Tailoring the properties of chitosan by grafting with 2-mercaptobenzoic acid to improve mucoadhesion: in silico studies, synthesis and characterization.

Mucoadhesive polymers improve oral bioavailability of drugs by prolonging the duration of adhesion of drugs with mucosa. Various methods could be employed to address the problems of mucoadhesive polymers like weak adhesion forces. Chemical modification of polymers, such as the addition of a thiol group or thiolation, is another way for improving the polymers' mucoadhesive properties that is studied in present research work. A novel thiomer of chitosan was prepared by attaching 2-mercaptobenzoic acid, a hydrophobic ligand onto it. The docking of thiomer and chitosan with mucin structure showed higher binding energy for former. The prepared thiomer was subjected to X-ray diffraction and DSC which established reduction in crystallinity and formation of a new compound through changes in glass transition, melting point and change in diffraction pattern. The NMR studies established conjugation of 2-mercapto benzoic acid to chitosan. The increased mucoadhesion in thiomer behaviour (2-3 fold) was confirmed through mucus glycoprotein assay as well as through texture analysis. The permeation enhancing the property of thiomer was established by demonstrating the permeation of phenol red across thiomer treated intestinal membrane. An in vitro cell toxicity assay was done to establish toxicity of chitosan and thiolated chitosan. Finally, the reduced water uptake of thiomer over chitosan proved that the increase in mucoadhesion is not contributed by swelling. Thus, a thiomer with improved mucoadhesion and enhanced permeation properties was prepared and characterized. Hence, all these properties render the newly synthesized polymer a better alternative to chitosan as an excipient for mucoadhesive drug delivery systems.

Molecular Docking in Formulation and Development.

BACKGROUND: In pharmaceutical research drug discovery and development process is timeconsuming and expensive. In many cases, it produces incompetent results due to the failure of in vitro and in vivo conventional approaches. Before any new drug is placed in the market it must undergo rigorous testing to get FDA approval. Due to the several limitations imposed by the drug discovery process, in recent times in silico approaches are widely applied in this field. The purpose of this review is to highlight the current molecular docking strategies used in drug discovery and to explore various advances in the field. METHODS: In this review we have compiled database after an extensive literature search on docking studies which has found its applications relevant to the field of formulation and development. The papers retrieved were further screened to appraise the quality of work. In depth strategic analysis was carried out to confirm the credibility of the findings. RESULTS: The papers included in this review highlight the promising role of docking studies to overcome the challenges in formulation and development by emphasizing it's applications to predict drug excipient interactions which in turn assist to increase protein stability; to determine enzyme peptide interactions which maybe further used in drug development studies; to determine the most stable drug inclusion complex; to analyze structure at molecular level that ascertain an increase in solubility, dissolution and in turn the bioavailability of the drug; to design a dosage form that amplify the drug discovery and development process. CONCLUSION: This review summarizes recent findings of critical role played by molecular docking in the process of drug discovery and development. The application of docking approach will assist to design a dosage form in the most cost effective and time saving manner.

Improvement of Oral Bioavailability of Lopinavir Without Co-administration of Ritonavir Using Microspheres of Thiolated Xyloglucan.

Lopinavir is a BCS Class IV drug exhibiting poor bioavailability due to P-gp efflux and limited permeation. The aim of this research was to formulate and characterize microspheres of lopinavir using thiolated xyloglucan (TH-MPs) as carrier to improve its oral bioavailability without co-administration of ritonavir. Thiomeric microspheres were prepared by ionotropic gelation between alginic acid and calcium ions. Interaction studies were performed using Fourier transform infrared spectroscopy (FT-IR). The thiomeric microspheres were characterized for its entrapment efficiency, T80, surface morphology, and mucoadhesion employing in vitro wash off test. The microspheres were optimized by 32 factorial design. The optimized thiomeric microsphere formulation revealed 93.12% entrapment efficiency, time for 80% drug release (T80) of 358.1 min, and 88% mucoadhesion after 1 h. The permeation of lopinavir from microspheres was enhanced 3.15 times as determined by ex vivo study using everted chick intestine and increased relative bioavailability over 3.22-fold over combination of lopinavir and ritonavir as determined by in vivo study in rat model.

Formulation of piperine solid lipid nanoparticles (SLN) for treatment of rheumatoid arthritis.

The purpose of this work was to formulate piperine solid lipid nanoparticle (SLN) dispersion to exploit its efficacy orally and topically. Piperine SLN were prepared by melt emulsification method and formula was optimized by the application of 32 factorial design. The nanoparticulate dispersion was evaluated for particle size, entrapment efficiency and zeta potential (ZP). Optimized batch (128.80 nm average size, 78.71% entrapment efficiency and -23.34 mV zeta potential) was characterized for differential scanning calorimetry (DSC), X-ray diffraction which revealed amorphous nature of piperine in SLN. The prepared SLN were administered orally and topically to CFA-induced arthritic rats. Ex vivo study using Franz diffusion cell indicate that piperine from SLN gel formulation accumulates in the skin. Pharmacodynamic study result indicates both the topical and oral piperine evoked a significant response compared to orally administered chloroquine suspension. The results of ELISA show significant reduction in TNFα in treated rat which might be the reason behind the DMARD action of piperine SLN.

Improving oral bioavailability of acyclovir using nanoparticulates of thiolated xyloglucan.

Acyclovir a BCS class III drug exhibits poor bioavailability due to limited permeability. The intention of this research work was to formulate and characterize thiolated xyloglucan polysaccharide nanoparticles (TH-NPs) of acyclovir with the purpose of increasing its oral bioavailability. Acyclovir-loaded TH-NPs were prepared using a cross-linking agent. Interactions of formulation excipients were reconnoitered using Fourier transform infrared spectroscopy (FT-IR). The formulated nanoparticles were lyophilised by the addition of a cryoprotectant and characterized for its particle size, morphology and stability and optimized using Box Behnken Design.The optimized TH-NP formulation exhibited particle size of 474.4±2.01 and an entrapment efficiency of 81.57%. A marked enhancement in the mucoadhesion was also observed. In-vivo study in a rat model proved that relative bioavailability of acyclovir TH-NPs is ∼2.575 fold greater than that of the marketed acyclovir drug suspension.

Fabrication and efficacy evaluation of chloroquine nanoparticles in CFA-induced arthritic rats using TNF-α ELISA.

Rheumatoid arthritis (RA), a chronic systemic autoimmune disease, stimulates various immune cells especially macrophages, causing release of various proinflammatory cytokines such as TNF-α leading to persistent synovitis. Chloroquine, an anti-malarial drug inhibits the production of TNF-α, thus, halting the disease progression. The aim of the present study was fabrication, characterization and demonstration of kinetic and dynamic efficacy of chloroquine loaded solid lipid nanoparticles (CQ-SLNs) in arthritic rats and in lowering TNF-α levels. CQ-SLNs were prepared using melt homogenization method and subjected to lyophilization. The particle size, zeta potential, PDI and entrapment efficiency were found to be 113.6±0.15nm, -27.8±1.21mV, 0.125±0.03 and 93.45±0.43% respectively. Ex vivo endocytic uptake studies revealed engrossment of endocytic pathways in the uptake of SLN from intestine. Plasma drug profile upon pharmacokinetic evaluation demonstrated increased AUC, half-life and decreased elimination rate of the drug. Pharmacodynamic studies revealed reduction in the paw volume, bone erosion and cartilage destruction, the same was also reflected in histopathological studies. The TNF-α ELISA concluded that the TNF-α level was significantly reduced in the synovial fluid upon treatment with CQ-SLN, thus, leading to the conclusion that CQ-SLN could be used as a potential in reducing inflammatory TNF-α at the arthritic site and halting the disease progression.

Formulation of mucoadhesive gastric retentive drug delivery using thiolated xyloglucan.

Tamarind seed xyloglucan is a polymer reported to possess mucoadhesive property. In the present work, role of cysteine derivative of tamarind seed polysaccharide (thiomer) to enhance the mucoadhesion and its influence on drug permeation has been studied. The xyloglucan was first chemically modified to carboxymethyl derivative which was further converted to thiomer by conjugation with cysteine in presence of a coupling agent, EDAC. The matrix tablets of simvastatin prepared using thiomer demonstrated drug release retardation, increased mucoadhesion force and increased ex vivo permeation, the same were proportional to the increase in the amount of thiomer. The in vivo residence of thiomer placebo was more than 7h in rabbit. Pharmacokinetic evaluation in rabbits indicated higher AUC for the formulation with highest content of thiomer and level 'A' correlation could be established from the generated dissolution and bioavailability data.

Synthesis and characterization of a novel mucoadhesive derivative of xyloglucan.

A novel polymer in the form of a thiolated derivative of natural tamarind seed polysaccharide or xyloglucan was synthesized and its chacteristics as a mucoadhesive polymer were studied as a part of the study undertaken herein. The synthetic route followed involves a two-step reaction mechanism of firstly oxidizing xyloglucan and then further conjugating it with l-cysteine to form thiolated xyloglucan or thiomer via imine linkage. The thiomer thus formed was characterized using various analytical techniques as differential scanning calorimetry (DSC), X-ray diffraction analysis (XRD), and nuclear magnetic resonance (NMR). Ellman's method was used to determine the numbers of thiol groups/g of thiolated xyloglucan. Zeta potential measurements were carried out for thiolated xyloglucan. Viscosities of the formulated xyloglucan and thiolated xyloglucan gels were comparatively evaluated along with the evaluation of mucoadhesive properties of the gels using ex vivo bioadhesion study employing freshly excised sheep intestinal mucosa.

Sugars as solid dispersion carrier to improve solubility and dissolution of the BCS class II drug: clotrimazole.

Solid dispersion of poorly soluble BCS class II drug, clotrimazole, was prepared with the aim of enhancing its dissolution profile. Solid dispersions were prepared using various sugars as carriers at different weight ratio to drug-like d-mannitol, d-fructose, d-dextrose and d-maltose by fusion method. The solubility of plain clotrimazole in different percent of sugar solutions was measured. Also, its solubility in solid dispersion and their physical mixture were assessed. The dissolution of all the prepared SD tablets, direct compressed clotrimazole tablet and plain drug were tested using the U.S. Pharmacopeia convention (USP) apparatus II. The dissolution profiles were characterized by parameters like area under curve (AUC), mean residence time (MRT), mean dissolution time (MDT) and percent dissolution efficiency (% DE). The release kinetics study was performed using DD Solver TM software. The selected solid dispersions (SDs) were evaluated for antifungal activity. A 100% solution of mannitol showed 806-fold increases in solubility as compared with plain clotrimazole in water. It was observed that the dissolution profile of clotrimazole was improved by mannitol SD at drug to sugar ration of 1:3. The percent DE value for mannitol SD tablet was found to be 77.3516% as against plain drug and directly compressed tablet of clotrimazole at 50.9439% and 31.33%, respectively. Also the antifungal activity indicated by inhibition zone was found to be 54 mm indicating enhance activity against Candida albicans as compared with plain CTZ at 6.6 mm. Thus, it can be concluded that the sugar alcohol, that is, mannitol is a more promising hydrophilic carrier for solid dispersion preparation to improve the solubility and dissolution of poorly soluble drugs.

Design and development of SMEDDS for colon-specific drug delivery.

CONTEXT: Lipoidal systems have particularly shown potential for specific accumulation in areas with inflamed tissue increasing the selectivity of local drug delivery. OBJECTIVE: Formulation and evaluation of self-microemulsifying drug delivery system (SMEDDS) for colon-specific drug delivery for effective treatment of colonic diseases. METHOD: Ternary phase diagram was used to optimize level of oil, surfactant and co-surfactant to optimize SMEDDS and were evaluated for percent transmittance, emulsification time, in vitro release, myeloperoxidase (MPO) activity and intestinal accumulation. The spray dried SMEDDS were filled in capsules which were enteric coated with Eudragit S-100 at 10% weight gain to ensure SMEDDS delivery at colon. The spray dried SMEDDS were also evaluated for IR, DSC, XRD, SEM and stability study. RESULT: In ternary phase diagram, Capmul MCM C8 and Capmul PG12 NF with surfactant (Tween 20) and co-surfactant (PG) in ratio 2:1 and 3:1, respectively, showed maximum emulsification area. These liquid SMEDDS show maximum transmittance, globule size of 90-30 nm. The spray-dried SMEDDS with diluents show good flow property. The units of MPO activity show lower level as compared to pure drug and control group, histopathology results supports better healing with SMEDDS. This was attributed to accumulation of SMEDDS in inflammatory area as compared to drug which was further proved by accumulation study. Enteric-coated capsule containing SMEDDS are able to deliver drug, specifically at the colonic region. CONCLUSION: Higher accumulation of lipoidal drug in inflammatory area and specific release of liposomes by enteric-coated capsules provide better option for the treatment of colonic disease.

In-vivo bioavailability and lymphatic uptake evaluation of lipid nanoparticulates of darunavir.

Darunavir is effective against wild-type and PI-resistant HIV, and has an oral bioavailability of 37%. It needs to be combined with ritonavir, which increases the bioavailability to 82%. The aim of this study was to evaluate the in-vivo efficacy of the darunavir-SLN and demonstrate lymphatic transport as a contributing pathway in increasing the drug bioavailability. The SLN was prepared by hot-homogenization technique using GMS as lipid. In-vitro drug release from SLN at the 12th hour was retarded (80.6%) compared to marketed tablet (92.6%). Ex-vivo apparent permeability of the freeze-dried SLN across everted rat intestine was 24 × 10-6 at 37 °C and 5.6 × 10-6 at 4 °C. The presence of endocytic process inhibitors like chlorpromazine and nystatin reduced it to 18.8 × 10-6 and 20.2 × 10-6, respectively, which established involvement of endocytic mechanism in the uptake of SLN. In-vivo pharmacokinetic studies on rats demonstrated increase in the AUC of SLN (26) as compared to that of marketed tablet (13.22), while the presence of lymphatic uptake inhibitor cycloheximide lowered the AUC of SLN to 17.19 which further led credence to the involvement of lymphatic uptake behind improved bioavailability. The detection of darunavir in the lymphatic fluid of the rats administered with darunavir-SLN further reinforced the conclusion of SLN being taken up by the lymphatic system.

Formulation and evaluation of Adapalene-loaded nanoparticulates for epidermal localization.

Adapalene (ADP), a topically administered antiacne drug, finds limitation due to poor penetration, limited localization, and associated incompatibility of photosensitization and skin irritation. To explicate an innovative and safe method for ADP administration and alleviating the associated limitations, solid lipid nanoparticles (SLN) of ADP have been fabricated and evaluated for efficacy in the present work. The SLN were prepared using pre-emulsion sonication method and incorporated into convenient topical dosage form, hydrogels. In vitro permeation studies of the hydrogels through HCS indicated gel containing ADP-SLN showed 2-fold more accumulation in skin layers as compared to conventional ADP gel. Rheological studies demonstrated ADP-SLN gel to possess pseudoplastic behavior, occlusion and hydration studies revealed permeation effectiveness of ADP-SLN gel over conventional ADP gel while primary skin irritation studies established safety of the ADP-SLN gel upon topical application. Hence, it was concluded that the studied ADP-SLN formulation with skin localizing ability may be a promising carrier for topical delivery of ADP.

Formulation and optimisation of sustained release spray-dried microspheres of glipizide using natural polysaccharide.

The objective of this study was to investigate the combined influence of three independent variables in the preparation of glipizide microspheres by the spray-drying method. A three factor, three level Box-Behnken design was used to derive polynomial equations and construct response surface plots to predict responses. The independent variables selected were concentration of polymer (xyloglucan) (X1), amount of crosslinking agent (X2), and feed rate (X3). Fifteen batches were prepared and evaluated for percentage drug entrapment and time for 80% drug release (t80). Response surface plots were constructed to demonstrate the combined effects of factors X1, X2, and X3 on response percent entrapment. The optimal microsphere preparations displayed a percent entrapment between 96.96 and 98.11 and a t80 between 420 and 439 min. The microspheres had particle size between 3 and 6 microns, and differential scanning chromatography thermograms showed the presence of glipizide in amorphous form in microspheres. LAY ABSTRACT: Multiparticulate dosage forms are pharmaceutical formulations in which the active substance is present as number of small independent subunits. The microspheres as drug delivery systems are especially suitable for providing oral controlled release formulations with low risk of dose dumping, Microspheres can be blended suitably to attain different release patterns. Glipizide is recommended orally for treatment of type II diabetes and is administered in 2 or 3 doses of 2.5 to 10 mg per day. The development of controlled-release dosage form would offer effective control by releasing drug over period of time. The present work describes formulation of microspheres containing glipizide using the tamarind seed polysaccharide or xyloglucan as carrier. The spray-drying method was used to formulate the microspheres and variables (concentration of xyloglucan, amount of crosslinking agent, and feed rate) affecting performance parameters such as time for 80% drug release and percent drug entrapment were optimized using a statistical design (Box Behnken design). The microspheres had particle size between 3 and 6 microns, had entrapment between 97 and 99%, and sustained the drug release beyond 7 hours.

Optimization of Carboxymethyl-Xyloglucan-Based Tramadol Matrix Tablets Using Simplex Centroid Mixture Design.

The aim was to determine the release-modifying effect of carboxymethyl xyloglucan for oral drug delivery. Sustained release matrix tablets of tramadol HCl were prepared by wet granulation method using carboxymethyl xyloglucan as matrix forming polymer. HPMC K100M was used in a small amount to control the burst effect which is most commonly seen with natural hydrophilic polymers. A simplex centroid design with three independent variables and two dependent variables was employed to systematically optimize drug release profile. Carboxymethyl xyloglucan (X 1), HPMC K100M (X 2), and dicalcium phosphate (X 3) were taken as independent variables. The dependent variables selected were percent of drug release at 2nd hour (Y 1) and at 8th hour (Y 2). Response surface plots were developed, and optimum formulations were selected on the basis of desirability. The formulated tablets showed anomalous release mechanism and followed matrix drug release kinetics, resulting in regulated and complete release from the tablets within 8 to 10 hours. The polymer carboxymethyl xyloglucan and HPMC K100M had significant effect on drug release from the tablet (P > 0.05). Polynomial mathematical models, generated for various response variables using multiple regression analysis, were found to be statistically significant (P > 0.05). The statistical models developed for optimization were found to be valid.

Synthesis of MCC-PEG conjugate and its evaluation as a superdisintegrant.

PEGylated conjugate of microcrystalline cellulose (MCC) was synthesized by reacting MCC with polyethylene glycol (PEG) 200 in the presence of catalyst at elevated temperature. Conjugation between MCC and PEG was confirmed by FT-IR and (1)H NMR studies. The conjugate showed 61% PEG content increase in molecular weight determined by mass spectroscopy. PEGylation did not improve solubility of cellulose significantly. The physico-chemical properties of conjugate were compared against MCC. This conjugate was evaluated for water vapor uptake isotherms, maximum water saturation, water penetration rate, disintegration time, superdisintegration power, and dissolution study. After comparing its results with that of commercial superdisintegrants, it can be concluded that MCC-PEG conjugate can prove to be a good superdisintegrant.

Novel ion exchange resin-based combination drug-delivery system for treatment of gastro esophageal reflux diseases

The present study involves preparation and characterization of a combination tablet of ranitidine in immediate release form and domperidone in sustained release form, using ion exchange resins. Ranitidine lowers acid secretion, while domperidone release over a prolonged period improves gastric motility thus justifying this combination in gastro esophageal reflux diseases (GERD) and ensuring patient compliance. Drug loading was carried out by batch method & resinates were characterized using FTIR, XRPD. Resinates were formulated as a combination tablet and evaluated for tablet properties & in vitro drug release. Resinates provided sustained release of domperidone and immediate release of ranitidine. IR and X-ray studies indicate complexation of drug and resin along with monomolecular distribution of drugs in amorphous form in the resin matrix. The tablets of resinate combination showed good tablet properties. In-vitro drug release gave desired release profiles and ex-vivo drug absorption studies carried out by placing everted rat intestine in dissolution medium indicated statistically significant similarity in absorption from test and marketed formulation. The novelty of this study is that the retardation in release of domperidone from resinates is achieved by presence of weak resin in the formulation.

O presente estudo envolve a preparação e a caracterização de associação do comprimido de ranitidina de liberação imediata e domperidona de liberação prolongada, utilizando resinas de troca iônica. A ranitidina diminui a secreção ácida, enquanto a liberação prolongada de domperidona melhora a motilidade gástica, justificando, dessa forma, a associação em doenças de refluxo gastroesofágico (DRGE) e garantindo a adesão do paciente. A carga de fármaco foi efetuada pelo método em batelada e os resinatos, caracterizados utilizando-se FTIR e XRPD. Os resinatos foram formulados como comprimido da associação e avaliados com relação às propriedades dos comprimidos e liberação do fármaco in vitro. Os resinatos proporcionaram a liberação prolongada da domperidona e a liberação imediata da ranitidina. IV e estudos de difração de raios X indicaram a complexação do fármaco e da resina junto com a distribuição monomolecular dos fármacos, em estado amorfo, na matriz da resina. Os comprimidos da associação do resinato apresentaram boas propriedades. Obtiveram-se os perfis de liberação in vitro e os estudos de absorção dos fármacos ex vivo realizados com intestino de rato em meio de dissolução indicaram semelhança significativa na absorção entre as formulações teste e comercializada. A inovação do trabalho é que o retardamento da liberação da domperidona dos resinatos é atingido pela presença de resina fraca na formulação.

Design of potential reverse transcriptase inhibitor containing Isatin nucleus using molecular modeling studies.

Two Dimensional (2D) and Three Dimensional (3D) Quantitative Structure-Activity Relationship (QSAR) studies were performed for correlating the chemical composition of Isatin analogues and their anti-HIV activity using Multiple Linear Regression (MLR) Analysis and k Nearest Neighbor Molecular Field Analysis (kNN MFA), respectively. New Chemical Entities (NCEs) were designed using results of QSAR studies. Binding affinities of designed NCEs were studied on Reverse Transcriptase enzyme using docking studies and their ADME properties were also predicted. Finally most promising compounds were selected from molecular modeling studies. Five compounds containing Isatin nucleus were synthesized and tested for their anti-HIV activity by performing Reverse Transcriptase Assay. Three compounds showed significant Reverse Transcriptase inhibiting activity compared to standard Navirapine. Structure-Activity Relationships were also discussed bases on obtained molecular modeling and experimental data.

In vitro and in vivo studies on chitosan beads of losartan Duolite AP143 complex, optimized by using statistical experimental design.

The aim of the present research work was to develop release modulated beads of losartan potassium complexed with anion exchange resin, Duolite AP143 (cholestyramine). Chitosan was selected as a hydrophilic polymer for the formation of beads which could sustain the release of the drug up to 12 h, along with drug resin complex (DRC). Chitosan beads were prepared using an in-liquid curing method by ionotropic cross-linking or interpolymer linkage with sodium tripolyphosphate (TPP). The formulation of the beads was optimized for entrapment efficiency and drug release using 3(2) full factorial design. The independent variables selected were DRC/chitosan and percent of TPP. The optimization model was validated for its performance characteristics. Studies revealed that as the concentration of chitosan and TPP was increased, entrapment efficiency and the drug release were found to increase and decrease, respectively. The swelling capacity of chitosan-TPP beads decreased with increasing concentration of TPP. The effect of chitosan concentration and percentage of TPP solution used for cross-linking on entrapment efficiency and drug release rate was extensively investigated. Optimized beads were subjected to in vivo studies in Wistar albino rats to determine the mean arterial blood pressure and compared with marketed formulation. The pharmacodynamic study demonstrates steady blood pressure control for optimized formulation as compared to fluctuated blood pressure for the marketed formulation.

Formulation design and optimization of novel taste masked mouth-dissolving tablets of tramadol having adequate mechanical strength.

The purpose of this work was to develop novel taste masked mouth-dissolving tablets of tramadol that overcomes principle drawback of such formulation which is inadequate mechanical strength. Tramadol is an opioid analgesic used for the treatment of moderate to severe pain. Mouth-dissolving tablets offer substantial advantages like rapid onset of action, beneficial for patients having difficulties in swallowing and in conditions where access to water is difficult. The crucial aspect in the formulation of mouth-dissolving tablets is to mask the bitter taste and to minimize the disintegration time while maintaining a good mechanical strength of the tablet. Mouth-dissolving tablets of tramadol are not yet reported in the literature because of its extreme bitter taste. In this work, the bitter taste of Tramadol HCl was masked by forming a complex with an ion exchange resin Tulsion335. The novel combination of a superdisintegrant and a binder that melts near the body temperature was used to formulate mechanically strong tablets that showed fast disintegration. A 3(2) full factorial design and statistical models were applied to optimize the effect of two factors, i.e., superdisintegrant (crospovidone) and a mouth-melting binder (Gelucire 39/01). It was observed that the responses, i.e., disintegration time and percent friability were affected by both the factors. The statistical models were validated and can be successfully used to prepare optimized taste masked mouth-dissolving tablets of Tramadol HCl with adequate mechanical strength and rapid disintegration.

Preparation and evaluation of miconazole nitrate-loaded solid lipid nanoparticles for topical delivery.

The purpose of this study was to prepare miconazole nitrate (MN) loaded solid lipid nanoparticles (MN-SLN) effective for topical delivery of miconazole nitrate. Compritol 888 ATO as lipid, propylene glycol (PG) to increase drug solubility in lipid, tween 80, and glyceryl monostearate were used as the surfactants to stabilize SLN dispersion in the SLN preparation using hot homogenization method. SLN dispersions exhibited average size between 244 and 766 nm. All the dispersions had high entrapment efficiency ranging from 80% to 100%. The MN-SLN dispersion which showed good stability for a period of 1 month was selected. This MN-SLN was characterized for particle size, entrapment efficiency, and X-ray diffraction. The penetration of miconazole nitrate from the gel formulated using selected MN-SLN dispersion as into cadaver skins was evaluated ex-vivo using franz diffusion cell. The results of differential scanning calorimetry (DSC) showed that MN was dispersed in SLN in an amorphous state. The MN-SLN formulations could significantly increase the accumulative uptake of MN in skin over the marketed gel and showed a significantly enhanced skin targeting effect. These results indicate that the studied MN-SLN formulation with skin targeting may be a promising carrier for topical delivery of miconazole nitrate.