Your search keyword '"Templeton AC"' showing total 7 results

1. In-Use Photostability Practice and Regulatory Evaluation for Pharmaceutical Products in an Age of Light-Emitting Diode Light Sources.

Author

Allain LR, Pierce BC, Wuelfing WP, Templeton AC, and Helmy R

Subjects

Antibodies, Monoclonal chemistry, Antibodies, Monoclonal radiation effects, Biological Products chemistry, Biological Products radiation effects, Facility Design and Construction instrumentation, Facility Design and Construction legislation & jurisprudence, Facility Design and Construction standards, Lighting legislation & jurisprudence, Lighting standards, Pharmaceutical Preparations radiation effects, Ultraviolet Rays adverse effects, Drug Stability, Lighting instrumentation, Pharmaceutical Preparations chemistry, Photolysis radiation effects, Semiconductors

Abstract

This article describes how the increased use of energy-efficient solid-state light sources (e.g., light-emitting diode [LED]-based illumination) in hospitals, pharmacies, and at home can help alleviate concerns of photodegradation for pharmaceuticals. LED light sources, unlike fluorescent ones, do not have spurious spectral contributions <400 nm. Because photostability is primarily evaluated in the International Council of Harmonization Q1B tests with older fluorescent bulb standards (International Organization for Standardization 10977), the amount of photodegradation observed can over-predict what happens in reality, as products are increasingly being stored and used in environments fitted with LED bulbs. Because photodegradation is premised on light absorption by a compound of interest (or a photosensitizer), one can use the overlap between the spectral distribution of a light source and the absorption spectra of a given compound to estimate if photodegradation is a possibility. Based on the absorption spectra of a sample of 150 pharmaceutical compounds in development, only 15% would meet the required overlap to be a candidate to undergo direct photodegradation in the presence of LED lights, against a baseline of 55% of compounds that would, when considering regular fluorescent lights. Biological drug products such as peptides and monoclonal antibodies are also expected to benefit from the use of more efficient solid-state lighting., (Copyright © 2019 American Pharmacists Association®. Published by Elsevier Inc. All rights reserved.)

Published

2019

2. New and Evolving Techniques for the Characterization of Peptide Therapeutics.

Author

D'Addio SM, Bothe JR, Neri C, Walsh PL, Zhang J, Pierson E, Mao Y, Gindy M, Leone A, and Templeton AC

Subjects

Chemistry, Pharmaceutical methods, Chromatography, Gas methods, Chromatography, Gas trends, Chromatography, Liquid methods, Chromatography, Liquid trends, Drug Delivery Systems methods, Drug Stability, Humans, Peptides chemistry, Tandem Mass Spectrometry methods, Tandem Mass Spectrometry trends, Chemistry, Pharmaceutical trends, Drug Delivery Systems trends, Peptides analysis, Peptides therapeutic use

Abstract

Advances in technologies related to the design and manufacture of therapeutic peptides have enabled researchers to overcome the biological and technological challenges that have limited their application in the past. As a result, peptides of increasing complexity have become progressively important against a variety of disease targets. Developing peptide drug products brings with it unique scientific challenges consistent with the unique physicochemical properties of peptide molecules. The identification of the proper characterization tools is required in order to develop peptide formulations with the appropriate stability, manufacturability, and bioperformance characteristics. This knowledge supports the build of critical quality attributes and, ultimately, regulatory specifications. The purpose of this review article is to provide an overview of the techniques that are employed for analytical characterization of peptide drug products. The techniques covered are highlighted in the context of peptide drug product understanding and include chemical and biophysical approaches. Emphasis is placed on summarizing the recent literature experience in the field. Finally, the authors provide regulatory perspective on these characterization approaches and discuss some potential areas for further research in the field., (Copyright © 2016 American Pharmacists Association®. Published by Elsevier Inc. All rights reserved.)

Published

2016

3. Implications of In-Use Photostability: Proposed Guidance for Photostability Testing and Labeling to Support the Administration of Photosensitive Pharmaceutical Products, Part 3. Oral Drug Products.

Author

Allain L, Baertschi SW, Clapham D, Foti C, Lantaff WM, Reed RA, Templeton AC, and Tønnesen HH

Subjects

Administration, Oral, Animals, Drug Labeling standards, Drug Packaging methods, Drug Packaging standards, Drug Stability, Humans, Photochemical Processes, Drug Labeling methods, Pharmaceutical Preparations administration & dosage, Pharmaceutical Preparations metabolism, Photolysis

Abstract

The ICH Q1B guidance and additional clarifying manuscripts provide the essential information needed to conduct photostability testing for pharmaceutical drug products in the context of manufacturing, packaging, and storage. As the previous 2 papers in this series highlight for drug products administered by injection (part 1) and drug products administered via topical application (part 2), there remains a paucity of guidance and methodological approaches to conducting photostability testing to ensure effective product administration. Part 3 in the series is presented here to provide a similar approach and commentary for photostability testing for oral drug products. The approach taken, as was done previously, is to examine "worst case" photoexposure scenarios in combination with ICH-defined light sources to derive a set of practical experimental approaches to support the safe and effective administration of photosensitive oral drug products., (Copyright © 2016 American Pharmacists Association®. Published by Elsevier Inc. All rights reserved.)

Published

2016

4. Implications of In-Use Photostability: Proposed Guidance for Photostability Testing and Labeling to Support the Administration of Photosensitive Pharmaceutical Products, Part 2: Topical Drug Product.

Author

Baertschi SW, Clapham D, Foti C, Kleinman MH, Kristensen S, Reed RA, Templeton AC, and Tønnesen HH

Subjects

Animals, Excipients chemistry, Guidelines as Topic, Humans, Oxidation-Reduction, Pharmaceutical Preparations, Administration, Topical, Drug Stability, Photochemical Processes

Abstract

Although essential guidance to cover the photostability testing of pharmaceuticals for manufacturing and storage is well-established, there continues to be a significant gap in guidance regarding testing to support the effective administration of photosensitive drug products. Continuing from Part 1, (Baertschi SW, Clapham D, Foti C, Jansen PJ, Kristensen S, Reed RA, Templeton AC, Tønnesen HH. 2013. J Pharm Sci 102:3888-3899) where the focus was drug products administered by injection, this commentary proposes guidance for testing topical drug products in order to support administration. As with the previous commentary, the approach taken is to examine "worst case" photoexposure scenarios in comparison with ICH testing conditions to provide practical guidance for the safe and effective administration of photosensitive topical drug products., (© 2015 Wiley Periodicals, Inc. and the American Pharmacists Association.)

Published

2015

5. Effect of added alkalizer and surfactant on dissolution and absorption of the potassium salt of a weakly basic poorly water-soluble drug.

Author

Mahjour M, Kesisoglou F, Cruanes M, Xu W, Zhang D, Maguire TJ, Rosen LA, Templeton AC, and Kress MH

Subjects

Adsorption, Animals, Biological Availability, Dogs, Solubility, Alkalies chemistry, Surface-Active Agents chemistry

Abstract

Telcagepant potassium salt (MK-0974) is an oral calcitonin gene-related peptide receptor inhibitor investigated for the treatment of acute migraine. Under gastric pH conditions, the salt rapidly gels, then converts to an insoluble neutral form that creates an impervious shell on the tablet surface, resulting in a slow and variable release dissolution rate and poor bioavailability. Early attempts to develop a solid dosage form, including solid dispersion and nanosuspension formulations, resulted in low exposures in preclinical studies. Thus, a liquid-filled soft gelatin capsule (SGC) formulation (oblong 20) was used for clinical studies. However, a solid dosage form was desirable for commercialization. The slow dissolution of the tablet formulations was overcome by using a basifying agent, arginine, and inclusion of a nonionic surfactant, poloxamer 407. The combination of arginine and poloxamer in the formulation created a local transient basic microenvironment that promoted the dissolution of the salt and prevented rapid precipitation of the neutral form on the tablet surface to form the gel layer. The tablet formulation achieved fast absorption and comparable exposure to the SGC formulation. The final optimized 280 mg tablet formulation was successfully demonstrated to be bioequivalent to the 300 mg SGC formulation., (© 2014 Wiley Periodicals, Inc. and the American Pharmacists Association.)

Published

2014

6. Implications of in-use photostability: proposed guidance for photostability testing and labeling to support the administration of photosensitive pharmaceutical products, part 1: drug products administered by injection.

Author

Baertschi SW, Clapham D, Foti C, Jansen PJ, Kristensen S, Reed RA, Templeton AC, and Tønnesen HH

Subjects

Drug Labeling methods, Drug Labeling standards, Humans, Injections, Pharmaceutical Preparations chemistry, Technology, Pharmaceutical methods, Technology, Pharmaceutical standards, Drug Stability, Pharmaceutical Preparations administration & dosage, Photolysis

Abstract

Basic guidance on the photostability testing of pharmaceuticals, designed to cover manufacturing and storage over shelf life, has long been established within ICH Q1(ICH,B(10) , but the guideline does not cover the photostability of drugs during or after administration (i.e., under conditions of use). To date, there has been a paucity of guidance covering the additional testing that would be of value during the clinical preparation and use of products. This commentary suggests a systematic approach, based on realistic "worst case" photoexposure scenarios and the existing ICH Option 1 and 2 light sources, to provide valuable data to pharmaceutical manufacturers and compounding pharmacists for the safe and effective use of photosensitive injection products., (© 2013 Wiley Periodicals, Inc. and the American Pharmacists Association.)

Published

2013

7. Evaluation of hydroperoxides in common pharmaceutical excipients.

Author

Wasylaschuk WR, Harmon PA, Wagner G, Harman AB, Templeton AC, Xu H, and Reed RA

Subjects

Cellulose analogs & derivatives, Cellulose chemistry, Chemistry, Pharmaceutical, Dosage Forms, Drug Stability, Excipients standards, Glycerides chemistry, Hydrogen Peroxide chemistry, Lactose chemistry, Mannitol chemistry, Peroxides analysis, Pharmaceutical Preparations chemistry, Poloxamer chemistry, Polyethylene Glycols chemistry, Polysorbates chemistry, Povidone chemistry, Quality Control, Solubility, Technology, Pharmaceutical methods, Drug Contamination, Excipients chemistry, Hydrogen Peroxide analysis

Abstract

While the physical properties of pharmaceutical excipients have been well characterized, impurities that may influence the chemical stability of formulated drug product have not been well studied. In this work, the hydroperoxide (HPO) impurity levels of common pharmaceutical excipients are measured and presented for both soluble and insoluble excipients. Povidone, polysorbate 80 (PS80), polyethylene glycol (PEG) 400, and hydroxypropyl cellulose (HPC) were found to contain substantial concentrations of HPOs with significant lot-to-lot and manufacturer-to-manufacturer variation. Much lower HPO levels were found in the common fillers, like microcrystalline cellulose and lactose, and in high molecular weight PEG, medium chain glyceride (MCG), and poloxamer. The findings are discussed within the context of HPO-mediated oxidation and formulating drug substance sensitive to oxidation. Of the four excipients with substantial HPO levels, povidone, PEG 400, and HPC contain a mixture of hydrogen peroxide and organic HPOs while PS80 contains predominantly organic HPOs. The implications of these findings are discussed with respect to the known manufacturing processes and chemistry of HPO reactivity and degradation kinetics. Defining critical HPO limits for excipients should be driven by the chemistry of a specific drug substance or product and can only be defined within this context., ((c) 2006 Wiley-Liss, Inc. and the American Pharmacists Association.)

Published

2007