V S Geetha scite author profile

Objective: To formulate, optimize and evaluate 5-fluorouracil loaded liquorice crude protein nanoparticles for sustained drug delivery using Box-Behnken design. Methods: 5-fluorouracil (5-FU) loaded liquorice crude protein (LCP) nanoparticles were prepared by desolvation method using ethanol-water (1:2 ratio), Tween-80 (2%v/v) as stabilizing agent and gluteraldehyde (8% v/v) as cross linking agent. The optimization of prepared nanoparticles was carried out using Box-Behnken design with 3 factors 2 levels and 3 responses. The independent variables were A)5-FU concentration B)LCP concentration and C) sonication time while the responses were R1) Drug entrapment efficiency R2) Drug loading efficiency and R3) Particle size. The correlation between factors and responses were studied through response surface plots and mathematical equations. The nanoparticles were evaluated for FTIR, physicochemical properties like particle size and zeta potential by Photon correlation spectroscopy (PCS) and surface morphology by TEM. The entrapment efficiency, drug loading efficiency and in vitro drug release studies in PBS pH 7.4 (24 h) were carried out. The observed values were found to be in close agreement with the predicted value obtained from the optimization process. Results: 5-fluorouracil loaded LCP nanoparticles were prepared by desolvation method, the optimization was carried out by Box-Behnken design and the final formulation was evaluated for particle size (301.1 nm), zeta-potential (-25.8mV), PDI(0.226), with entrapment efficiency (64.07%), drug loading efficiency (28.54%), in vitro drug release (65.2% in 24 h) respectively. The formulated nanoparticles show Higuchi model drug release kinetics with sustained drug delivery for 24 h in pH7.4 buffer. Conclusion: The results were proved to be the most valuable for the sustained delivery of 5-Fluorouracil using liquorice crude protein as carrier. 5-FU–LCP nanoparticles were prepared using Tween-80 as stabilizing agent and gluteraldehyde as cross-linking agent to possess ideal sustained drug release characteristics.

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Design, Development and in Vitro Evaluation of Erlotinib Loaded Liquorice Crude Protein Nanoparticles by Box Behnken Design

Geetha

Velraj

2021

Int J App Pharm

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Objective: To formulate and evaluate Erlotinib loaded Liquorice crude protein (LCP) nanoparticles from the powdered liquorice root (Glycyrrhiza glabra) using Box-Behnken design. Methods: Erlotinib loaded liquorice crude protein nanoparticles were prepared by desolvation method using ethanol-water (1:2 ratio), Tween-80 (2%v/v) and gluteraldehyde (8% v/v) as cross linking agent. Box-Behnken design with 3 factors, 3 levels and 3 responses was used to optimize the prepared nanoparticles. The independent variables were taken as A) Erlotinib concentration B) LCP concentration and C) Incubation time with responses R1) Drug entrapment efficiency R2) Drug Release and R3) Particle size. The correlation between factors and responses were studied through response surface plots and mathematical equations. The nanoparticles were evaluated for FTIR, particle size and zeta potential by Photon correlation spectroscopy (PCS) and surface morphology by TEM. The entrapment efficiency, and in vitro drug release studies in PBS pH 7.4 (26 h) were carried out. The experimental values were found to be in close resemblance with the predicted value obtained from the optimization process. The in vitro cytotoxicity studies of the prepared nanoparticles in lung cancer cell line (A 549) were studied with different concentrations for 24h. Results: The average particle size, zeta potential, Polydispersity index (PDI) were found to be 292.1 nm,-25.8 mV and 0.384 respectively. TEM image showed that the nanoparticles dispersed well with a uniform shape and showed not much change during storage. The in vitro drug release showed 41.23% for 26 h in PBS (7.4) and release kinetics showed highest R2value (0.982) for Korsmeyer-Peppas model, followed by 0.977 for Higuchi model. The in vitro cytotoxicity of prepared nanoparticles in A 549 cell line showed good results with different concentrations for 24h. Conclusion: Erlotinib (Erlo) is a BCS class II drug with poor solubility, poor bioavailability and selective tyrosine kinase inhibitor for non small-cell lung cancer (NSCLC) through oral administration. To improve the oral bioavailability and absorption of molecules, plant protein as carriers is used for developing drug delivery systems due to their proven safety. The optimization variables were Conc of Erlo, Conc. of LCP and Incubation time to get responses as drug entrapment efficiency, drug release and particle size. The compatibility between drug and LCP were evaluated by FTIR.

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V S Geetha

In vitro screening of Annonareticulata L. Pericarp for antimicrobial activity

Formulation, Optimization and in Vitro Evaluation of 5-Fluorouracil Loaded Liquorice Crude Protein Nanoparticles for Sustained Drug Delivery Using Box-Behnken Design

Design, Development and in Vitro Evaluation of Erlotinib Loaded Liquorice Crude Protein Nanoparticles by Box Behnken Design

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