Intranasal administration of innovative triamcinolone acetonide encapsulated cubosomal in situ gel: formulation and characterization.

AIM: The primary objective of the research was to develop a cubosomal in situ gel encapsulated with Triamcinolone acetonide (TCA) in order to enhance its penetration through the blood-brain barrier (BBB) when administered via the intranasal route, thus enabling efficient and rapid action. METHOD: Cubosomes were formulated by top-down approach using glyceryl monooleate (GMO), using pluronics127 (PF127) and polyvinyl alcohol (PVA) in varying proportions based on the Box-Behnken design. High resolution transmission electron microscopy (HR-TEM) analysis confirmed the morphology of the cubosomes. The in situ gel was formulated and optimized. Experiments involving ex vivo permeation and histopathology analyses were undertaken to evaluate drug permeation and tissue effects. RESULTS: The cubosomes exhibited a particle size (PS) of 197.9 nm, zeta potential (ZP) of -31.11 mV, and entrapment efficacy (EE) of 84.31%, with low deviation. Batch F4 (19% PF127) showed favorable results. In vitro and ex vivo permeation studies revealed drug release of 78.59% and 76.65%, respectively, after 8 h. Drug release followed the Hixson Crowell model of release kinetics. The histopathological examination revealed no signs of toxicity or adverse effects on the nasal mucosa of the sheep. The formulation exhibited short-term stability, maintaining its integrity and properties when stored at room temperature. CONCLUSION: The utilization of an intranasal cubosomal in situ gel encapsulated with TCA was anticipated to lower intracranial pressure and improve patient adherence by offering effective relief for individuals suffering from Brain edema. This efficacy is attributed to its rapid onset of action and its safe and well-tolerated dosage form.

Exploring magnesium myristate for its dual functionality as a binder and lubricant in the formulation of tablet.

Purpose: To explore 'magnesium myristate' for its dual functionality as a lubricant and binder in the formulation of tablets. Methods: Using (DoE), tablet formulations using magnesium myristate and conventional excipients (magnesium stearate and PVP K30) were developed by wet granulation technique. The prepared granules and formulated tablets were evaluated for pre- and post-compression parameters, respectively. Results: Magnesium myristate exhibited excellent flow properties. The optimized formulations containing magnesium myristate exhibited increased hardness and in vitro drug release in comparison to conventional excipients. f2 similarity index for in vitro drug release showed no significant variations with optimized formulations and with the marketed formulations. Conclusion: Magnesium myristate shows a promising replacement for conventional excipients as both a lubricant and binder in tablet formulation.

Formulation and evaluation of itraconazole-loaded nanoemulgel for efficient topical delivery to treat fungal infections.

Aim: The clinical application of conventional oral dosage form of itraconazole is limited due to its poor bioavailability. The aim of the study was to develop nanoemulgel of Itraconazole for topical delivery. Method: Nanoemulsions were prepared, optimized and further incorporated into a gel and evaluated for homogeneity, pH, viscosity, spreadability, in vitro drug release and skin irritation studies. Results: Cumulative drug release from nanoemulsions was within the range of 37.24 to 47.63% at 10 h. Drug release % for all the nanoemulgel formulations at10 h was 32.39, 39.75 and 45.9% respectively. Nanoemulgel was non-irritant as demonstrated by skin irritation studies in animals. Conclusion: Itraconazole nanoemulgels were proved to be potential for effective topical delivery of drug with enhanced bioavailability.

Fabrication, Optimization, and Evaluation of Transdermal Patch: As an Alternative and Effective Transdermal Delivery System for Nebivolol HCl.

BACKGROUND: Nebivolol HCl is a unique third-generation beta blocker that has less oral bioavailability and exhibits various adverse effects like gastrointestinal disturbance and abdominal pain. OBJECTIVE: This study aimed to formulate and evaluate nebivolol HCl transferosomal transdermal patches to reduce the problems associated with oral delivery of the drug and enhancement of drug permeation through the skin. METHODS: Nebivolol HCl loaded transferosomes were prepared by thin film hydration method. Eight formulations were prepared based on the two independent variables, type of surfactant (Tween 80 and Span 80) and Phospholipid: Edge activator ratio and were evaluated for their vesicle size, PDI, and entrapment efficiency. The optimized formulations were incorporated into transdermal patches, which were evaluated for physicochemical properties, in-vitro and ex-vivo permeation, skin irritancy, and stability studies. RESULTS: The vesicle size of the transferosomes ranged from 49nm to 93nm, and EE% varied from 39% to 79%. Vesicles formed with Span 80 as an edge activator showed smaller vesicle size and greater EE% as compared to Tween 80. Based on the results, TW4 and SP4 were selected as the optimized formulations for further incorporation into the transdermal patches. In-vitro and ex-vivo permeation studies showed permeation in the order F2 > F3 > F1, indicating that transferosomal formulations showed superior permeation of the drug compared to plain Nebivolol HCl patches. Span 80 transferosomes showed a slightly better permeation than Tween 80. Stability studies showed that transferosomes and the transdermal patches demonstrated good stability under proper storage conditions. CONCLUSION: The study concluded that transferosomal patches of Nebivolol HCl could be used as a potential approach with effective transdermal delivery for the management of hypertension.

A comprehensive review on pharmaceutical excipients.

The effectiveness of pharmaceutical drugs depends not only on their active components and manufacturing processes, but also on the role played by pharmaceutical excipients. The traditional definition of excipients as inactive and cost-effective substances has evolved significantly. They are now recognized as essential elements of drug formulations, constituting 80-90% of the final product. The rapid advancements in delivery systems, along with scientific, regulatory, financial and technological developments in biopharmaceutics, have generated renewed interest in the use and functionality of excipients, especially in solid dosage forms. This review focuses on the categorization of excipients according to the International Pharmaceutical Excipient Council (IPEC) and the establishment of guidelines for evaluating the safety of a new proposed excipient.

Excipients are matter we add to medicine when we make it. They give the medicine different qualities, like making it easier to dissolve, stick together, or slide smoothly. But if we use too many excipients, it can make the medicine less stable and more expensive. To avoid these problems, we can use special excipients that can do more than one thing. These multi-purpose excipients make the medicine work better, stay stable and cost less.

In situ gastric floating gel of atazanavir sulphate for sustained release: formulation, optimization and evaluation.

Aim: Atazanavir sulphate belongs to BCS class II drug, its oral bioavailability is limited due to its rapid first-pass metabolism and P-gp efflux. Materials & methods: The in situ floating gel using the complexed drug was prepared by ion gelation method and optimized the formulation as per 32 full factorial design. Results: Floating lag time of optimized formulation was found to be 18 s and percentage drug release of 94.18 ± 0.18 % at the end of 16 h. The concentration of gelling polymer affects drug release and a floating lag time and vice versa. Conclusion: In situ floating gel of atazanavir sulphate was found promising to sustain drug release due to an increased gastric residence time, which leads to enhanced potential therapy.

In our study, we wanted to create a gel for a medicine called atazanavir sulphate. This gel can float in the stomach for a long time and slowly release the medicine. We mixed atazanavir sulphate with something called ß-cyclodextrin, and this mixture made the medicine dissolve better in water. We used this mixture to make our floating gel, which can stay in the stomach without sinking. Our gel can make the medicine work better because it dissolves well and stays in the stomach for a long time. This means the medicine can help people for a longer period.

Current Novel Drug Deliveries for Oral Cancer: A Chronotherapeutic Approach.

Oral squamous cell carcinoma is a malignant disease that is causing considerable mortality worldwide. Conventional treatment approaches, like surgery, cause destructive alterations in facial appearance and oral function impairments associated with psychological and social functioning. Chemotherapy exhibits low bioaccessibility of the anticancer drugs, multiple drug resistance, higher dose necessities, which elevate toxicities to the normal cells, low therapeutic index, and non-specific targeting. Radiation therapies significantly affect the well-being of the patient and impair the quality of life. Therefore, chemotherapeutics are developed that can either actively or passively target the carcinomas, reduce the adverse side effect, and improve therapeutic efficacy. Innovations in novel drug delivery systems deliver the drugs to the desired site of action with better treatment approaches with reduced toxicities to the normal cells and improve the health and survival rate of the patient. Cancer chronotherapy enhances the treatment proficiency by administration of the drugs at the best time, considering biological timings to improve the treatment profiles. Chronotherapy provides benefits to the current anticancer therapies, with minimum adverse effects to the healthy cells. This review discusses the risk factors for oral carcinomas, targeted therapy by nanocarriers, nanotechnology approaches, the role of circadian rhythm in the management of oral cancer, and advances in controlled drug delivery.

Formulation, optimization and validation of floating oral in situ gel of Ivabradine hydrochloride.

Aim: Ivabradine hydrochloride is a hyperpolarized activated channel blocker used for symptomatic treatment of chronic angina pectoris. However, due to its short half-life it is rapidly eliminated from systemic circulation. Materials & methods: Floating in situ gel was formulated using sodium alginate and HPMC K 100 M by pH induced ion gelation technique employing 32 factorial design for optimization and evaluated. Results: The in situ formulation remained buoyant in gastric environment for 12 h. Optimized formulation sustained and prolonged drug release in comparison with marketed product. Kinetic analysis of drug release indicated non fickian mechanism. Short term stability studies showed no significant changes indicating good formulation stability. Conclusion: Formulated in situ solution shows potential effective sustained release over a prolonged period of time.

Nanostructured lipid carrier-incorporated gel for efficient topical delivery of fluconazole.

Background: Nanostructured lipid carriers (NLCs) of fluconazole were prepared to improve permeability and thereby effective topical drug delivery. Materials and methods: NLCs were prepared and evaluated, and then the optimized NLC suspension was incorporated into a gel that was further evaluated for topical drug delivery. Results and discussion: F-2 NLC formulation was optimized based on results of particle size (161.3 ± 1.385 nm), polydispersity index (0.401), zeta potential (-33 ± 0.46), entrapment efficiency (82.26 ± 0.91%) and in vitro drug release (76.40 ± 0.21%). Ex vivo skin permeation studies showed flux of F-2 gel and the comparison marketed gel as 0.21 and 0.18 mg/cm2/h, respectively. The in vitro antifungal study revealed significantly better activity compared with the marketed gel. Conclusion: Fluconazole NLCs increase drug permeability and proved to be effective in topical drug delivery.

Exploring the Solvent-Anti-solvent Method of Nanosuspension for Enhanced Oral Bioavailability of Lovastatin

Objectives: Lovastatin is an antilipidemic drug that belongs to the class of statins that has poor oral bioavailability due to its low solubility and variable dissolution rate. The main aim of this study was to enhance the solubility and dissolution rate of the drug and understand its oral bioavailability. Materials and Methods: Lovastatin nanosuspension was formulated using a solventanti-solvent method using a probe sonication technique. A nanosuspension was prepared, using hydroxypropyl methylcellulose (HPMC) K15M and pluronic F68 as stabilizers. The formulated nanosuspensions were characterized for particle size, polydispersity index (PDI) zeta potential, surface morphology, and in vitro release rate. Further, an in vivo bioavailability study and stability studies were also performed. Results: Optimized formulation showed a particle size of 127±0.01 nm, a PDI of 0.492±0.001, and a zeta potential of -37.9 mV, which indicates good stability. Morphological study showed that the particles were in the nano range. The drug content was found to be in the range of 73-87%. In vitro release revealed much faster release of the drug in one hour compared to the pure drug and its marketed formulation. In vivo bioavailability study was carried out in Wistar rats, which showed improvement in bioavailability by approximately 2.5 folds compared with the marketed formulation. Stability studies indicated that the optimized formulation F2 was more stable at 4°C±2°C. Conclusion: The prepared lovastatin nanosuspension showed improvement in solubility, dissolution rate, and oral bioavailability compared to the pure drug and its marketed formulation. Hence, lovastatin nanosuspension may be a potentially valuable tool for improving the oral bioavailability of lovastatin.

Development of Orodispersible Tizanidine HCl Tablets Using Spray Dried Coprocessed Exipient Bases.

Tizanidine HCl is a centrally acting α-2 adrenergic agonist muscle relaxant with a slightly bitter taste having short half-life of 2.5 h. In the present study effect of co-processed excipient bases in formulation of orodispersible tizanidine HCl tablets by direct compression method was investigated. Co-processed excipient of microcrystalline cellulose with SSL-hydroxypropylcellulose was prepared using spray drier in 1:1, 1:2 and 1:3 ratio. Formulated tablets were evaluated for hardness, friability, in vitro disintegration time and in vitro drug release. Formulation F-3 prepared by addition of co-processed excipient base in ratio of 1:3 showed minimum disintegration time of 9.15±0.04 s and higher amount of drug release of 93.75% at the end of 15 min. Granules obtained by spray drying technique were found to be more spherical which improved its flow property and was supported by scanning electron microscope studies. Thermal studies indicated change in amorphous state, compatibility of drug in formulation was confirmed by fourier transform infrared studies. Analyses of drug release data indicated formulation followed first order kinetics. Inclusion of co-processed excipient base in formulation of orodispersible tablets enhanced disintegration significantly.