Sustained-release from Layered Matrix System Comprising Chitosan and Xanthan Gum

ABSTRACT

Sustained-release tablets of propranolol HCl were prepared by direct compression using chitosan and xanthan gum as matrix materials. The effective prolongation of drug release in acidic environment was achieved for matrix containing chitosan together with xanthan gum which prolonged the drug release more extensive than that containing single polymer. Increasing lactose into matrix could adjust the drug release characteristic by enhancing the drug released. Component containing chitosan and xanthan gum at ratio 1:1 and lactose 75% w/w was selected for preparing the layered matrix by tabletting. Increasing the amount of matrix in barrier or in middle layer resulted in prolongation of drug release. From the investigation of drug release from one planar surface, the lag time for drug release through barrier layer was apparently longer as the amount of barrier was enhanced. Least square fitting the experimental dissolution data to the mathematical expressions (power law, first order, Higuchi's and zero order) was performed to study the drug release mechanism. Layering with polymeric matrix could prolong the drug release and could shift the release pattern approach to zero order. The drug release from chitosan-xanthan gum three-layer tablet was pH dependent due to the difference in charge density in different environmental pH. FT-IR and DSC studies exhibited the charge interaction between of NH₃⁺ of chitosan molecule and COO^? of acetate or pyruvate groups of xanthan gum molecule. The SEM images revealed the formation of the loose membranous but porous film that was due to the gel layer formed by the polymer relaxation upon absorption of dissolution medium. The decreased rate of polymer dissolution resulting from the decreased rate of solvent penetration was accompanied by a decrease in drug diffusion due to ionic interaction between chitosan and xanthan gum. This was suggested that the utilization of chitosan and xanthan gum could give rise to layered matrix tablet exhibiting sustained drug release.     

Development of Polysaccharide-Based Colon Targeted Drug Delivery Systems for the Treatment of Amoebiasis

ABSTRACT

The main focus of this study is to develop colon targeted drug delivery systems for metronidazole (MTZ). Tablets were prepared using various polysaccharides or indigenously developed graft copolymer of methacrylic acid with guar gum (GG) as a carrier. Various polysaccharides such as GG, xanthan gum, pectin, carrageenan, β-cyclodextrin (CD) or methacrylic acid-g-guar (MAA-g-GG) gum have been selected and evaluated. The prepared tablets were tested in vitro for their suitability as colon-specific drug delivery systems. To further improve the colon specificity, some selected tablet formulations were enteric coated with Eudragit-L 100 to give protection in an acidic environment. Drug release studies were performed in simulated gastric fluid (SGF) for 2 hr followed by simulated intestinal fluid (SIF) at pH 7.4. The dissolution data demonstrate that the rate of drug release is dependent upon the nature and concentration of polysaccharide/polymer used in the formulations. Uncoated tablets containing xanthan gum or mixture of xanthan gum with graft copolymer showed 30–40% drug release during the initial 4–5 hr, whereas for tablets containing GG with the graft copolymer, it was 70%. After enteric coating, the release was drastically reduced to 18–24%. The other polysaccharides were unable to protect drug release under similar conditions. Preparations with xanthan gum as a matrix showed the time-dependent release behavior. Further, in vitro release was performed in the dissolution media with rat caecal contents. Results indicated an enhanced release when compared to formulations studied in dissolution media without rat caecal contents, because of microbial degradation or polymer solubilization. The nature of drug transport was found to be non-Fickian in case of uncoated formulations, whereas for the coated formulations, it was found to be super-Case-II. Statistical analyses of release data indicated that MTZ release is significantly affected by the nature of the polysaccharide used and enteric coating of the tablet. Differential scanning calorimetry indicated the presence of crystalline nature of drug in the formulations.     

Design and in vitro characterization of buccoadhesive tablets of timolol maleate

Objective: The purpose of this work was to develop and evaluate buccoadhesive tablets of timolol maleate (TM) due to its potential to circumvent the first-pass metabolism and to improve its bioavailability.

Methods: The tablets were prepared by direct compression using two release modifying polymers, Carbopol 974P (Cp-974p) and sodium alginate (SA). A 3² full factorial design was employed to study the effect of independent variables, Cp-974p and SA, in various proportions in percent w/w, which influences the in vitro drug release and bioadhesive strengths. Physicochemical properties of the drug were evaluated by ultraviolet, Fourier transform infrared spectroscopy (FTIR), differential scanning calorimetry (DSC) and powder X-ray diffraction (P-XRD). Tablets were evaluated for hardness, thickness, weight variation, drug content, surface pH, swelling index, bioadhesive force and in vitro drug release.

Results: The FTIR and DSC studies showed no evidence of interactions between drug, polymers and excipients. The P-XRD study revealed that crystallinity of TM remain unchanged in optimized formulation tablet. Formulation F9 achieves an in vitro drug release of 98.967%?±?0.28 at 8?h and a bioadhesive force of 0.088 N?±?0.01211.

Conclusion: We successfully developed buccal tablet formulations of TM and describe a non-Fickian-type anomalous transport as the release mechanism.     

Sustained-release from layered matrix system comprising chitosan and xanthan gum

Sustained-release tablets of propranolol HCl were prepared by direct compression using chitosan and xanthan gum as matrix materials. The effective prolongation of drug release in acidic environment was achieved for matrix containing chitosan together with xanthan gum which prolonged the drug release more extensive than that containing single polymer. Increasing lactose into matrix could adjust the drug release characteristic by enhancing the drug released. Component containing chitosan and xanthan gum at ratio 1:1 and lactose 75% w/w was selected for preparing the layered matrix by tabletting. Increasing the amount of matrix in barrier or in middle layer resulted in prolongation of drug release. From the investigation of drug release from one planar surface, the lag time for drug release through barrier layer was apparently longer as the amount of barrier was enhanced. Least square fitting the experimental dissolution data to the mathematical expressions (power law, first order, Higuchi's and zero order) was performed to study the drug release mechanism. Layering with polymeric matrix could prolong the drug release and could shift the release pattern approach to zero order. The drug release from chitosan-xanthan gum three-layer tablet was pH dependent due to the difference in charge density in different environmental pH. FT-IR and DSC studies exhibited the charge interaction between of NH₃⁺ of chitosan molecule and COO^- of acetate or pyruvate groups of xanthan gum molecule. The SEM images revealed the formation of the loose membranous but porous film that was due to the gel layer formed by the polymer relaxation upon absorption of dissolution medium. The decreased rate of polymer dissolution resulting from the decreased rate of solvent penetration was accompanied by a decrease in drug diffusion due to ionic interaction between chitosan and xanthan gum. This was suggested that the utilization of chitosan and xanthan gum could give rise to layered matrix tablet exhibiting sustained drug release.     

In vitro evaluation of gentamicin- and vancomycin-containing minitablets as a replacement for fortified eye drops

Objective: Ocular bioadhesive minitablets containing gentamicin and vancomycin were developed using different powder mixtures of pregelatinized starch and Carbopol (physical or cospray-dried mixtures). Methods: Drug content, antimicrobial activity, and radical formation of the powders used for tablet preparation were evaluated immediately and 30 days after gamma sterilization. Tablet properties and in vitro drug release from the sterilized minitablets were determined. Storage stability of vancomycin and gentamicin in sterilized bioadhesive mixtures was examined by LC–UV/MS and a microbiological assay, respectively. A bioadhesive powder mixture containing only vancomycin was irradiated by X electron-magnetic radiation to evaluate vancomycin stability following sterilization through irradiation. Results: The antimicrobial activity of gentamicin against Staphylococcus epidermidis was not altered in comparison to nonsterilized formulations. Only after an overkill dose of 50 kGy, the concentration of vancomycin decreases to an extent that was pharmaceutically significant. No significant difference in radiation stability between drug substance and product (i.e., powder mixture) was observed. A shift in stability profile was not observed at 6 weeks after irradiation. All other degradation products were present only in small quantities not exceeding 1.0%. The in vitro drug release from the minitablets prepared with physical powder mixtures of pregelatinized starch and Carbopol® 974P NF (96 : 4) was faster compared to the cospray-dried mixtures of starch with Carbopol® 974P NF (ratio: 95:5 and 85:15). The electron paramagnetic resonance signals of the radicals formed during sterilization were still visible after storage for 30 days. The slug mucosal irritation test indicated mild irritation properties of the bioadhesive powder mixtures although no tissue damage was observed.     

Development of polysaccharide-based colon targeted drug delivery systems for the treatment of amoebiasis

The main focus of this study is to develop colon targeted drug delivery systems for metronidazole (MTZ). Tablets were prepared using various polysaccharides or indigenously developed graft copolymer of methacrylic acid with guar gum (GG) as a carrier. Various polysaccharides such as GG, xanthan gum, pectin, carrageenan, β-cyclodextrin (CD) or methacrylic acid-g-guar (MAA-g-GG) gum have been selected and evaluated. The prepared tablets were tested in vitro for their suitability as colon-specific drug delivery systems. To further improve the colon specificity, some selected tablet formulations were enteric coated with Eudragit-L 100 to give protection in an acidic environment. Drug release studies were performed in simulated gastric fluid (SGF) for 2 hr followed by simulated intestinal fluid (SIF) at pH 7.4. The dissolution data demonstrate that the rate of drug release is dependent upon the nature and concentration of polysaccharide/polymer used in the formulations. Uncoated tablets containing xanthan gum or mixture of xanthan gum with graft copolymer showed 30-40% drug release during the initial 4-5 hr, whereas for tablets containing GG with the graft copolymer, it was 70%. After enteric coating, the release was drastically reduced to 18-24%. The other polysaccharides were unable to protect drug release under similar conditions. Preparations with xanthan gum as a matrix showed the time-dependent release behavior. Further, in vitro release was performed in the dissolution media with rat caecal contents. Results indicated an enhanced release when compared to formulations studied in dissolution media without rat caecal contents, because of microbial degradation or polymer solubilization. The nature of drug transport was found to be non-Fickian in case of uncoated formulations, whereas for the coated formulations, it was found to be super-Case-II. Statistical analyses of release data indicated that MTZ release is significantly affected by the nature of the polysaccharide used and enteric coating of the tablet. Differential scanning calorimetry indicated the presence of crystalline nature of drug in the formulations.     

Xanthan Gum and Alginate Based Controlled Release Theophylline Formulations

Abstract

The oral absorption of theophylline from two sustained release formulations, formulated using xanthan gum or sodium alginate, has been investigated in the beagle dog. A commercial product was used for comparison. Dissolution tests and an in vivo dog study both indicated that the xanthan gum tablet released drug at a constant rate and performed as a pH independent zero-order controlled release formulation. With the alginate tablet, faster dissolution rates were observed when acid medium was present. The pH dependent release behavior of the alginate formulation is explained. Drug release mechanisms which are influenced by the gel behaviors in these two polymers are discussed. The relative oral bioavailabilities of these two formulations in dog were 74–84% compared to immediately releasing capsules, and three-fold that of the commercial product with an equivalent dose.     

Polysaccharide matrices for microbially triggered drug delivery to the colon

Matrix tablets were prepared using xanthan gum (XG) and guar gum (GG) in varying proportions, and the suitability of the prepared tablets was evaluated for colon specific drug delivery. Indomethacin was used as a model drug. The ability of the prepared matrices to retard drug release in the upper gastrointestinal tract (GIT) and to undergo enzymatic hydrolysis by the colonic bacteria was evaluated. For this, drug release studies were carried out in the presence of rat cecal content. Further cecal content of rats with induced enzymatic activity were used. To ascertain the role of bacterial flora in carrying out the hydrolysis of the tablet, cecal content of rats treated with antibiotics were used in the dissolution media. Presence of XG in combination with GG in the tablets could retard drug release in the conditions of the upper GIT. However, the presence of GG and starch made these matrices microbially degradable. Guar gum alone as a drug release-retarding excipient in the matrices does not achieve the desired retardation. Presence of XG in the tablets not only retards the initial drug release from the tablets, but due to high swelling, makes them more vulnerable to digestion by the microbial enzymes in the colon.     

Statistical evaluation of influence of xanthan gum and guar gum blends on dipyridamole release from floating matrix tablets

The present investigation explored the use of xanthan gum and guar gum for development of floating drug delivery system of dipyridamole using factorial design approach. The content of polymer blends (X(1)) and ratio of xanthan gum to guar gum (X(2)) were selected as independent variables. The diffusion exponent (n), release rate constant (k), percentage drug release at 1 hr (Q(1)) and 6 hr (Q(6)) were selected as dependent variables. Tablets of all batches had desired buoyancy characteristics. Multiple regression analysis with two way ANOVA revealed that both the factors had statistically significant influence on the response studied (p<0.05). Results of Tukey test showed the relative contribution of each level of different factors for the response studied. It was concluded that the ratio of xanthan to gaur gum had equal or dominant role as controlling factor on kinetics of drug release compared to content of polymer blends.     

Evaluation of Xanthan Gum in the Preparation of Sustained Release Matrix Tablets

The objective of this study was to evaluate xanthan gum as a matrix former for the preparation of sustained release tablets. Preliminary experiments indicated that a fine particle sue of xanthan gum produced the slowest and most reproducible release profiles. Based on single surface experiments and tablet erosion studies, it was concluded that release of a soluble drug (chlorpheniramine maleate) and an insoluble drug (theophylline) from tablets containing low concentraions of xanthan gum was mainly via diffusion and erosion, respectively. Drug release from tablets containing xanthan gum was slightly faster in acidic media due to more rapid initial surface erosion than at higher pH. After hydration of the gum, drug release was essentially pH-independent. The amount released was directly proportional to the loading dose of drug and inversely proportional to gum concentration in tablets. Release profiles of chlorpheniramine maleate and theophylline remained unchanged after three months storage of the tablets at 40°C/80% RH and 40°C. Model tablets containing 5% xanthan gum exhibited release profiles similar to tablets containing 15% hydroxypropyl methylcellulose.     

Formulation and rheological evaluation of ethosome-loaded carbopol hydrogel for transdermal application

Objective: To select a suitable ethosome-loaded Carbopol hydrogel formulation, specifically tailored for transdermal application that exhibits (i) plastic flow with yield stress of approximately 50–80?Pa at low polymer concentration, (ii) relatively frequency independent elastic (G′) and viscous (G″) properties and (iii) thermal stability.

Methods: Carbopol (C71, C934, C941, C971 or C974) hydrogels were prepared by dispersing Carbopol in distilled water followed neutralization by sodium hydroxide. The effects of Carbopol grade, Carbopol concentration, ethosome addition and temperature on flow (yield stress and viscosity) and viscoelastic (G′ and G″) properties of Carbopol hydrogel were evaluated. Based on the aforementioned rheological properties evaluated, suitable ethosome-loaded Carbopol hydrogel was selected. In-vitro permeation studies of diclofenac using rat skin were further conducted on ethosome-loaded Carbopol hydrogel along with diclofenac-loaded ethosomal formulation as control.

Results: Based on preliminary screening, C934, C971 and C974 grades were selected and further evaluated for flow and viscoelastic properties. It was observed that ethosome-loaded C974 hydrogel at concentration of 0.50 and 0.75% w/w, respectively, demonstrated acceptable plastic flow with distinct yield stress and a frequency independent G′ and G″. Furthermore, the flow and viscoelastic properties were maintained at the 4, 25 and 32?°C. The results from in vitro skin permeation studies indicate that ethosome-loaded C974 hydrogel at 0.5% w/w polymer concentration exhibited similar skin permeation as that of ethosomal formulation.

Conclusion: The results indicate that suitable rheological properties of C974 could facilitate in achieving desired skin permeation of diclofenac while acting as an efficient carrier system for ethosomal vesicles.     

Development of topical hydrogels of terbinafine hydrochloride and evaluation of their antifungal activity

The purpose of this study was to prepare hydrogels and microemulsion (ME)-based gel formulations containing 1% terbinafine hydrochloride (TER-HCL) and to evaluate the use of these formulations for the antifungal treatment of fungal infections. Three different hydrogel formulations were prepared using chitosan, Carbopol® 974 and Natrosol® 250 polymers. A pseudo-ternary phase diagram was constructed, and starting from ME formulation, a ME gel form containing 1% Carbopol 974 was prepared. We also examined the characteristic properties of the prepared hyrogels. The physical stability of hydrogels and the ME -based gels were evaluated after storage at different temperatures for a period of 3 months. The release of TER-HCL from the gels and the commercial product (Lamisil®) was carried out by using a standard dialysis membrane in phosphate buffer (pH 5.2) at 32?°C. The results of the in vitro release study showed that the Natrosol gel released the highest amount of drug, followed by Carbopol gel, chitosan gel, commercial product, and the microoemulsion-based gel in that order. In vitro examination of antifungal activity revealed that all the prepared and commercial products were effective against Candida parapsilosis, Penicillium, Aspergillus niger and Microsporum. These results indicate that the Natrosol®-based hydrogel is a good candidate for the topical delivery of TER-HCL.     

Incorporation of calcium salts into xanthan gum matrices: hydration,erosion and drug release characteristics

Xanthan gum (XG), a hydrophilic biopolymer with modified release properties, was used to produce directly compressed matrix tablets containing a model drug, sodium p-aminosalicylate. Three formulations were prepared, each containing a different calcium dihydrate salt: calcium chloride, calcium sulfate or dibasic calcium phosphate. The aim of the investigation was to relate the calcium ion content and solubility of the calcium salt to the in vitro drug release profile of the xanthan matrices. Tablet hydration, erosion and drug release were determined in distilled water using the British Pharmacopoeia (BP) paddle method. The data showed that the overall drug release was the greatest with addition of calcium sulfate, followed by calcium chloride and dibasic calcium phosphate. The chloride salt formulation displayed the greatest percentage erosion due to rapid mass loss during the initial phase, followed by those with sulfate or phosphate salts. As xanthan gel viscosity increased and drug release was also found to be lower, it can be concluded that drug release is influenced by the solubility of the salt present in the formulation, since these parameters determine the viscosity and structure of the gel layer.     

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:     

In situ gelling nasal inserts for influenza vaccine delivery

Purpose: The objective of this study was to investigate the potential of rapidly gelling nasal inserts as vaccine delivery system. Methods: Nasal inserts were prepared by freeze-drying hydrophilic polymer solutions containing influenza split vaccine. In vitro vaccine release from polymer solutions and inserts and the vaccine hemagglutination activity were determined. In vivo immunization studies in mice and rats were performed with nasal solutions and nasal inserts. Results: The in vitro release of proteins (vaccine) from polymeric solutions and inserts was incomplete because of the high molecular weight of the proteins. The release rate was controlled by the polymer (Lutrol® F68 > PVP 90 > HPMC K15M > Carbopol® > chitosan ≥ carrageenan = xanthan gum) because of differences in solution viscosity and possible polymer–protein interactions. Xanthan gum, a negatively charged polymer with intrinsic adjuvanticity, enhanced the serum IgG as well as the nasal IgA response in in vivo studies with nasal vaccine solutions. Poly-l-arginine and cationic lipid were the best performing adjuvants. Solutions containing vaccine with xanthan gum and cationic lipid were effectively stabilized with 0.4 M NaCl. Discussion: The specific activity of the major vaccine protein, hemagglutinin, was not significantly affected by the addition of polymers and the freeze-drying process during insert preparation. The addition of cationic lipid as adjuvant decreased the hemagglutination activity, which strongly indicated inhibition of the protein binding site to erythrocytes. Inserts prepared from xanthan gum and cationic lipid stabilized with NaCl showed a reduced protein activity but were superior to the cationic lipid alone. Conclusion: Rat immunization with solid nasal inserts based on xanthan gum containing the influenza vaccine, with or without an additional cationic lipid adjuvant, resulted in similar IgG levels as the pure nasal liquid vaccine formulation.     

Preparation and in-vivo evaluation of dimenhydrinate buccal mucoadhesive films with enhanced bioavailability

Abstract

Dimenhydrinate (DMH)-loaded buccal bioadhesive films for the prevention and treatment of motion sickness were prepared and optimized. This study examines the rate of drug release from the films for prolonged periods of time to reduce or limit the frequency of DMH administration. Based on preliminary studies using various polymers and concentrations, hydroxyethylcellulose (2.5, 3.0, and 3.2%), and xanthan gum (2.8%) were chosen as matrix polymers. The films were analyzed with respect to their mechanical, physicochemical, bioadhesive, swelling, and in-vitro release properties. In in-vivo pharmacokinetic studies, xanthan gum-based DMH buccal film was associated with significantly increased DMH plasma levels between 1 h and 5 h after DMH dosing when compared with an oral drug solution. The area under the curve AUC_{0–7 h} value of the mucoadhesive buccal film was two-fold higher than the oral DMH solution. Histological analysis revealed that DMH films cause mild morphological and inflammatory changes in rabbit buccal mucosa. The DMH buccal film is effective for approximately 7 h, thus representing an option for single-dose antiemetic therapy. This dosage regimen could be particularly beneficial for chain travelers who travel for long periods of time.     

Oral controlled release formulation for highly water-soluble drugs: drug--sodium alginate--xanthan gum--zinc acetate matrix

An oral controlled release formulation matrix for highly water-soluble drugs was designed and developed to achieve a 24-hour release profile. Using ranitidine HCl as a model drug, sodium alginate formulation matrices containing xanthan gum or zinc acetate or both were investigated. The caplets for these formulations were prepared by direct compression and the in vitro release tests were carried out in simulated intestinal fluid (SIF, pH7.5) and simulated gastric fluid (SGF, pH1.2). The release of the drug in the sodium alginate formulation containing only xanthan gum completed within 12 hours in the SIF, while the drug release in the sodium alginate formulation containing only zinc acetate finished almost within 2 hours in the same medium. Only the sodium alginate formulation containing both xanthan gum and zinc acetate achieved a 24-hour release profile, either in the SIF or in the pH change medium. In the latter case, the caplet released in the SGF for 2 hours was immediately transferred into the SIF to continue the release test. The results showed that the presence of both xanthan gum and zinc acetate in sodium alginate matrix played a key role in controlling the drug release for 24 hours. The helical structure and high viscosity of xanthan gum might prevent zinc ions from diffusing out of the ranitidine HCl-sodium alginate-xanthan gum-zinc acetate matrix so that zinc ions could react with sodium alginate to form zinc alginate precipitate with a cross-linking structure. The cross-linking structure might control a highly water-soluble drug to release for 24 hours. Evaluation of the release data showed the release mechanism for the novel formulation might be attributed to the diffusion of the drug.     

Polymorphism and drug release behavior of spray-dried microcapsules of sulfamethoxazole with polysaccharide gum and colloidal silica

Abstract

Sulfamethoxazole microcapsules with polysaccharide gum, i.e. xanthan gum and guar gum, were prepared by employing a spray drying technique. The aqueous or the ammonium hydroxide solution of the gum containing the drug with or without colloidal silica was atomized with a centrifugal wheel atomizer rotated at 40000 rpm into a drying chamber held at 140±10°C. By formulation with colloidal silica, particle size of the resultant product increased, leading to improve the flowability and packability for the tableting. Polymorphic sulfamethoxazole mixture of Form I, II and III was produced in the formulation with cellulose acetate     

Biopolymeric mucoadhesive bilayer patch of pravastatin sodium for Buccal delivery and treatment of patients with atherosclerosis

Mucoadhesive bilayer buccal patch has been developed to improve the bioavailability and therapeutic efficacy along with providing sustained release of pravastatin sodium. Buccal patches comprising of varying composition of Carbopol 934P and HPMC K4M were designed and characterized for surface pH, swelling index, in vitro bioadhesion, mechanical properties, in vitro drug release and in vivo pharmacokinetic and pharmacodynamics performance. All formulations exhibited satisfactory technological parameters and followed non-fickian drug release mechanism. Bilayer buccal patch containing Carbopol 934P and HPMC K4M in 4:6 ratio (PBP5) was considered optimum in terms of swelling, mucoadhesion, mechanical properties and in vitro release profile. Pharmacokinetic studies in rabbits showed significantly higher (p < 0.05) Cmax (75.63 ± 6.98 ng/mL), AUC_0-8 (311.10 ± 5.89 ng/mL/h) and AUC_0-∞ (909.42 ± 5.89 ng/mL/h) than pravastatin oral tablet (Cmax – 67.40 ± 9.23 ng/mL, AUC_0-8-130.33 ± 10.25 ng/mL/h and AUC_0-∞-417.17 ± 5.89 ng/mL/h)). While, increased tmax of buccal patch indicated its sustained release property in comparison to oral tablet. Pharmacodynamic studies in rabbits showed statistically significant difference (p < 0.005) in the reduction of TG (131.10 ± 10.23 mg/dL), VLDL (26.00 ± 2.56 mg/dL) and LDL level (8.99 ± 3.01 mg/dL) as compared to oral conventional tablet. In conclusion, bioavailability from the developed buccal patch of pravastatin was 2.38 times higher than the oral dosage form, indicating its therapeutic potential in the treatment of atherosclerosis.     

Oral Controlled Release Formulation for Highly Water‐Soluble Drugs: Drug–Sodium Alginate–Xanthan Gum–Zinc Acetate Matrix

An oral controlled release formulation matrix for highly water‐soluble drugs was designed and developed to achieve a 24‐hour release profile. Using ranitidine HCl as a model drug, sodium alginate formulation matrices containing xanthan gum or zinc acetate or both were investigated. The caplets for these formulations were prepared by direct compression and the in vitro release tests were carried out in simulated intestinal fluid (SIF, pH7.5) and simulated gastric fluid (SGF, pH1.2). The release of the drug in the sodium alginate formulation containing only xanthan gum completed within 12 hours in the SIF, while the drug release in the sodium alginate formulation containing only zinc acetate finished almost within 2 hours in the same medium. Only the sodium alginate formulation containing both xanthan gum and zinc acetate achieved a 24‐hour release profile, either in the SIF or in the pH change medium. In the latter case, the caplet released in the SGF for 2 hours was immediately transferred into the SIF to continue the release test. The results showed that the presence of both xanthan gum and zinc acetate in sodium alginate matrix played a key role in controlling the drug release for 24 hours. The helical structure and high viscosity of xanthan gum might prevent zinc ions from diffusing out of the ranitidine HCl–sodium alginate–xanthan gum–zinc acetate matrix so that zinc ions could react with sodium alginate to form zinc alginate precipitate with a cross‐linking structure. The cross‐linking structure might control a highly water‐soluble drug to release for 24 hours. Evaluation of the release data showed the release mechanism for the novel formulation might be attributed to the diffusion of the drug.