Temperature-dependent mucosal permeation kinetics of stigmasterol microspheres: In vivo mice model antioral candidiasis study.

Evaluation of mucosal permeation of stigmasterol from the glutaraldehyde cross linked chitosan microspheres at increasing experimental temperatures was performed. The activation energy of permeation, partition, and diffusion were estimated to understand the permeation kinetic with respect to the temperature. The formulation depicting least activation energy possessed the increased permeation thresholds of drug at the site of application. The encapsulation efficacy and mucoadhesive strength were found to be directly proportional to the polymer-emulsifier ratio. Decreased intensity in crystallography directed the molecular dispersion of microencapsulated drug. The depleted enthalpic phase transition in thermogram affirmed the stigmasterol encapsulation. The sphericity and the size of microspheres were determined by scanning electron photo micrograph. The in vivo quantification of oral Candida infection with different statistical approach and histopathological observation of infected tongue of mice on treatment with the stigmasterol encapsulated microspheres showed significant anti oral candidiasis activity by reduction of fungal colony count and recovery of papillae, reorganization of basal cell layer and newly formed papillae during 21-28 days of treatment.

Drug-in-mucoadhesive type film for ocular anti-inflammatory potential of amlodipine: Effect of sulphobutyl-ether-beta-cyclodextrin on permeation and molecular docking characterization.

Mucoadhesive type ocular film has been prepared for studying the anti-inflammatory potential of amlodipine (AML) on carrageenan-induced rabbit model and the effect of sulphobutyl-ether-beta-cyclodextrin on corneal permeation was tested. Hydroxypropyl methylcellulose (HPMC) ocular film was prepared after complexation of amlodipine with ß-cyclodextrin, (BCD), hydroxypropyl ß-cyclodextrin (HPCD), and sulfobutylether ß-cyclodextrin (SBCD). The film without cyclodextrin showed a maximum swelling, and erosion to the highest extent. Both drug release and permeation were highly diffusion controlled and highest improvement was observed with SBCD due to increased dissolution, compared to other formulations with or without cyclodextrin. Highest binding energy and highest extent of amorphization were noticed in the SBCD film formulation. Improved amlodipine release in-vitro and ocular permeation were found by the HPMC film formulation after complexation of the drug with cyclodextrins wherein SBCD exhibited both to the highest extent. Binary and ternary systems molecular docking studies confirmed the lowest energy of binding between amlodipine and BCD compared to HBCD and SBCD. Signs of acute inflammation were mitigated within 2 h of film application in the cul-de-sac. Presence of sulphobutyl-ether ß-cyclodextrin in the amlodipine-HPMC film can improve ocular permeation significantly and could be utilized as mucoadhesive type formulation for anti-inflammatory activity.

Ocular Permeation and Sustained Anti-inflammatory Activity of Dexamethasone from Kaolin Nanodispersion Hydrogel System.

PURPOSE: Kaolin can adhere to the mucosa and protect it by absorbing toxins, bacteria, and viruses. Ocular delivery and anti-inflammatory activity of dexamethasone hydrogel system could be advantageous after kaolin incorporation. METHODS: Hydroxypropyl methylcellulose (HPMC) films of dexamethasone have been prepared without and with kaolin by solvent casting method. Differential scanning calorimetry (DSC), X-ray diffractometry (XRD), and scanning electron microscopy (SEM) were utilized for evaluating thermal property, crystallinity, and morphology of the film preparations respectively. In vitro drug release and corneal permeation ex vivo were carried out in phosphate buffer saline of pH 7.4 (PBS) at 34 ± 0.5°C for 6 h. Anti inflammatory effect of the prepared film was evaluated using carrageenan induced rabbit eye. RESULTS: Disappearance of melting endotherm in the DSC thermogram is the indication of almost complete amorphization of drug in all the films. High-intensity reflections with characteristic peaks of pure drug crystal have resulted extensively reduced ordering of the crystal lattice in the X-ray pattern of all the films. Photomicrographs revealed that the plate-shaped geometry of the drug crystal has almost been lost in absence and presence of the nano-kaolin particles in the films. Kaolin incorporation controlled the drug release up to 6 h. Ocular permeation was diffusion controlled and extended for 6 h or more without exhibiting significant "Burst effect". Adsorption of drug onto the surface of nano-kaolin prolonged the permeation due to cation exchange and hydrogen bonding. Signs of inflammation of the carrageenan induced rabbit eye have been disappeared almost completely after 2 h of film application. CONCLUSIONS: Local controlled delivery sustained anti-inflammatory activity of dexamethasone has been achieved using kaolin incorporated HPMC film.

Transcorneal permeation of diclofenac as a function of temperature from film formulation in presence of triethanolamine and benzalkonium chloride.

The objective of this report was to evaluate the transcorneal permeation of diclofenac potassium (DCP) as a function of temperature from hydroxypropyl methylcellulose (HPMC) matrix film containing triethanolamine (TEM) as plasticizer and benzalkonium chloride (BKC) as preservative. Activation energy (Ea), enthalpy (ΔH), entropy (ΔS) and free energy (ΔG) of permeation, diffusion and partition were evaluated to understand the underlying mechanism of permeation. Permeation improved with the presence of both the plasticizer and preservative compared to preservative alone. Further, increased amount of TEM in the film increased drug transport across the cornea. Decreased Ea value of the film supported the fact. Rise of temperature from 26 to 30, 34 and 40 °C increased permeation in all the films. Ocular residence of the film in vivo in the rabbit revealed that the film swelled by pronounced lachrymal fluid uptake and traces of hydrogel remained still at the end of 6 h of application. Absence of characteristic exothermic peak of the drug in the thermogram of film formulations indicated the molecular dispersion of drug in polymer matrix. Scanning electron microscopy indicated that the drug crystal size decreased with increasing concentration of TEM in presence of BKC due to effective wetting of drug particles by the polymer.

Effects of microcrystalline cellulose based comilled powder on the compression and dissolution of ibuprofen.

Ibuprofen is a poorly soluble and poorly compressible drug and is unsuitable for "direct tableting". Microcrystalline cellulose (Avicel(®) PH 101) based ibuprofen powder formulations have been comilled in presence of Aerosil(®) (colloidal silicon dioxide) as lubricant, and the total compression behavior was evaluated using the Cooper-Eaton equation. Scanning electron microscopy (SEM) revealed about the damage of crystal geometry of the crystalline drug after comilling. Differential scanning calorimetry (DSC) indicated decrease of melting endotherm (partially) attributing to the decrease in crystalline intensity of ibuprofen upon comilling. Small changes in the infrared spectra such as shift of characteristic bands, reduction in intensity, and appearance of new bands are mainly related to the possible physical interaction and/or amorphization of the drug in the comilled mixtures. Increased compaction can be achieved after milling of the microcrystalline cellulose based blends. Milling decreased particle size and improved wettability of the drug and increased dissolution. Microcrystalline cellulose based comilled ibuprofen powder with improved compression and dissolution may be taken as a future scope of scale up for "direct tableting".

Study of particle rearrangement, compression behavior and dissolution properties after melt dispersion of ibuprofen, Avicel and Aerosil.

Particle rearrangements, compaction under pressure and in vitro dissolution have been evaluated after melt dispersion of ibuprofen, Avicel and Aerosil. The Cooper-Eaton and Kuno equations were utilized for the determination of particle rearrangement and compression behavior from tap density and compact data. Particle rearrangement could be divided into two stages as primary and secondary rearrangement. Transitional tapping between the stages was found to be 20-25 taps in ibuprofen crystalline powder, which was increased up to 45 taps with all formulated powders. Compaction in the rearrangement stages was increased in all the formulations with respect to pure ibuprofen. Significantly increased compaction of ibuprofen under pressure can be achieved using Avicel by melt dispersion technique, which could be beneficial in ibuprofen tablet manufacturing by direct compression. SEM, FTIR and DSC have been utilized for physicochemical characterization of the melt dispersion powder materials. Dissolution of ibuprofen from compacted tablet of physical mixture and melt dispersion particles has also been improved greatly in the following order: Ibc