Your search keyword '"Carol Bason"' showing total 3 results

1. Development of a liver-targeted siRNA delivery platform with a broad therapeutic window utilizing biodegradable polypeptide-based polymer conjugates

Author

Quang Truong, Conrad E. Raab, Michael J. Lyman, Andrew H. Latham, Haihong Fan, Eileen S. Walsh, Marissa Vavrek, Robert M. Garbaccio, Eric Kemp, Marc Abrams, Erin N. Guidry, Tao Pei, Steven L. Colletti, Laura Sepp-Lorenzino, Edward J. Carlini, Carol Bason, Melissa Stern, J. Michael Williams, Eric D. Soli, Rob S. Burke, Mihir Patel, Jun H. Heo, Brian A. Carr, Stephanie Young, Jacob H. Waldman, Sean Riley, Nicole T. Pudvah, Louis S. Crocker, Bonnie J. Howell, Sergey Pechenov, Steven J. Staskiewicz, Sheri Smith, Marina Busuek, Rubina G. Parmar, Stephanie E. Barrett, Anthony Leone, and Robert A. Kowtoniuk

Subjects

Biodistribution, Pharmaceutical Science, Biocompatible Materials, Nanotechnology, Gene delivery, Rats, Sprague-Dawley, Structure-Activity Relationship, Drug Stability, Species Specificity, In vivo, Animals, Humans, Structure–activity relationship, Tissue Distribution, RNA, Small Interfering, Radionuclide Imaging, chemistry.chemical_classification, Drug Carriers, Gene knockdown, Chemistry, Hep G2 Cells, Polymer, Macaca mulatta, Nylons, Liver, Drug Design, Hepatocytes, Biophysics, Autoradiography, Female, Peptides, Drug carrier, Conjugate

Abstract

The greatest challenge standing in the way of effective in vivo siRNA delivery is creating a delivery vehicle that mediates a high degree of efficacy with a broad therapeutic window. Key structure-activity relationships of a poly(amide) polymer conjugate siRNA delivery platform were explored to discover the optimized polymer parameters that yield the highest activity of mRNA knockdown in the liver. At the same time, the poly(amide) backbone of the polymers allowed for the metabolism and clearance of the polymer from the body very quickly, which was established using radiolabeled polymers to demonstrate the time course of biodistribution and excretion from the body. The fast degradation and clearance of the polymers provided for very low toxicity at efficacious doses, and the therapeutic window of this poly(amide)-based siRNA delivery platform was shown to be much broader than a comparable polymer platform. The results of this work illustrate that the poly(amide) platform has a promising future in the development of a siRNA-based drug approved for human use.

Published

2014

2. Liquid extraction surface analysis mass spectrometry (LESA-MS) as a novel profiling tool for drug distribution and metabolism analysis: the terfenadine example

Author

Jack Henion, Daniel Eikel, Carol Bason, Marissa Vavrek, Walter A. Korfmacher, Suzie Yeh, and Sheri Smith

Subjects

Drug, Chromatography, Fexofenadine, Chemistry, media_common.quotation_subject, Organic Chemistry, Mass spectrometry, Analytical Chemistry, First pass effect, medicine, Distribution (pharmacology), Terfenadine, Spectroscopy, Active metabolite, Ex vivo, medicine.drug, media_common

Abstract

Liquid extraction surface analysis mass spectrometry (LESA-MS) is a novel surface profiling technique that combines micro-liquid extraction from a solid surface with nano-electrospray mass spectrometry. One potential application is the examination of the distribution of drugs and their metabolites by analyzing ex vivo tissue sections, an area where quantitative whole body autoradiography (QWBA) is traditionally employed. However, QWBA relies on the use of radiolabeled drugs and is limited to total radioactivity measured whereas LESA-MS can provide drug- and metabolite-specific distribution information. Here, we evaluate LESA-MS, examining the distribution and biotransformation of unlabeled terfenadine in mice and compare our findings to QWBA, whole tissue LC/MS/MS and MALDI-MSI. The spatial resolution of LESA-MS can be optimized to ca. 1 mm on tissues such as brain, liver and kidney, also enabling drug profiling within a single organ. LESA-MS can readily identify the biotransformation of terfenadine to its major, active metabolite fexofenadine. Relative quantification can confirm the rapid absorption of terfendine after oral dosage, its extensive first pass metabolism and the distribution of both compounds into systemic tissues such as muscle, spleen and kidney. The elimination appears to be consistent with biliary excretion and only trace levels of fexofenadine could be confirmed in brain. We found LESA-MS to be more informative in terms of drug distribution than a comparable MALDI-MS imaging study, likely due to its favorable overall sensitivity due to the larger surface area sampled. LESA-MS appears to be a useful new profiling tool for examining the distribution of drugs and their metabolites in tissue sections.

Published

2011

3. Liquid extraction surface analysis mass spectrometry (LESA-MS) as a novel profiling tool for drug distribution and metabolism analysis: the terfenadine example

Author

Daniel, Eikel, Marissa, Vavrek, Sheri, Smith, Carol, Bason, Suzie, Yeh, Walter A, Korfmacher, and Jack D, Henion

Subjects

Male, Mice, Histocytological Preparation Techniques, Histocytochemistry, Liquid-Liquid Extraction, Animals, Autoradiography, Reproducibility of Results, Tissue Distribution, Terfenadine, Sensitivity and Specificity, Mass Spectrometry

Abstract

Liquid extraction surface analysis mass spectrometry (LESA-MS) is a novel surface profiling technique that combines micro-liquid extraction from a solid surface with nano-electrospray mass spectrometry. One potential application is the examination of the distribution of drugs and their metabolites by analyzing ex vivo tissue sections, an area where quantitative whole body autoradiography (QWBA) is traditionally employed. However, QWBA relies on the use of radiolabeled drugs and is limited to total radioactivity measured whereas LESA-MS can provide drug- and metabolite-specific distribution information. Here, we evaluate LESA-MS, examining the distribution and biotransformation of unlabeled terfenadine in mice and compare our findings to QWBA, whole tissue LC/MS/MS and MALDI-MSI. The spatial resolution of LESA-MS can be optimized to ca. 1 mm on tissues such as brain, liver and kidney, also enabling drug profiling within a single organ. LESA-MS can readily identify the biotransformation of terfenadine to its major, active metabolite fexofenadine. Relative quantification can confirm the rapid absorption of terfendine after oral dosage, its extensive first pass metabolism and the distribution of both compounds into systemic tissues such as muscle, spleen and kidney. The elimination appears to be consistent with biliary excretion and only trace levels of fexofenadine could be confirmed in brain. We found LESA-MS to be more informative in terms of drug distribution than a comparable MALDI-MS imaging study, likely due to its favorable overall sensitivity due to the larger surface area sampled. LESA-MS appears to be a useful new profiling tool for examining the distribution of drugs and their metabolites in tissue sections.

Published

2011