In Vitro Release of Disopyramide from Cellulose Acetate Butyrate Microspheres

Disopyramide was microencapsulated with cellulose acetate butyrate (CAB) using an emulsion-solvent evaporation process. Drug dissolution from microcapsules was studied in both simulated gastric (SGF) and intestinal fluids (SIF) under sink conditions using the USP paddle method. There was no significant difference between drug release into SIF and SGF. As the CAB to drug ratio decreased from 3:1 to 2:1 at constant polymer mass, the drug release rate increased and the T50Y0 decreased from 2.3 hr to 0.3 hr for 303 pm particles. Dissolution T50% increased from 0.4 hr to 2 hr when the mean microcapsule size was increased from 153 to 428 μm (26% drug loading). The addition of acetone to the external phase during preparation shifted the size distribution toward larger particles, but resulted in a higher drug dissolution rate for a given particle size range. A shift to smaller particles was obtained upon increasing the concentration of surfactant. The dissolution profiles were described by the Higuchi and Baker-Lonsdale equations for drug release from spherical matrices up to 90% of the drug release.     

In Vitro Release of Disopyramide from Cellulose Acetate Butyrate Microspheres

Abstract

Disopyramide was microencapsulated with cellulose acetate butyrate (CAB) using an emulsion-solvent evaporation process. Drug dissolution from microcapsules was studied in both simulated gastric (SGF) and intestinal fluids (SIF) under sink conditions using the USP paddle method. There was no significant difference between drug release into SIF and SGF. As the CAB to drug ratio decreased from 3:1 to 2:1 at constant polymer mass, the drug release rate increased and the T50Y0 decreased from 2.3 hr to 0.3 hr for 303 pm particles. Dissolution T50% increased from 0.4 hr to 2 hr when the mean microcapsule size was increased from 153 to 428 μm (26% drug loading). The addition of acetone to the external phase during preparation shifted the size distribution toward larger particles, but resulted in a higher drug dissolution rate for a given particle size range. A shift to smaller particles was obtained upon increasing the concentration of surfactant. The dissolution profiles were described by the Higuchi and Baker-Lonsdale equations for drug release from spherical matrices up to 90% of the drug release.     

Design and Evaluation of a Two-Layer Floating Tablet for Gastric Retention Using Cisapride as a Model Drug

A new kind of two-layer floating tablet for gastric retention (TFTGR) with cisapride as a model drug was developed. The in vitro drug release was determined, and the resultant buoyancy and the time-buoyancy curve were plotted. Because of the sodium bicarbonate added to the floating layer, when immersed in simulated gastric fluid (SGF) the tablet expands and rises to the surface, where the drug is gradually released. The in vitro drug release of this kind of two-layer dosage was controlled by the amount of hydroxypropylmethylcellulose (HPMC) in the drug-loading layer. Generally, the more HPMC, the slower the drug releases. Because cisapride has greater solubility in SGF than simulated intestinal fluid (SIF), its in vitro drug dissolution in SGF is faster than in SIF. One of the distinguishing characteristics of this kind of tablet is the separate regulation of buoyancy and drug release. The idea developed in this experiment can be used as a general model for the design of other tablets for gastric retention.     

Design and Evaluation of a Two-Layer Floating Tablet for Gastric Retention Using Cisapride as a Model Drug

A new kind of two-layer floating tablet for gastric retention (TFTGR) with cisapride as a model drug was developed. The in vitro drug release was determined, and the resultant buoyancy and the time-buoyancy curve were plotted. Because of the sodium bicarbonate added to the floating layer, when immersed in simulated gastric fluid (SGF) the tablet expands and rises to the surface, where the drug is gradually released. The in vitro drug release of this kind of two-layer dosage was controlled by the amount of hydroxypropylmethylcellulose (HPMC) in the drug-loading layer. Generally, the more HPMC, the slower the drug releases. Because cisapride has greater solubility in SGF than simulated intestinal fluid (SIF), its in vitro drug dissolution in SGF is faster than in SIF. One of the distinguishing characteristics of this kind of tablet is the separate regulation of buoyancy and drug release. The idea developed in this experiment can be used as a general model for the design of other tablets for gastric retention.     

pH-sensitive hydrogels based on semi-interpenetrating network (semi-IPN) of chitosan and polyvinyl pyrrolidone for clarithromycin release

The aim of this study was to develop a pH-sensitive chitosan/polyvinyl pyrrolidone (PVP) based controlled drug release system for clarithromycin. The hydrogels were synthesized by cross-linking chitosan and PVP blend with glutaraldehyde to form a semi-interpenetrating polymer network (semi-IPN). These semi-IPNs were studied for their content uniformity, swelling index (SI), mucoadhesion, wettability, in vitro release and their release kinetics. The hydrogels showed more than 97% content of clarithromycin. These hydrogels showed high swelling and mucoadhesion under acidic conditions. The swelling may be due to the protonation of a primary amino group on chitosan. In acidic condition, chitosan would be ionized, and adhesion could have occurred between the positively charged chitosan and the negatively charged mucus. In the alkaline condition, less swelling and mucoadhesion was noticed. In vitro release study revealed that formulation containing chitosan (2% w/v) and PVP (4% w/v) in the ratio of 21:4 showed complete drug release after 12 h. Release profile showed that all the formulations followed non-Fickian diffusion mechanism. The cross-linking and compatibility of clarithromycin in the formulation was studied by Fourier transform infrared (FTIR) spectroscopic analysis, differential scanning calorimetry (DSC) and powder X-ray diffraction (p-XRD) study, which confirmed proper formation of semi-IPN and stability of clarithromycin in the formulations. The surface morphology of semi-IPN was studied before and after dissolution in simulated gastric fluid (SGF, pH 1.2) which revealed pores formation in membrane after dissolution. The results of study suggest that semi-IPNs of chitosan/PVP are potent candidates for delivery of clarithromycin in acidic environment.     

Development of Diclofenac Sodium Controlled Release Solid Dispersion Powders and Capsules by Freeze Drying Technique Using Ethylcellulose and Chitosan as Carriers

Abstract

Controlled-release, solid dispersions of diclofenac sodium (DS) were prepared by freeze-drying technique, using ethylcellulose (EC) and chitosan (CS) as single and combined carriers. Factorial design was applied as an experimental design to study the main and interactive effects of EC and CS on drug dissolution from the controlled release solid dispersion. All DS solid dispersions showed slower drug dissolution than did DS powder. The equations of dissolution parameters as functions of EC and CS contents were established through multiple regression. The contour plots of the established equations were constructed. The 10: (2.4 + 0.05) DS:(EC + CS) solid dispersion was prepared and developed into a capsule dosage from, using lactose as diluent. The effect on capsule dissolution of a disintegrant, sodium starch glycolate (Explotab®), in concentrations of 2%, 5%, and 8% was studied. The solid-dispersion capsule containing 5% Explotab was found to provide the most similar dissolution profile to the one obtained with the 10:(2.4 + 0.05) DS:(EC + CS) solid-dispersion powder. The dissolutions of the 10:(2.4 + 0.05) solid-dispersion powder and capsules were closer to a first-order model than to a zero-order or diffusion control model.     

Zero-order release of theophylline from a core-in-cup tablet in sequenced simulated gastric and intestinal fluid

Core-in-cup tablets containing theophylline were evaluated for their dissolution characteristics in sequenced simulated gastric fluid (SGF) followed by simulated intestinalfluid (SIF). Core-in-cup tablets containing 10% w/w, 20% w/w, and 30% w/w acacia as binder were evaluated for their effects on the time course of release of theophylline. This was done to optimize a formula that could release theophylline at a zero-order rate of release for 8-16 hr in simulated gastrointestinal fluids. Theophylline was released and dissolved from the core-in-cup tablets at a rate that is more consistent with a zero-order dissolution rate than a first-order dissolution rate in both SIG and SIF. The dissolution rates of theophylline from the 10%, 20%, and 30% acacia core-in-cup tablets were 0.87 mg/min, 0.53 mg/min, and 0.27 mg/min, respectively in SGF, and 0.61 mg/min, 0.30 mg/min, and 0.20 mg/min, respectively in SIF. The results indicate that a concentration of 32% w/w acacia in the core tablet will release theophylline at a rate of 0.14 mg/min in SGF for 2 hr followed by SIF for 10 hr.     

Poly (vinyl alcohol) hydrogels for pH dependent colon targeted drug delivery

Oral drug administration is convenient with pH dependent drug delivery system since the drug has to pass through different pH environments in gastro intestinal (GI) tract. The pH dependent swelling/shrinking behavior of hydrogel drug carrier controls the drug release without affecting the function of drug. pH dependent hydrogels of poly (vinyl alcohol) (PVA) were prepared by cross linking with maleic acid (MA). The hydrogels were characterized by attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectroscopy, DSC, porosimetry, SEM, TEM, biocompatibility study and by measuring their swelling behavior in water, simulated gastric fluid (SGF) and intestinal fluid (SIF). Swelling of the hydrogels was found to be highest in SIF (pH: 7.5) and lowest in SGF (pH: 1.2) resembling that required in colon targeted drug delivery systems. Since the swelling behavior of the gel is pH dependent, these hydrogels were studied for colon targeted drug delivery in an in-vitro set-up resembling the condition of GI tract. The ratio of PVA and MA in the hydrogel was varied to study the effect on the drug diffusion rate. For drug delivery study, vitamin B12 and salicylic acid were used as model drugs. The hydrogel, loaded with model drugs vitamin B12 and salicylic acid also demonstrated colon specific drug release with a relatively higher drug release in SIF (pH: 7.5) than that in SGF (pH: 1.2).     

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.     

pH-sensitive hydrogels based on semi-interpenetrating network (semi-IPN) of chitosan and polyvinyl pyrrolidone for clarithromycin release

The aim of this study was to develop a pH-sensitive chitosan/polyvinyl pyrrolidone (PVP) based controlled drug release system for clarithromycin. The hydrogels were synthesized by cross-linking chitosan and PVP blend with glutaraldehyde to form a semi-interpenetrating polymer network (semi-IPN). These semi-IPNs were studied for their content uniformity, swelling index (SI), mucoadhesion, wettability, in vitro release and their release kinetics. The hydrogels showed more than 97% content of clarithromycin. These hydrogels showed high swelling and mucoadhesion under acidic conditions. The swelling may be due to the protonation of a primary amino group on chitosan. In acidic condition, chitosan would be ionized, and adhesion could have occurred between the positively charged chitosan and the negatively charged mucus. In the alkaline condition, less swelling and mucoadhesion was noticed. In vitro release study revealed that formulation containing chitosan (2% w/v) and PVP (4% w/v) in the ratio of 21:4 showed complete drug release after 12?h. Release profile showed that all the formulations followed non-Fickian diffusion mechanism. The cross-linking and compatibility of clarithromycin in the formulation was studied by Fourier transform infrared (FTIR) spectroscopic analysis, differential scanning calorimetry (DSC) and powder X-ray diffraction (p-XRD) study, which confirmed proper formation of semi-IPN and stability of clarithromycin in the formulations. The surface morphology of semi-IPN was studied before and after dissolution in simulated gastric fluid (SGF, pH 1.2) which revealed pores formation in membrane after dissolution. The results of study suggest that semi-IPNs of chitosan/PVP are potent candidates for delivery of clarithromycin in acidic environment.     

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.     

Chitosan-Alginate Multilayer Beads for Gastric Passage and Controlled Intestinal Release of Protein

Abstract

Chitosan-alginate beads loaded with a model protein, bovine serum albumin (BSA) were investigated to explore the temporary protection of protein against acidic and enzymatic degradation during gastric passage. Optimum conditions were established for preparation of homogenous, spherical, and smooth chitosan-alginate beads loaded with BSA. Multilayer beads were prepared by additional treatment with either chitosan or alginate or both. The presence of chitosan in the coagulation bath during bead preparation resulted in increased entrapment of BSA. During incubation in simulated gastric fluid (SGF pH 1.2), the beads showed swelling and started to float but did not show any sign of erosion. Inclusion of pepsin in the gastric fluid did not show a further effect on the properties of the beads. Release studies were done in simulated gastric fluid (SGF pH 1.2) and subsequently in simulated intestinal fluid (SIF pH 7.5) to mimic the physiological gastrointestinal conditions. After transfer to intestinal fluid, the beads were found to erode, burst, and release the protein. Microscopic and macroscopic observations confirmed that the release of protein was brought about by the burst of beads. Chitosan-reinforced calcium-alginate beads showed delay in the release of BSA. The multilayer beads disintegrated very slowly. The enzymes pepsin and pancreatin did not change the characteristics of BSA-loaded chitosan-alginate beads. Single layer chitosan-alginate beads released 80–90% of the model protein within 12 h while multilayer beads released only 40–50% in the same period of time. The release from chitosan-alginate beads and multilayer beads in SIF was further delayed without prior incubation in SGF. It is concluded that alginate beads reinforced with chitosan offer an excellent perspective for controlled gastrointestinal passage of protein drugs.     

Chitosan-alginate multilayer beads for gastric passage and controlled intestinal release of protein

Chitosan-alginate beads loaded with a model protein, bovine serum albumin (BSA) were investigated to explore the temporary protection of protein against acidic and enzymatic degradation during gastric passage. Optimum conditions were established for preparation of homogenous, spherical, and smooth chitosan-alginate beads loaded with BSA. Multilayer beads were prepared by additional treatment with either chitosan or alginate or both. The presence of chitosan in the coagulation bath during bead preparation resulted in increased entrapment of BSA. During incubation in simulated gastric fluid (SGF pH 1.2), the beads showed swelling and started to float but did not show any sign of erosion. Inclusion of pepsin in the gastric fluid did not show a further effect on the properties of the beads. Release studies were done in simulated gastric fluid (SGF pH 1.2) and subsequently in simulated intestinal fluid (SIF pH 7.5) to mimic the physiological gastrointestinal conditions. After transfer to intestinal fluid, the beads were found to erode, burst, and release the protein. Microscopic and macroscopic observations confirmed that the release of protein was brought about by the burst of beads. Chitosan-reinforced calcium-alginate beads showed delay in the release of BSA. The multilayer beads disintegrated very slowly. The enzymes pepsin and pancreatin did not change the characteristics of BSA-loaded chitosan-alginate beads. Single layer chitosan-alginate beads released 80-90% of the model protein within 12 h while multilayer beads released only 40-50% in the same period of time. The release from chitosan-alginate beads and multilayer beads in SIF was further delayed without prior incubation in SGF. It is concluded that alginate beads reinforced with chitosan offer an excellent perspective for controlled gastrointestinal passage of protein drugs.     

Mucoadhesive nanostructured lipid carriers (NLCs) as potential carriers for improving oral delivery of curcumin

Purpose: To examine effects of polymer types on the mucoadhesive properties of polymer-coated nanostructured lipid carriers (NLCs).

Experiment: Curcumin-loaded NLCs were prepared using a warm microemulsion technique followed by coating particle surface with mucoadhesive polymers: polyethylene glycol400 (PEG400), polyvinyl alcohol (PVA), and chitosan (CS). The physicochemical properties and entrapment efficacy were examined. In vitro mucoadhesive studies were assessed by wash-off test. In addition, the stability of mucoadhesive NLCs in gastrointestinal fluids and the pattern of drug release were also investigated.

Findings: The obtained nanoparticles showed spherical shape with size ranging between 200?nm and 500?nm and zeta potential between ?37 and ?9?mV depending on the type of polymer coating. Up to 80% drug entrapment efficacy was observed. In vitro mucoadhesive studies revealed that PEG-NLCs and PVA-NLCs were adhered strongly to freshly porcine intestinal mucosa, more than 2-fold mucoadhesive compared to CS-NLCs and uncoated-NLCs. The particle size of all polymer-coated NLCs could be maintained in both simulated gastric fluid (SGF) and simulated intestinal fluid (SIF) suggesting good physical stability in physiological fluid. In contrast, uncoated-NLCs showed particle aggregation in SGF. In vitro dissolution studies revealed a fast release characteristic.     

Poly (vinyl alcohol) hydrogels for pH dependent colon targeted drug delivery

Oral drug administration is convenient with pH dependent drug delivery system since the drug has to pass through different pH environments in gastro intestinal (GI) tract. The pH dependent swelling/shrinking behavior of hydrogel drug carrier controls the drug release without affecting the function of drug. pH dependent hydrogels of poly (vinyl alcohol) (PVA) were prepared by cross linking with maleic acid (MA). The hydrogels were characterized by attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectroscopy, DSC, porosimetry, SEM, TEM, biocompatibility study and by measuring their swelling behavior in water, simulated gastric fluid (SGF) and intestinal fluid (SIF). Swelling of the hydrogels was found to be highest in SIF (pH: 7.5) and lowest in SGF (pH: 1.2) resembling that required in colon targeted drug delivery systems. Since the swelling behavior of the gel is pH dependent, these hydrogels were studied for colon targeted drug delivery in an in-vitro set-up resembling the condition of GI tract. The ratio of PVA and MA in the hydrogel was varied to study the effect on the drug diffusion rate. For drug delivery study, vitamin B₁₂ and salicylic acid were used as model drugs. The hydrogel, loaded with model drugs vitamin B₁₂ and salicylic acid also demonstrated colon specific drug release with a relatively higher drug release in SIF (pH: 7.5) than that in SGF (pH: 1.2).     

Basic drug--enterosoluble polymer coevaporates: development of oral controlled release systems

Precipitation of basic drugs within oral prolonged release systems, at the higher pH values of the intestine, would affect drug release. Coevaporates of a model basic drug verapamil HCl, in single or mixed polymer systems, containing Eudragit L100 (L100) and ethyl cellulose or Eudragit RS100, were prepared from ethanolic solution. XRD and DSC indicated loss of crystallinity of the drug in the coevaporates. The presence of the enterosoluble polymer in the system was found to aid in faster dissolution of the drug at higher pH values. This was affected by the presence and type of retarding polymer present in the system. Compression of the coevaporates resulted in either very slow release of the drug or undesirable changes in the release profile. Pelletization of a coevaporate containing drug and L100 yielded systems, which released the drug uniformly when studied by the buffer change method in simulated gastric (SGF) and intestinal (SIF) fluids. The presence of L100 in intimate contact with the drug was found to be essential for the desirable drug release properties of the system. The drug release occurred predominantly by diffusion in SGF and by a combination of diffusion and polymer dissolution/erosion in SIF. Appropriate choice of release modifiers and formulation variables and development of suitable formulations can yield systems which compensate for the reduced solubility of the drug in the higher pH environments of the intestine.     

Development of Diclofenac Sodium Controlled Release Solid Dispersion Tablet Using Optimization Strategy

Directly compressed diclofenac sodium (DS) controlled release tablets were prepared from spray-dried DS controlled release solid dispersion of optimum dissolution projile. Optimization strategy using a central composite design and multiple regression was used to study the influences of four parameters: compression force, the amounts of spray-dried rice starch (Era-TabR), croscarmellose sodium (Ac-Di-Sol^R), and magnesium stearate, on tablet physical properties and dissolution. The optimum conditions of those parameters were searched and an optimum DS controlled release tablet formulation was formulated. The dissolution profile of the optimized DS controlled release tablet was similar to that of the DS controlled release solid dispersion. The mechanism of drug release from the optimized DS tablet was found to be diffusion controlled.     

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.     

Effect of polymer molecular weight and of polymer blends on the properties of rapidly gelling nasal inserts

The objective was to investigate the potential of polymer molecular weight (MW) and polymer blends for the control of drug release from in situ gelling nasal inserts prepared by lyophilization of solutions of model drugs (oxymetazoline HCl, diprophyllin) and polymers. Drug release, polymer solution viscosity, water uptake and mass loss, mechanical properties, and bioadhesion potential were measured. Sonication was effective to reduce the viscosity/polymer MW of carrageenan solutions. Nasal inserts prepared from sonicated carrageenan showed an insignificant reduction in water uptake with sonication time and no disintegration of the gel matrix. In contrast, inserts of different MW Na-alginates revealed a reduced water uptake and an increased mass loss with lower MW. Inserts prepared from carrageenan/low MW Na-alginate blends took up more water at a higher low MW Na-alginate content. Sonicated carrageenan inserts released oxymetazoline HCl independent of the sonication time and diprophyllin with only a slight reduction in the release rate. Release of both drugs from Na-alginate inserts was slow from high MW inserts because no insert dissolution occurred. Increasing the Na-alginate content of inserts prepared from polymer blends accelerated the drug release enabling release rates over a broad range. The bioadhesion potential of Na-alginate inserts was strongly reduced for the low MW grades because of dissolution of the inserts. Xanthan gum and Carbopol 971 blended with Na-alginate formed inserts with poor bioadhesion. The use of polymer blends to control the drug release from nasal inserts was superior to the use of polymers of different MW.     

Formulation development and in-vitro/in-vivo correlation for a novel sterculia gum-based oral colon-targeted drug delivery system of azathioprine

The present study was aimed at designing a microflora triggered colon-targeted drug delivery system (MCDDS) based on swellable polysaccharide, sterculia gum in combination with biodegradable polymers with a view to target azathioprine (AZA) in the colon for the treatment of IBD with reduced systemic toxicity. The microflora degradation study of gum was investigated in rat cecal medium. The polysaccharide tablet was coated to different film thicknesses with blends of chitosan/Eudragit RLPO and over coated with Eudragit L00 to provide acid and intestinal resistance. Swelling and drug release studies were carried out in simulated gastric fluid (SGF) (pH 1.2), simulated intestinal fluid (SIF) (pH 6.8) and simulated colonic fluid (SCF) (pH 7.4 under anaerobic environment), respectively. Drug release study in SCF revealed that swelling force of the gum could concurrently drive the drug out of the polysaccharide core due to the rupture of the chitosan/Eudragit coating in microflora-activated environment. Chitosan in the mixed film coat was found to be degraded by enzymatic action of the microflora in the colon. Release kinetic data revealed that, the optimized MCDDS was fitted well into first order model and apparent lag time was found to be 6?h, followed by Higuchi spherical matrix release. The degradation of chitosan was the rate-limiting factor for drug release in the colon. In-vivo study in rabbit shows delayed T_max, prolonged absorption time, decreased C_max and absorption rate constant (K_a) indicating reduced systemic toxicity of the drug as compared to other dosage forms.