Formulation, Optimization, and Evaluation of Ketoconazole Loaded Nanostructured Lipid Carrier Gel for Topical Delivery

Nanostructured Etodolac Carriers in Transdermal Gel: Optimization and Characterization

AIMS

To optimize, formulate, and evaluate a Nanostructured Lipid Carrier (NLC) based transdermal gel of Etodolac (ETD).

OBJECTIVE

To avoid issues of conventional route ETD administration like first pass metabolism, gastric ulceration, hemorrhage, and being a class-II drug with less solubility. A transdermal gel of nanostructured lipid carrier for ETD has been developed. Formulation will execute faster onset of action, increased penetration, permeation with extended release of the drug for a longer duration.

METHODS

A central composite 32 factorial design is used to plan experiments. NLCs are prepared by the method of melt emulsification and ultrasonication. Compritol 888ATO and Miglyol are used as solid and liquid lipid phases. Surfactant Pluronic F68 showed a significant effect on particle size, entrapment efficiency, and drug release. Particle size characterized using photon correlation spectroscopy and scanning electron microscopy. Cumulative drug release studied using an artificial diffusion cell and a dialysis membrane. A skin permeation study was performed using goat skin at 32°C ± 0.5°C. The efficacy of the NLC gel was verified using a pharmacodynamic study followed by stability study for 3 and 6 months.

RESULTS

The optimized batch of ETD NLC found spherical with a 241.3 nm particle size with 0.392 PDI,-29 mV zeta potential. Entrapment efficiency and cumulative drug release were found to be 64.21 ± 1.23% and 70.12 ± 2.10% (after 12 hours), respectively. All batches followed zeroorder drug release kinetics and non-Fickian (Super Case II transport) with 0.1619 mg/cm2/hr transdermal flux. The NLC gel of ETD showed a quick onset and lengthened therapeutic activity until 24 hours compared to the micellar ETD gel.

CONCLUSION

Etodolac NLC batch successfully optimized using central composite design. The relationships between the components of the NLC-total lipid:drug and surfactant-and the outcomes- particle size,%entrapment and% drug release-were better understood by examining several contour plots. The results of the experimental and predicted formulations were found to be in good agreement with slight bias, demonstrating the reliability of the optimization process.

Effect of the Surfactant and Liquid Lipid Type in the Physico-chemical Characteristics of Beeswax-based Nanostructured Lipid Carrier (NLC) of Metformin

BACKGROUND

Metformin (MF) is an antidiabetic drug that belongs to class III of the biopharmaceutical classification system (BCS) characterized by high solubility and low permeability.

OBJECTIVE

The study aimed to prepare metformin as nanostructured lipid carriers (MF-NLCs) to control the drug release and enhance its permeability through the biological membrane.

METHODS

2² full factorial design was used to make the design of MF-NLCs formulations. MFNLCs were prepared by hot-melt homogenization-ultra sonication technique using beeswax as solid lipid in the presence of liquid lipid (either capryol 90 or oleic acid) and surfactant (either poloxamer 188 or tween 80).

RESULTS

The entrapment efficiency (EE%) of MF-NLCs was ranged from 85.2±2.5 to 96.5±1.8%. The particle size was in the nanoscale (134.6±4.1 to 264.1±4.6 nm). The value of zeta potential has a negative value ranged from -25.6±1.1 to -39.4±0.9 mV. The PDI value was in the range of 0.253±0.01 to 0.496±0.02. The cumulative drug release was calculated for MF-NLCs and it was found that Q_12h ranged from 90.5±1.7% for MF-NLC1 to 99.3±2.8 for MF-NLC4. Infra-red (IR) spectroscopy and differential scanning calorimetry (DSC) studies revealed the compatibility of the drug with other ingredients. MF-NLC4 was found to be the optimized formulation with the best responses.

CONCLUSION

2² full factorial design succeed to obtain an optimized formulation which controls the drug release and increases the drug penetration.

The Antifungal and Ocular Permeation of Ketoconazole from Ophthalmic Formulations Containing Trans-Ethosomes Nanoparticles

Ketoconazole (KET), a synthetic imidazole broad-spectrum antifungal agent, is characterized by its poor aqueous solubility and high molecular weight, which might hamper its corneal permeation. The aim was to develop an ophthalmic formulation loaded with optimized trans-ethosomal vesicles to enhance KET ocular permeation, antifungal activity, rapid drug drainage, and short elimination half-life. Four formulation factors affecting the vesicles' size, zeta potential, entrapment efficiency, and flexibility of the trans-ethosomes formulations were optimized. The optimum formulation was characterized, and their morphological and antifungal activity were studied. Different ophthalmic formulations loaded with the optimized vesicles were prepared and characterized. The ocular irritation and in vivo corneal permeation were investigated. Results revealed that the drug-to-phospholipid-molar ratio, the percentage of edge activator, the percentage of ethanol, and the percentage of stearyl amine significantly affect the characteristics of the vesicles. The optimized vesicles were spherical and showed an average size of 151.34 ± 8.73 nm, a zeta potential value of +34.82 ± 2.64 mV, an entrapment efficiency of 94.97 ± 5.41%, and flexibility of 95.44 ± 4.33%. The antifungal activity of KET was significantly improved following treatment with the optimized vesicles. The developed in situ gel formulations were found to be nonirritating to the cornea. The trans-ethosomes vesicles were able to penetrate deeper into the posterior eye segment without any toxic effects. Accordingly, the in situ developed gel formulation loaded with KET trans-ethosomes vesicles represents a promising ocular delivery system for the treatment of deep fungal eye infections.

Colloidal lipid nanodispersion enriched hydrogel of antifungal agent for management of fungal infections: Comparative in-vitro, ex-vivo and in-vivo evaluation for oral and topical application

Ketoconazole (KZ) is broad spectrum antifungal drug, used for the treatment of fungal infections. KZ's clinical topical use has been associated with some adverse effects in healthy adults particularly local reactions, such as stinging, severe irritation, and pruritus. However, bioavailability of KZ after oral administration is low from tablets due to its low aqueous solubility. The objective of this investigation was development and characterization of KZ-containing solid lipid nanoparticles (KZ-SLNs) and SLN-containing hydrogel (KZ-SLN-H) for oral and topical delivery of KZ. KZ-SLNs were prepared using homogenization-sonication method. Optimal KZ-SLN formulation was selected based on physicochemical and in-vitro release studies. Optimized KZ-SLN converted to KZ-SLN hydrogel (KZ-SLN-H) using gelling polymers and optimized with rheological and in-vitro studies. Further, optimized KZ-SLN and KZ-SLN-H formulations evaluated for crystallinity, morphology, stability, ex-vivo and in-vivo pharmacokinetic (PK) studies in rats, comparison with KZ suspension (KZ-S) and KZ-S hydrogel (KZ-SH). Optimized KZ-SLN formulation showed desirable characters. KZ-SLN and KZ-SLN-H formulations exhibited spherical shape, converted to amorphous, sustained release behaviour and enhanced permeability (p < 0.05). Moreover, both formulations were stable for three months at 4 °C and 25 °C. PK studies revealed 1.9 and 1.5-folds, 3.5 and 2.8-folds enhancement of bioavailability of optimized KZ-SLN and KZ-SLN-H formulations (p < 0.05) compared with KZ-S and KZ-SH formulations, respectively. Overall, SLN and SLN-H formulations could be considered as an efficient delivery vehicles for KZ through oral and topical administration for better control over topical and systemic fungal infections.

Formulation, optimization, and in vitro evaluation of nanostructured lipid carriers for topical delivery of Apremilast

This work was aimed to formulate topical Apremilast (APM)-loaded nanostructured lipid carriers (NLCs) for the management of psoriasis. NLCs were prepared by a cold homogenization technique using Compritol 888ATO, oleic acid, Tween 80 and Span 20, and Transcutol P as a solid lipid, liquid lipid, surfactant mixture, and penetration enhancer, respectively. Carbopol 940 was used to convert NLC dispersion into NLC-based hydrogel to improve its viscosity for topical administration. The optimized formulation was characterized for size, polydispersity index (PDI), zeta potential (ZP), percentage of entrapment efficiency (%EE), and surface morphology. Furthermore, viscosity, spreadability, stability, in vitro drug diffusion, ex vivo skin permeation, and skin deposition studies were carried out. APM-loaded NLCs showed a narrow PDI (0.339) with a particle size of 758 nm, a %EE of 85.5%, and a ZP of -33.3 mV. Scanning electron microscopy confirmed spherical shape of NLCs. in vitro drug diffusion and ex vivo skin permeation results showed low drug diffusion, sustained drug release, and 60.1% skin deposition. The present study confirms the potential of the nanostructured lipid form of poorly water-soluble drugs for topical application and increased drug deposition in the skin.