Development and in vitro evaluation of buccoadhesive carvedilol tablets

Buccoadhesive tablets of carvedilol were prepared using HPMC K4M, HPMC K15M and Carbopol 934 as mucoadhesive polymers. Fifteen formulations were developed with varying concentrations of polymers. Formulations of the BC or BD series were composed of HPMC K4M or HPMC K15M in ratios of 1:1 to 1:5 whereas in the BE series Carbopol 934 was used (1:0.25 to 1:1.50). The formulations were tested for in vitro drug release, in vitro bioadhesion, moisture absorption and in vitro drug permeation through porcine buccal mucosa. Formulation BC3 showed maximum release of the drug (88.7 +/- 0.4%) with the Higuchi model release profile and permeated 21.5 +/- 2.9% of the drug (flux 8.35 +/- 0.291 microg h(-1)cm(-2)) permeation coefficient 1.34 +/- 0.05 cm h(-1)) through porcine buccal membrane. BC3 formulation showed 1.62 +/- 0.15 N of peak detachment force and 0.24 +/- 0.11 mJ of work of adhesion. FTIR results showed no evidence of interaction between the drug and polymers. XRD study revealed that the drug is in crystalline form in the polymer matrix. The results indicate that suitable bioadhesive buccal tablets with desired permeability could be prepared.     

Mucoadhesive bilayer buccal tablet of carvedilol-loaded chitosan microspheres: in vitro, pharmacokinetic and pharmacodynamic investigations

A multiple-unit system comprising mucoadhesive bilayer buccal tablets of carvedilol-loaded chitosan microspheres (CMs) was developed to improve bioavailability and therapeutic efficacy of carvedilol. Drug-loaded CMs were prepared by spray drying, evaluated for powder and particle characteristics, and optimized batch of CMs was compressed into bilayer buccal tablets using Carbopol. Tablets were evaluated for physicochemical parameters, in vitro drug release, in vivo pharmacokinetic and pharmacodynamic studies. Optimized formulation, CMT1 (CMT, chitosan microsphere tablet) showed maximum mucoadhesive force (50?±?1.84?dyne/cm2), exhibited 73.08?±?3.05% drug release and demonstrated zero-order kinetics with non-Fickian release mechanism. Pharmacokinetic studies in rabbits showed significantly higher C(max) (71.26?±?6.45?ng/mL), AUC(0-10) (AUC, area under the curve 390.75?±?5.23?ng/mL/h) and AUC(0-∞) (664.72?ng/mL/h) than carvedilol oral tablet. Pharmacodynamic studies confirmed reduction in mean arterial pressure, heart rate, body weight and triglyceride on administration of bilayer buccal tablet compared to oral carvedilol tablet. Multiple-unit system exhibited enhanced bioavailability and sustained release of carvedilol, indicating its improved therapeutic potential for the treatment of hypertension.     

Mucoadhesive buccal patches based on interpolymer complexes of chitosan–pectin for delivery of carvedilol

The study was designed to develop bioadhesive patches of carvedilol hydrochloride using chitosan (CH) and pectin (PE) interpolymer complexes and to systematically evaluate their in vitro and in vivo performances. Mucoadhesive buccal patches of carvedilol were prepared using solvent casting method. The physicochemical interaction between CH and PE was investigated by FTIR and DSC studies. The patches were evaluated for their physical characteristics like mass variation, content uniformity, folding endurance, ex vivo mucoadhesion strength, ex vivo mucoadhesion time, surface pH, in vitro drug release, in situ release study, and in vivo bioavailability study. The swelling index of the patches was found to be proportional to the PE concentration. The surface pH of all the formulated bioadhesive patches was found to lie between 6.2 and 7.2. The optimized bioadhesive patch (C1, CH:PE 20:80) showed bioadhesive strength of 22.10 ± 0.20 g, in vitro release of 98.73% and ex vivo mucoadhesion time of 451 min with in a period of 8 h. The optimized patch demonstrated good in vitro and in vivo results. The buccal delivery of carvedilol in rabbits showed a significant improvement in bioavailability of carvedilol from patches when compared to oral route.     

Bilayered transmucosal drug delivery system of pravastatin sodium: statistical optimization, in vitro, ex vivo, in vivo and stability assessment

The objective of the present study was to develop a mucoadhesive sustained release bilayered buccal patch of pravastatin sodium using Eudragit S100 as the base matrix so as to surmount hepatic first pass metabolism and gastric instability of the drug. A 32 full factorial design was employed to study the effect of independent variables viz. levels of HPMC K4M and carbopol 934P on % cumulative drug release, mucoadhesion time and mucoadhesive force. Amount of carbopol 934P and HPMC K4M significantly influenced characteristics like swelling index, in vitro mucoadhesive force, drug release, and mucoadhesion time. In vitro evaluation revealed that formulations exhibited satisfactory technological parameters. The mechanism of drug release was found to be non-Fickian diffusion. Different permeation enhancers were investigated to improve the permeation of drug from the optimized patches (F9) across the buccal mucosa. Formulation [F9 (P3)] containing 4% (v/v) dimethyl sulfoxide exhibited desirable permeation of drug. Histopathological studies performed using goat buccal mucosa revealed no mucosal damage. Bioavailability studies in rabbits demonstrated that [F9 (P3)] significantly higher C(max) (67.34?±?3.58?ng/ml) and AUC??∞ (350.27?±?9.59?ng/ml×h) (p < 0.05) of pravastatin sodium from optimized patch than IR tablet (C(max) 58.73?±?4.63?ng/ml and AUC??∞ 133.80?±?8.25?ng/ml×h). Formulation [F9 (P3)] showed sustained drug plasma concentration over a period of 10?h which was significantly longer than oral tablet (p < 0.05). Stability studies as per ICH guidelines established physical stability of the patch and chemical stability drug. The present study established potential of the optimized mucoadhesive buccal patches to circumvent the hepatic first-pass metabolism, gastric instability and to improve bioavailability of pravastatin sodium.     

Effect of HPMC and mannitol on drug release and bioadhesion behavior of buccal discs of buspirone hydrochloride: In-vitro and in-vivo pharmacokinetic studies

Delivery of orally compromised therapeutic drug molecules to the systemic circulation via buccal route has gained a significant interest in recent past. Bioadhesive polymers play a major role in designing such buccal dosage forms, as they help in adhesion of designed delivery system to mucosal membrane and also prolong release of drug from delivery system. In the present study, HPMC (release retarding polymer) and mannitol (diluent and pore former) were used to prepare bioadhesive and controlled release buccal discs of buspirone hydrochloride (BS) by direct compression method. Compatibility of BS with various excipients used during the study was assessed using DSC and FTIR techniques. Effect of mannitol and HPMC on drug release and bioadhesive strength was studied using a 3² factorial design. The drug release rate from delivery system decreased with increasing levels of HPMC in formulations. However, bioadhesive strength of formulations increased with increasing proportion of HPMC in buccal discs. Increased levels of mannitol resulted in faster rate of drug release and rapid in vitro uptake of water due to the formation of channels in the matrix. Pharmacokinetic studies of designed bioadhesive buccal discs in rabbits demonstrated a 10-fold increase in bioavailability in comparison with oral bioavailability of buspirone reported.     

Transmucosal delivery of domperidone from bilayered buccal patches: <Emphasis Type="Italic">In Vitro,Ex Vivo</Emphasis> and <Emphasis Type="Italic">In Vivo</Emphasis> characterization

Bilayered mucoadhesive buccal patches for systemic administration of domperidone (DOM), a dopamine-receptor (D₂) antagonist, were developed using hydroxy propyl methyl cellulose and PVPK30 as a primary layer and Eudragit RLPO and PEO as a secondary layer. Ex vivo drug permeation through porcine buccal membrane was performed. Bilayered buccal patches were developed by solvent casting technique and evaluated for in vitro drug release, moisture absorption, mechanical properties, surface pH, in vitro bioadhesion, in vivo residence time and ex vivo permeation of DOM through porcine buccal membrane from a bilayered buccal patch. Formulation DB4 was associated with 99.5% drug release with a higuchi model release profile and 53.9% of the drug had permeated in 6 h, with a flux of 0.492 mg/h/cm² through porcine buccal membrane. DB4 showed 5.58 N and 3.28 mJ peak detachment force and work of adhesion, respectively. The physicochemical interactions between DOM and the polymer were investigated by differential scanning calorimetry (DSC) and fourier transform infrared (FTIR) Spectroscopy. DSC and FTIR studies revealed no interaction between drug and polymer. Stability studies for optimized patch DB4 was carried out at 40°C/75% relative humidity. The formulations were found to be stable over a period of 3 months with respect to drug content, in vitro release and ex vivo permeation through porcine buccal membrane. The results indicate that suitable bilayered mucoadhesive buccal patches with desired permeability could be prepared.     

制霉菌素口腔双层贴膜在口腔内释药动态研究

目的：测定自制的制霉菌素口腔双层贴膜在口腔内释药过程。方法：采用剩余量法测定制霉菌素口腔双层贴膜在口腔内释药情况,测定制霉菌素口腔双层贴膜体外释放度,并比较体内外释放的相关性。结果：体外释放方程：ln（100-Q）=-0.089t＋4.998,r=0.997 0,口腔内释药方程为ln（100-P）=-0.022t＋5.014,r=0.993 5。以体内平均释放百分率（Y,%）对体外平均释放百分率（X,%）回归,得方程Y=0.990X＋0.372,r=0.998 0。结论：体内外释放度具有良好的相关性,可以用体外释放度来预测药物的释放。     

Preparation and evaluation of fast dissolving ibuprofen-polyethylene glycol 6000 solid dispersions

To improve its oral absorption, rapidly dissolving ibuprofen solid dispersions (SD) were prepared in a relatively easy, simple, quick, inexpensive, and reproducible manner, characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and Fourier transform infrared spectroscopy (FTIR). They were evaluated for solubility, in vitro release, and oral bioavailability of ibuprofen in rats. Loss of individual surface properties during melting and resolidification as revealed by SEM indicated the formation of effective SDs. Absence or shifting toward the lower melting temperature of the drug peak in SDs and physical mixtures in DSC study indicated the possibilities of drug-polymer interactions. However, no such interactions in the solid state were confirmed by FTIR spectra that showed the presence of drug crystalline in SDs. Quicker release of ibuprofen from SDs in rat intestine resulted in a significant increase in AUC and C(max), and a significant decrease in T(max) over pure ibuprofen. Preliminary results from this study suggested that the preparation of fast-dissolving ibuprofen SDs by low temperature melting method using PEG 6000 as a meltable hydrophilic polymer carrier could be a promising approach to improve solubility, dissolution, and absorption rate of ibuprofen.     

Formulation, characterization, and in vitro evaluation of bioadhesive gels containing 5-Fluorouracil

The objective of this study was to prepare and evaluate in vitro the bioadhesive gels of 5-Fluorouracil (FU) for the treatment of oropharyngeal cancer. In preformulation study, the physicochemical interactions between FU and polymers were investigated by X-ray diffraction (XRD), Fourier transform infrared (FTIR) spectrophotometry, and differential scanning calorimetry (DSC). According to FTIR, XRD, and DSC studies, the drug did not show any evidence of an interaction with the polymers used and was present in an unchanged state. The gel formulations containing FU were prepared by using Poloxamer 407, HPMC K 15 M, and Gantrez S-97 (polymethylvinylether-co-maleic anhydride). The formulations contained Poloxamer 407 (16-18% w/w) either alone or in combination with HPMC K 15 M and Gantrez S-97. The bioadhesiveness of the gels was found to increase with increasing proportion of HPMC K 15 M and Gantrez S-97. In vitro release studies indicated that release could be sustained up to 8 hr. The permeability coefficients (Kp) of gel across cellulose membrane and buccal mucosal membrane were 1.06 x 10(-4) cm/s and 3.94 x 10(-5) cm/s, respectively, and differed significantly ( p < 0.05). Increasing temperature increased the drug release by increasing drug diffusion despite increase in viscosity. The pH of the release medium showed a very slight effect on the release of FU. Mathematical modeling of in vitro dissolution data indicated the best fitting with Korsemeyer-Peppas model and the drug release kinetics primarily as non-Fickian diffusion.     

Buccal absorption of ergotamine tartrate using the bioadhesive tablet system in guinea-pigs

The buccal administration of ergotamine tartrate (ET) combined with polyvinyl alcohol (PVA) gel brought about higher plasma concentration of ET compared with that of oral administration of capsules in guinea-pigs. T(max) of ET in plasma of buccal administration was significantly smaller than that of oral administration. For the buccal dosage form of ET, the bioadhesive tablet system (BTS) was newly developed. It consisted of a reservoir of drug and an adhesive region. BTS showed better absorption of ET compared with PVA gel in guinea pigs. Among several pharmaceutical bases in the reservoir of BTS, Witepsol W-35 was most effective. It is likely that the high lipophilic property of Witepsol W-35 in which ET was dissolved facilitated the drug release by its relatively low melting point (around 35 degrees C), consequently a rapid absorption. In addition, the enhancing activity of the cod-liver oil extract (CLOE) in hydrophilic ointment on the in vivo buccal ET absorption was clarified to be comparable to that in the in vitro study utilizing the keratinized epithelial-free membrane (KEF-membrane) of the hamster cheek pouch.     

Mucoadhesive bilayer buccal tablet of carvedilol-loaded chitosan microspheres: in vitro,pharmacokinetic and pharmacodynamic investigations

A multiple-unit system comprising mucoadhesive bilayer buccal tablets of carvedilol-loaded chitosan microspheres (CMs) was developed to improve bioavailability and therapeutic efficacy of carvedilol. Drug-loaded CMs were prepared by spray drying, evaluated for powder and particle characteristics, and optimized batch of CMs was compressed into bilayer buccal tablets using Carbopol. Tablets were evaluated for physicochemical parameters, in vitro drug release, in vivo pharmacokinetic and pharmacodynamic studies. Optimized formulation, CMT1 (CMT, chitosan microsphere tablet) showed maximum mucoadhesive force (50?±?1.84?dyne/cm²), exhibited 73.08?±?3.05% drug release and demonstrated zero-order kinetics with non-Fickian release mechanism. Pharmacokinetic studies in rabbits showed significantly higher C_max (71.26?±?6.45?ng/mL), AUC_0–10 (AUC, area under the curve 390.75?±?5.23?ng/mL/h) and AUC_0–∞ (664.72?ng/mL/h) than carvedilol oral tablet. Pharmacodynamic studies confirmed reduction in mean arterial pressure, heart rate, body weight and triglyceride on administration of bilayer buccal tablet compared to oral carvedilol tablet. Multiple-unit system exhibited enhanced bioavailability and sustained release of carvedilol, indicating its improved therapeutic potential for the treatment of hypertension.     

Formulation,Characterization, and In Vitro Evaluation of Bioadhesive Gels Containing 5-Fluorouracil

The objective of this study was to prepare and evaluate in vitro the bioadhesive gels of 5-Fluorouracil (FU) for the treatment of oropharyngeal cancer. In preformulation study, the physicochemical interactions between FU and polymers were investigated by X-ray diffraction (XRD), Fourier transform infrared (FTIR) spectrophotometry, and differential scanning calorimetry (DSC). According to FTIR, XRD, and DSC studies, the drug did not show any evidence of an interaction with the polymers used and was present in an unchanged state. The gel formulations containing FU were prepared by using Poloxamer 407, HPMC K 15 M, and Gantrez® S-97 (polymethylvinylether-co-maleic anhydride). The formulations contained Poloxamer 407 (16–18% w/w) either alone or in combination with HPMC K 15 M and Gantrez® S-97. The bioadhesiveness of the gels was found to increase with increasing proportion of HPMC K 15 M and Gantrez® S-97. In vitro release studies indicated that release could be sustained up to 8 hr. The permeability coefficients (Kp) of gel across cellulose membrane and buccal mucosal membrane were 1.06 × 10^?4 cm/s and 3.94 × 10^?5 cm/s, respectively, and differed significantly (p < 0.05). Increasing temperature increased the drug release by increasing drug diffusion despite increase in viscosity. The pH of the release medium showed a very slight effect on the release of FU. Mathematical modeling of in vitro dissolution data indicated the best fitting with Korsemeyer–Peppas model and the drug release kinetics primarily as non-Fickian diffusion.     

Transbuccal delivery of chlorpheniramine maleate from mucoadhesive buccal patches

This article describes buccal permeation of chlorpheniramine maleate (CPM) and its transbuccal delivery using mucoadhesive buccal patches. Permeation of CPM was calculated in vitro using porcine buccal membrane and in vivo in healthy humans. Buccal formulations were developed with hydroxyethylcellulose (HEC) and evaluated for in vitro release, moisture absorption, mechanical properties, and bioadhesion, and optimized formulation was subjected for bioavailability studies in healthy human volunteers. In vitro flux of CPM was calculated to be 0.14 ± 0.03 mg.h^-1.cm^-2 and buccal absorption also was demonstrated in vivo in human volunteers. In vitro drug release and moisture absorbed were governed by HEC content and formulations exhibited good tensile and mucoadhesive properties. Bioavailability from optimized buccal patch was 1.46 times higher than the oral dosage form and the results showed statistically significant difference.     

Development of mucoadhesive buccal films for the treatment of oral sub-mucous fibrosis: a preliminary study

The objective of the present study was to develop the mucoadhesive buccal film of valdecoxib for the treatment of oral sub mucous fibrosis, a localized buccal disease. Valdecoxib, a novel COX-2 inhibitor has been reported to be used in various osteopathic and rheumatoid conditions as oral therapy. The films were made out of chitosan and HPMC K4M as polymers. Sodium taurocholate was used as a permeation enhancer. All the formulations were examined for film thickness, swelling properties, drug content, weight variation, in vitro release studies, bioadhesive force, tensile strength, diffusion studies using pig mucosa and pharmacokinetic study in healthy male volunteers. Prepared films were thin, flexible, smooth and transparent. Bioadhesive force and tensile strength of the optimized formulation were found to be 75 ± 4 kg m^?1 S^?2 and more than 2.5 kg/3 cm², respectively. The percent drug content was 98.5 ± 1.3%. The in vitro drug release from the selected formulation showed that about 69.34% of the drug payload was released up to 6 hours. The drug permeation through the dialysis sac and pig buccal mucosa was found to be 62.70% and 54.39%, respectively. Pharmacokinetic studies of the buccal mucoadhesive film showed that the drug was released locally at the target site of action, and a very small amount might have absorbed systemically.     

Formulation,in vitro evaluation and kinetic analysis of chitosan–gelatin bilayer muco-adhesive buccal patches of insulin nanoparticles

The present study was performed to optimise the formulation of a muco-adhesive buccal patch for insulin nanoparticles (NPs) delivery. Insulin NPs were synthesised by an ionic gelation technique using N-di methyl ethyl chitosan cysteine (DMEC-Cys) as permeation enhancer biopolymer, tripolyphosphate (TPP) and insulin. Buccal patches were developed by solvent-casting technique using chitosan and gelatine as muco-adhesive polymers. Optimised patches were embedded with 3?mg of insulin-loaded NPs with a homogeneous distribution of NPs in the muco-adhesive matrix, which displayed adequate physico-mechanical properties. The drug release characteristics, release mechanism and kinetics were investigated. Data fitting to Peppas equation with a correlation coefficient indicated that the mechanism of drug release followed an anomalous transport that means drug release was afforded through drug diffusion along with polymer erosion. In vitro drug release, release kinetics, physical and mechanical studies for all patch formulations reflected the ideal characteristics of this buccal patch for the delivery of insulin NPs.     

Physicochemical characterization and evaluation of buccal adhesive patches containing propranolol hydrochloride

Buccal adhesive patches containing 20 mg of propranolol hydrochloride were prepared using solvent casting method. Chitosan was used as a natural bioadhesive polymer. Patches were prepared at different ratios of PVP K-30 and evaluated for various physicochemical characteristics such as weight variation, drug content uniformity, folding endurance, surface pH, ex-vivo mucoadhesive strength, ex-vivo residence time, in vitro drug release and in vitro buccal permeation study. Patches exhibited sustained release over a period of 7 hours. The mechanism of drug release was found to be Non-Fickian diffusion. Addition of PVP K-30 generally enhanced the releasing rate. The ex-vivo mucoadhesive strength was performed using sheep buccal mucosa on modified physical balance. Optimized patches (batch F4) showed satisfactory bioadhesive strength (9.6 degrees 2.0 gram) and ex vivo residence time (272 degrees 0.25 minutes). Swelling index was proportional to PVP K-30. The surface pH of all batches was within satisfactory limit (7.0+/-1.5) and hence patches would not cause irritation in the buccal cavity. Good correlation was observed between in vitro drug release and in vitro drug permeation with correlation coefficient of 0.9364. Stability of optimized patches was performed in natural human saliva showed that both drug and dosage forms were stable in human saliva.     

Glibenclamide transdermal patches: physicochemical, pharmacodynamic, and pharmacokinetic evaluations

In the present study, matrix type transdermal patches containing glibenclamide were prepared using different ratios of ethyl cellulose (EC)/polyvinylpyrrolidone (PVP) and Eudragit RL-100 (ERL)/Eudragit RS-100 (ERS) by solvent evaporation technique. The possible drug and polymer interaction was studied by infrared spectroscopy, differential scanning calorimetry, and HPTLC analysis. All the prepared formulations were subjected to physicochemical studies (thickness, weight variation, drug content, moisture content and uptake, and flatness), in vitro release and in vitro permeation studies through mouse skin. The results suggested that there was no interaction between drug and polymers. Variations in drug release/permeation profiles among the formulations studied were observed. The microphotographs obtained by scanning electron microscopy showed the formation of pores on the surface of the patches after in vitro skin permeation studies. Based on physicochemical and in vitro skin permeation studies, the formulations with EC:PVP (3:2) and ERL:ERS (4:1) were selected for in vivo experiments. The hypoglycemic activity of the patches in comparison with oral glibenclamide administration was studied for acute (24 h) and long-term (6 weeks) effect in both normal and streptozotocin-induced diabetic mice. Various biochemical parameters (serum levels of high-density lipoprotein-cholesterol, triglycerides, total cholesterol, alanine transaminase, aspertate transaminase, urea, and creatinine and liver protein and glycogen content) and histopathological (liver, pancreas and stomach) studies were carried out in diabetic mice after treating for 6 weeks. The patches were subjected to skin irritation test (by both visual observation and histopathological evaluation), oral glucose tolerance test and pharmacokinetic evaluation in mice. The results revealed that the patches successfully prevented the severe hypoglycemia in the initial hours, which is the major side effect associated with oral route. The patches maintained similar effect during long-term treatment also. The transdermal systems produced better improvement with all the tested biochemical parameters compared to oral administration. They produced improved repair of the tissues after diabetes induced tissue injury and exhibited negligible skin irritation. The pharmacokinetic evaluation showed that the patches could maintain almost steady-state concentration of drug within the pharmacologically effective range for prolonged period of time. The better in vivo performance of the transdermal patches of glibenclamide in comparison with oral administration could be due to day-to-day glycemic control on long-term application.     

Development and evaluation of mucoadhesive buccal patches of flurbiprofen

In the present study, an attempt was made to formulate mucoadhesive buccal patches of flurbiprofen (FBN) in order to enhance solubility. Solubity enhancement was attempted by making solid dispersion of drug with beta-CD (cyclodextrin). Initially preformulation were carried out using reported methods. Buccal patches were prepared by solvent casting technique using polymers like polyvinyl alcohol (PVA), sodium carboxymethyl cellulose (SCMC), and hydroxypropyl methylcellulose (HPMC). The prepared patches were evaluated for their weight variation, thickness, folding endurance, surface pH, swelling index, in vitro residence time, in vitro permeation studies, drug content uniformity and bioadhesion test.     

Eudraginated polymer blends: a potential oral controlled drug delivery system for theophylline

Sustained release (SR) dosage forms enable prolonged and continuous deposition of the drug in the gastrointestinal (GI) tract and improve the bioavailability of medications characterized by a narrow absorption window. In this study, a new strategy is proposed for the development of SR dosage forms for theophylline (TPH). Design of the delivery system was based on a sustained release formulation, with a modified coating technique and swelling features aimed to extend the release time of the drug. Different polymers, such as Carbopol 71G (CP), sodium carboxymethylcellulose (SCMC), ethylcellulose (EC) and their combinations were tried. Prepared matrix tablets were coated with a 5 % (m/m) dispersion of Eudragit (EUD) in order to get the desired sustained release profile over a period of 24 h. Various formulations were evaluated for micromeritic properties, drug concentration and in vitro drug release. It was found that the in vitro drug release rate decreased with increasing the amount of polymer. Coating with EUD resulted in a significant lag phase in the first two hours of dissolution in the acidic pH of simulated gastric fluid (SGF) due to decreased water uptake, and hence decreased driving force for drug release. Release became faster in the alkaline pH of simulated intestinal fluid (SIF) owing to increased solubility of both the coating and matrixing agents. The optimized formulation was subjected to in vivo studies in rabbits and the pharmacokinetic parameters of developed formulations were compared with the commercial (Asmanyl(?)) formulation. Asmanyl(?) tablets showed faster absorption (t(max) 4.0 h) compared to the TPH formulation showing a t(max) value of 8.0 h. The C(max) and AUC values of TPH formulation were significantly (p < 0.05) higher than those for Asmanyl(?), revealing relative bioavailability of about 136.93 %. Our study demonstrated the potential usefulness of eudraginated polymers for the oral delivery of the sparingly soluble drug theophylline.     

Synthesis of Conjugated Chitosan and its Effect on Drug Permeation from Transdermal Patches

The aim of this study was to synthesis the conjugated chitosan by covalent attachment of thiol moieties to the cationic polymer, mediated by a carbodiimide to improve permeation properties of chitosan. Thioglycolic acid was covalently attached to chitosan by the formation of amide bonds between the primary amino groups of the polymer and the carboxylic acid groups of thioglycolic acid. Hence, these polymers are called as thiomers or thiolated polymers. Conjugation of chitosan was confirmed by Fourier transform-infrared and differential scanning calorimetric analysis. Matrix type transdermal patches of carvedilol were prepared using the different proportions of chitosan and chitosan-thioglycolic acid conjugates (2:0, 1.7:0.3, 1.4:0.6, 1:1, 0.6:1.4 and 0.3:1.7) by solvent casting technique. Prepared matrix type patches were evaluated for their physicochemical characterization followed by in vitro evaluation. Selected formulations were subjected for their ex vivo studies on Wistar albino rat skin and human cadaver skin using the modified Franz diffusion cell. As the proportion of conjugated chitosan increased, the transdermal patches showed increased drug permeation. The mechanism of drug release was found to be nonFickian profiles. The present study concludes that the transdermal patches of carvedilol using conjugated chitosan with different proportions of chitosan were successfully developed to provide improved drug permeation. The transdermal patches can be a good approach to improve drug bioavailability by bypassing the extensive hepatic first-pass metabolism of the drug.