Your search keyword '"J. Teckoe"' showing total 3 results

1. Investigation into the Effect of Ethylcellulose Viscosity Variation on the Drug Release of Metoprolol Tartrate and Acetaminophen Extended Release Multiparticulates—Part I

Author

S Workentine, J Teckoe, R Mehta, C Schoener, D Ferrizzi, and Ali R. Rajabi-Siahboomi

Subjects

Drug, Metoprolol Tartrate, Drug Liberation, Polymers, Chemistry, Pharmaceutical, media_common.quotation_subject, Pharmaceutical Science, 02 engineering and technology, Aquatic Science, Pharmacology, 030226 pharmacology & pharmacy, Dosage form, Quality by Design, Excipients, Delayed-Action Preparations, 03 medical and health sciences, Viscosity, 0302 clinical medicine, Drug Discovery, Cellulose, Ecology, Evolution, Behavior and Systematics, Acetaminophen, media_common, chemistry.chemical_classification, Chromatography, Ecology, Chemistry, General Medicine, Polymer, 021001 nanoscience & nanotechnology, 0210 nano-technology, Agronomy and Crop Science, Metoprolol

Abstract

Ethylcellulose is one of the most commonly used polymers to develop reservoir type extended release multiparticulate dosage forms. For multiparticulate extended release dosage forms, the drug release is typically governed by the properties of the barrier membrane coating. The ICH Pharmaceutical Development Guideline (ICH Q8) requires an understanding of the influence of critical material attributes and critical process parameters on the drug release of a pharmaceutical product. Using this understanding, it is possible to develop robust formulations with consistent drug release characteristics. Critical material attributes for ethylcellulose were evaluated, and polymer molecular weight variation (viscosity) was considered to be the most critical attribute that can impact drug release. To investigate the effect of viscosity variation within the manufacturer's specifications of ethylcellulose, extended release multiparticulate formulations of two model drugs, metoprolol tartrate and acetaminophen, were developed using ETHOCEL™ as the rate controlling polymer. Quality by Design (QbD) samples of ETHOCEL Std. 10, 20, and 100 Premium grades representing the low, medium, and high molecular weight (viscosity) material were organically coated onto drug layered multiparticulates to a 15% weight gain (WG). The drug release was found to be similar (f 2 > 50) for both metoprolol tartrate and acetaminophen multiparticulates at different coating weight gains of ethylcellulose, highlighting consistent and robust drug release performance. The use of ETHOCEL QbD samples also serves as a means to develop multiparticulate dosage formulations according to regulatory guidelines.

Published

2016

2. Investigation into the Effect of Ethylcellulose Viscosity Variation on the Drug Release of Metoprolol Tartrate and Acetaminophen Extended Release Multiparticulates-Part I.

Author

Mehta R, Teckoe J, Schoener C, Workentine S, Ferrizzi D, and Rajabi-Siahboomi A

Subjects

Cellulose chemistry, Chemistry, Pharmaceutical methods, Drug Liberation, Excipients chemistry, Polymers chemistry, Viscosity, Acetaminophen chemistry, Cellulose analogs & derivatives, Delayed-Action Preparations chemistry, Metoprolol chemistry

Abstract

Ethylcellulose is one of the most commonly used polymers to develop reservoir type extended release multiparticulate dosage forms. For multiparticulate extended release dosage forms, the drug release is typically governed by the properties of the barrier membrane coating. The ICH Pharmaceutical Development Guideline (ICH Q8) requires an understanding of the influence of critical material attributes and critical process parameters on the drug release of a pharmaceutical product. Using this understanding, it is possible to develop robust formulations with consistent drug release characteristics. Critical material attributes for ethylcellulose were evaluated, and polymer molecular weight variation (viscosity) was considered to be the most critical attribute that can impact drug release. To investigate the effect of viscosity variation within the manufacturer's specifications of ethylcellulose, extended release multiparticulate formulations of two model drugs, metoprolol tartrate and acetaminophen, were developed using ETHOCEL™ as the rate controlling polymer. Quality by Design (QbD) samples of ETHOCEL Std. 10, 20, and 100 Premium grades representing the low, medium, and high molecular weight (viscosity) material were organically coated onto drug layered multiparticulates to a 15% weight gain (WG). The drug release was found to be similar (f 2  > 50) for both metoprolol tartrate and acetaminophen multiparticulates at different coating weight gains of ethylcellulose, highlighting consistent and robust drug release performance. The use of ETHOCEL QbD samples also serves as a means to develop multiparticulate dosage formulations according to regulatory guidelines.

Published

2016

3. Process optimization of a novel immediate release film coating system using QbD principles.

Author

Teckoe J, Mascaro T, Farrell TP, and Rajabi-Siahboomi AR

Subjects

Chemistry, Pharmaceutical, Color, Kinetics, Models, Chemical, Pressure, Quality Control, Solubility, Surface Properties, Tablets, Technology, Pharmaceutical standards, Temperature, Excipients chemistry, Polyvinyl Alcohol chemistry, Technology, Pharmaceutical methods

Abstract

This work describes a quality-by-design (QbD) approach to determine the optimal coating process conditions and robust process operating space for an immediate release aqueous film coating system (Opadry® 200). Critical quality attributes (CQAs) or associated performance indicators of the coated tablets were measured while coating process parameters such as percent solids of the coating dispersion, coating spray rate, inlet air temperature, airflow rate and pan speed were varied, using a design of experiment protocol. The optimized process parameters were then confirmed by independent coating trials. Disintegration time of coated tablets was not affected by the coating process conditions used in this study, while tablet appearance, as determined by measurement of tablet color, coating defects and gloss was determined to be a CQA. Tablet gloss increased when low spray rate and low percent solids were used, as well as with increased coating pan speed. The study used QbD principles and experimental design models to provide a basis to identify ranges of coating process conditions which afford acceptable product quality. High productivity, color uniformity, and very low defect levels were obtained with Opadry 200 even when using a broad range of coating process conditions.

Published

2013