPMC compacts made of three different viscosity grades of Methocel showed consistent swelling and gel formation when exposed to hydroalcoholic media.     

Development of controlled-release buccoadhesive hydrophilic matrices of diltiazem hydrochloride: optimization of bioadhesion,dissolution, and diffusion parameters

Buccoadhesives have long been employed to improve the bioavailability of drugs undergoing significant hepatic first-pass metabolism. Diltiazem hydrochloride (DLZ) is also reported to have low oral bioavailability due to an extensive hepatic first-pass effect. Controlled-release buccoadhesive hydrophilic matrices containing DLZ were prepared using a 3(2) factorial design. Amounts of Carbopol 934P (CP) and Methocel K100LV (HPMC) were taken as the formulation variables (factors) for optimizing bioadhesion, and kinetics of dissolution and diffusion. A mathematical model was generated for each response parameter. Bioadhesive strength tended to vary quite linearly in increasing order with increasing amount of each polymer. The drug release pattern for all the formulation combinations was found to be non-fickian, approaching zero-order kinetics. The values of permeation coefficient tended to vary non-linearly with polymer amount, depicting the plausibility of interaction between the two polymers. Suitable combinations of the two polymers provided adequate bioadhesive strength and a fairly regulated release profile up to 10 hr. The response surfaces and contour plots for each response parameter are presented for further interpretation of the results. The optimum formulations were chosen and their predicted results found to be in close agreement with experimental findings.     

Preparation and in Vitro evaluation of mefenamic Acid Sustained Release Beads

Abstract

Sustained release beads of mefenamic acid were prepared by a capillary method using cellulose acetate phthalate, surfactants (Tween 80 and Span 80), and polymers (K 100 M Methocel and K 100 LV Methocel). These beads were then formulated into capsule dosage form. The beads did not disintegrate in simulated gastric fluid; however, they disintegrated in simulated intestinal fluid. The dissolution profiles of mefenamic acid beads and capsule dosage form were conducted in phosphate buffer (pH 7.2) at 37° C. The beads containing Span 80 and a mixture of K 100 M and A 4 M Methocel resulted in prolonged drug release. The formulations prepared with Tween 80 and K 100 LV Methocel released over 90% of the drug in 2 hours indicating no sustained release properties. The beads in capsule dosage form yielded slower dissolution profiles compared to the beads alone. Aging for six months had no effect on dissolution of mefenamic acid beads. The release of mefenamic acid seems to be combination of diffusion and leaching. The release of mefenamic acid from beads can be modified by varying the polymer composition and their concentration.     

Studies on Drug Release Kinetics from Carbomer Matrices

The objective of this study is to gain a mechanistic understanding of drug release kinetics from directly compressed tablets containing Carbopol 934P and 974P resins. Carbopol resins belong to a family of carbomers which are synthetic, high molecular weight, non-linear polymers of acrylic acid, crosslinked with polyalkenyl polyether. They are currently being used as polymeric matrices for controlling drug release in pharmaceutical tablets. This investigation focuses on the influence of the type of drug and the pH of the dissolution media, along with other factors on the drug release kinetics from carbomer matrices. Directly compressed tablets were prepared using a Stokes single station laboratory press and blends of polymers and lactose with drugs like theophylline, norephedrine HCI, and chlorpheniramine maleate. In vitro. drug release studies from the tablets were performed according to USP method II. Drug release rates were obtained by plotting the fraction released versus time and data fitted to the equation:     

Kinetic Release of Theophylline from Hydrophilic Swellable Matrices

The objective of this research was to evaluate the effect of hydroxypropylmethylcellulose (HPMC; Methocel K4M Premium) level and type of excipient on theophylline release and to attempt to predict the drug release from hydrophilic swellable matrices. Formulations containing theophylline anhydrous (10% w/w), Methocel K4M Premium (10%, 30%, and 40% w/w), different diluents (Lactose Fast Flo, Avicel PH-101, and Emcompress), and magnesium stearate (0.75% w/w) were prepared by direct compression at a target weight of 450 mg ± 5% and target hardness of 7 kp to 10 kp. It was found that, as the percentage of polymer in all formulations increased from 10% to 30% or 40%, the drug release decreased. However, there was no significant difference in drug release between formulations containing 30% polymer and formulations containing 40% polymer. At low levels of polymer, the drug release is controlled by the type of diluent used. Avicel PH-101 formulation gave the highest release, while its corresponding Emcompress formulation gave the lowest release. Formulations containing 30% or 40% polymer gave the same release profiles irrespective of the type of diluent used. In all cases, replacement of a portion of Methocel K4M Premium with any diluent resulted in increase of theophylline release. In addition, this investigation demonstrated that the drug release from hydrophilic swellable matrices can be predicted using only a minimum number of experiments.     

Interpolymer complexation between copovidone and carbopol and its effect on drug release from matrix tablets

The interaction between copovidone and Carbopol 907 is pH dependent. When the pH of an aqueous solution fell below pH 4.5, a water-insoluble complex began to form and precipitate. This complex resulted from a hydrogen-bond-induced interaction between the carboxylic groups in Carbopol 907 and the carbonyl groups of N-vinylpyrrolidone repeat units in copovidone. Consisting of these two polymers at an approximate 1:1 weight ratio, the complex was an amorphous material with a glass transition temperature of 157?°C. The interpolymer complexation in situ was applied to modify drug release properties of Carbopol 907-based theophylline matrix tablets. The effect of copovidone on drug release was dependent on the pH of the dissolution medium. In a 0.1 N hydrochloride acid solution at pH 1.2 and 50?mM acetate buffer at pH 4.0, an insoluble tablet matrix was formed as a result of the in situ interpolymer complexation, and theophylline was released therefore via Fickian diffusion. In a 50?mM phosphate buffer at pH 6.8, drug release from the matrix tablets was still impacted by the in situ interpolymer complexation because of the low-pH microenvironment induced by Carbopol 907. As a result, drug release rate of the matrix tablet containing both polymers at pH 6.8 was slower than that of the matrix tablets containing individual polymers. We observed similar drug release rates at both pH 1.2 and pH 6.8 between tablets containing the physical blend of these two polymers and tablets containing preformed interpolymer complexes.     

Kinetic Release of Theophylline from Hydrophilic Swellable Matrices

The objective of this research was to evaluate the effect of hydroxypropylmethylcellulose (HPMC; Methocel K4M Premium) level and type of excipient on theophylline release and to attempt to predict the drug release from hydrophilic swellable matrices. Formulations containing theophylline anhydrous (10% w/w), Methocel K4M Premium (10%, 30%, and 40% w/w), different diluents (Lactose Fast Flo, Avicel PH-101, and Emcompress), and magnesium stearate (0.75% w/w) were prepared by direct compression at a target weight of 450 mg ± 5% and target hardness of 7 kp to 10 kp. It was found that, as the percentage of polymer in all formulations increased from 10% to 30% or 40%, the drug release decreased. However, there was no significant difference in drug release between formulations containing 30% polymer and formulations containing 40% polymer. At low levels of polymer, the drug release is controlled by the type of diluent used. Avicel PH-101 formulation gave the highest release, while its corresponding Emcompress formulation gave the lowest release. Formulations containing 30% or 40% polymer gave the same release profiles irrespective of the type of diluent used. In all cases, replacement of a portion of Methocel K4M Premium with any diluent resulted in increase of theophylline release. In addition, this investigation demonstrated that the drug release from hydrophilic swellable matrices can be predicted using only a minimum number of experiments.     

Preparation and Evaluation of Sustained Release Ibuprofen Beads

Sustained release beads of ibuprofen were prepared by a capillary method using cellulose acetate phthalate, surfactants (Tween 80 and Span 80), and polymers (K 100 M Methocel and K 100 LV Methocel). These beads were formulated into capsule and tablet dosage forms. The beads did not disintegrate in simulated gastric fluid; however, they disintegrated in simulated intestinal fluid. The dissolution profiles of ibuprofen beads and dosage forms of beads (tablets and capsules) were conducted in phosphate buffer (pH 7.2) at 37°C. The beads containing Span 80 and K 100 M Methocel resulted in prolonged drug release. The preparation containing Span 80 and equal quantities of both the polymers (K 100 M Methocel and K 100 LV Methocel), also showed good sustained release properties. The formulations prepared with Tween 80 and K 100 LV Methocel released over 90% of the drug in 2 hours indicating no sustained release properties. The beads in tablet dosage form yielded slower dissolution profiles compared to the beads in capsule form which, in turn, had slower release profiles compared to the beads alone. Release of ibuprofen was much slower from tablets after one year of storage compared to tablets immediately after their manufacture.     

Studies on Drug Release Kinetics from Carbomer Matrices

The objective of this study is to gain a mechanistic understanding of drug release kinetics from directly compressed tablets containing Carbopol 934P and 974P resins. Carbopol resins belong to a family of carbomers which are synthetic, high molecular weight, non-linear polymers of acrylic acid, crosslinked with polyalkenyl polyether. They are currently being used as polymeric matrices for controlling drug release in pharmaceutical tablets. This investigation focuses on the influence of the type of drug and the pH of the dissolution media, along with other factors on the drug release kinetics from carbomer matrices. Directly compressed tablets were prepared using a Stokes single station laboratory press and blends of polymers and lactose with drugs like theophylline, norephedrine HCI, and chlorpheniramine maleate. In vitro. drug release studies from the tablets were performed according to USP method II. Drug release rates were obtained by plotting the fraction released versus time and data fitted to the equation:     

Sucralfate as a Bioadhesive Gastric Intestinal Retention system: Preliminary Evaluation

Abstract

A prototype formulation of a gastric intestinal retention system was successfully developed. A matrix tablet containing sucralfate, Methocel E4M and the appropriate type of drug powder, granules or pellets was prepared using the Carver Press. Three different formulations were evaluated using three different drug entities, namely; theophylline sustained release pellets, aspirin granules and antacid powder. Tablets of these three different formulations showed remarkable adhesive characteristics onto the glass vessel in acidic medium up to at least eight hours. In addition, all three different formulations exhibited sustained release in-vitro dissolution profiles. These data imply that this gastric intestinal retention system can be used to prepare sustained release formulations.     

Preparation and Evaluation of Sustained Release Ibuprofen Beads

Sustained release beads of ibuprofen were prepared by a capillary method using cellulose acetate phthalate, surfactants (Tween 80 and Span 80), and polymers (K 100 M Methocel and K 100 LV Methocel). These beads were formulated into capsule and tablet dosage forms. The beads did not disintegrate in simulated gastric fluid; however, they disintegrated in simulated intestinal fluid. The dissolution profiles of ibuprofen beads and dosage forms of beads (tablets and capsules) were conducted in phosphate buffer (pH 7.2) at 37°C. The beads containing Span 80 and K 100 M Methocel resulted in prolonged drug release. The preparation containing Span 80 and equal quantities of both the polymers (K 100 M Methocel and K 100 LV Methocel), also showed good sustained release properties. The formulations prepared with Tween 80 and K 100 LV Methocel released over 90% of the drug in 2 hours indicating no sustained release properties. The beads in tablet dosage form yielded slower dissolution profiles compared to the beads in capsule form which, in turn, had slower release profiles compared to the beads alone. Release of ibuprofen was much slower from tablets after one year of storage compared to tablets immediately after their manufacture.     

Sucralfate as a Bioadhesive Gastric Intestinal Retention system: Preliminary Evaluation

A prototype formulation of a gastric intestinal retention system was successfully developed. A matrix tablet containing sucralfate, Methocel E4M and the appropriate type of drug powder, granules or pellets was prepared using the Carver Press. Three different formulations were evaluated using three different drug entities, namely; theophylline sustained release pellets, aspirin granules and antacid powder. Tablets of these three different formulations showed remarkable adhesive characteristics onto the glass vessel in acidic medium up to at least eight hours. In addition, all three different formulations exhibited sustained release in-vitro dissolution profiles. These data imply that this gastric intestinal retention system can be used to prepare sustained release formulations.     

Matrices of water-soluble drug using natural polymer and direct compression method

The objective of this research was to find an optimum Carrageenan matrix formulation with the desired drug release and physical properties prepared by direct compression. In order to achieve this, matrices containing 10% theophylline, different Carrageenan level, and different excipient were prepared and evaluated. A selected matrix containing 40% Carrageenan and lactose fast flo was tested for dissolution in three different dissolution media (distilled water, 0.1 N HCl, and phosphate buffer pH 7.4). The same formulation was also tested for dissolution at 50 rpm, 100 rpm, and 150 rpm, and using different dissolution apparatus (Apparatus 1 and 2).

All matrices showed a decrease in drug release as the polymer level was increased. Only Avicel PH-101 did not show any significant difference between matrices prepared with 30% and 40% polymer. At 10% polymer level, it appears that the type of diluent used controls the drug release. However, at high polymer level, 30% and 40%, it appears that the polymer level controls the drug release. Phosphate buffer pH 7.4 and 0.1 N HCl increase drug release and appear to increase Carrageenan solubility and decrease gel formation. Also, as the rotational speed of the apparatus was increased, the integrity of the gel layer was decreased, and the release of drug was increased. The drug release from Carrageenan matrices appears to follow the diffusion model for inert matrix up to 90 min. After 90 min, the drug release follows a zero-order model.

This study demonstrated that matrices using Carrageenan can be successfully prepared by direct compression.     

Matrices of Water-Soluble Drug Using Natural Polymer and Direct Compression Method

ABSTRACT

The objective of this research was to find an optimum Carrageenan matrix formulation with the desired drug release and physical properties prepared by direct compression. In order to achieve this, matrices containing 10% theophylline, different Carrageenan level, and different excipient were prepared and evaluated. A selected matrix containing 40% Carrageenan and lactose fast flo was tested for dissolution in three different dissolution media (distilled water, 0.1 N HCl, and phosphate buffer pH 7.4). The same formulation was also tested for dissolution at 50 rpm, 100 rpm, and 150 rpm, and using different dissolution apparatus (Apparatus 1 and 2).

All matrices showed a decrease in drug release as the polymer level was increased. Only Avicel PH-101 did not show any significant difference between matrices prepared with 30% and 40% polymer. At 10% polymer level, it appears that the type of diluent used controls the drug release. However, at high polymer level, 30% and 40%, it appears that the polymer level controls the drug release. Phosphate buffer pH 7.4 and 0.1 N HCl increase drug release and appear to increase Carrageenan solubility and decrease gel formation. Also, as the rotational speed of the apparatus was increased, the integrity of the gel layer was decreased, and the release of drug was increased. The drug release from Carrageenan matrices appears to follow the diffusion model for inert matrix up to 90 min. After 90 min, the drug release follows a zero-order model.

This study demonstrated that matrices using Carrageenan can be successfully prepared by direct compression.     

Oral sustained-release bioadhesive tablet formulation of didanosine

The objective of this study was to formulate a hydrogel-forming bioadhesive drug delivery system for oral administration of didanosine (ddI). The aim of this tablet dosage form is to improve the oral absorption of ddI by delivering it in small doses over an extended period and localizing it in the intestine by bioadhesion. Compressed tablets of ddI using Polyox® WSRN-303, Carbopol® 974P-NF, and Methocel® K4M as the bioadhesive release rate-controlling polymers were prepared. The effect of polymer concentration on the release profile and in vitro bioadhesion of the matrix tablets was studied. Tablet formulations with Polyox WSRN-303 (10%) and Methocel K4M (30%) showed 93 and 90% drug release, respectively, after 12 h. The drug release was found to be linear when fitted in the Higuchi equation (square-root time equation), suggesting zero-order release. Carbopol 974-P-NF was found to inhibit the complete release of ddI because of drug-polymer interaction; hence, is not suitable for formulation of ddI. Drug diffusion and swelling of the polymer (anomalous Fickian release) was found dominant in ddI release. In general, in vitro bioadhesion increased with an increase in polymer concentration. Tablets containing a single polymer can be designed to form hydrogels serving the dual purpose of bioadhesion and sustained release.