Your search keyword '"Peter Bloomingdale"' showing total 3 results

1. Minimal brain PBPK model to support the preclinical and clinical development of antibody therapeutics for CNS diseases

Author

Christian Maass, Suruchi Bakshi, Cesar Pichardo-Almarza, Piet H. van der Graaf, Peter Bloomingdale, Eline van Maanen, Daniela Bumbaca Yadav, and Nitin Mehrotra

Subjects

Drug, Physiologically based pharmacokinetic modelling, PBPK, media_common.quotation_subject, Central nervous system, Context (language use), Drug development, Models, Biological, Antibodies, Pharmacokinetics, Central Nervous System Diseases, Medicine, Humans, Computer Simulation, Compartment (pharmacokinetics), Antibody, media_common, Pharmacology, Original Paper, business.industry, Area under the curve, Brain, medicine.anatomical_structure, business, Neuroscience

Abstract

There are several antibody therapeutics in preclinical and clinical development, industry-wide, for the treatment of central nervous system (CNS) disorders. Due to the limited permeability of antibodies across brain barriers, the quantitative understanding of antibody exposure in the CNS is important for the design of antibody drug characteristics and determining appropriate dosing regimens. We have developed a minimal physiologically-based pharmacokinetic (mPBPK) model of the brain for antibody therapeutics, which was reduced from an existing multi-species platform brain PBPK model. All non-brain compartments were combined into a single tissue compartment and cerebral spinal fluid (CSF) compartments were combined into a single CSF compartment. The mPBPK model contains 16 differential equations, compared to 100 in the original PBPK model, and improved simulation speed approximately 11-fold. Area under the curve ratios for minimal versus full PBPK models were close to 1 across species for both brain and plasma compartments, which indicates the reduced model simulations are similar to those of the original model. The minimal model retained detailed physiological processes of the brain while not significantly affecting model predictability, which supports the law of parsimony in the context of balancing model complexity with added predictive power. The minimal model has a variety of applications for supporting the preclinical development of antibody therapeutics and can be expanded to include target information for evaluating target engagement to inform clinical dose selection. Supplementary Information The online version contains supplementary material available at 10.1007/s10928-021-09776-7.

Published

2021

2. Machine Learning in Drug Discovery and Development Part 1: A Primer

Author

Almut G. Winterstein, Gregory Hather, Juan Francisco Morales, Jagdeep T. Podichetty, Jackson Burton, Sarah Kim, Joshua D. Brown, Samuel Kim, Alan Talevi, Daniela J. Conrado, Jensen Kael White, Stephan Schmidt, and Peter Bloomingdale

Subjects

Computer science, Drug development, Machine learning, computer.software_genre, Machine Learning, Drug Development, Artificial Intelligence, Predictive Value of Tests, Drug Discovery, Tutorial, Humans, Pharmacology (medical), Model development, Drug Approval, business.industry, Drug discovery, lcsh:RM1-950, Pillar, Química, History, 20th Century, Models, Theoretical, Pharmacometrics, lcsh:Therapeutics. Pharmacology, Modeling and Simulation, Key (cryptography), Artificial intelligence, business, computer, Algorithms

Abstract

Artificial intelligence, in particular machine learning (ML), has emerged as a key promising pillar to overcome the high failure rate in drug development. Here, we present a primer on the ML algorithms most commonly used in drug discovery and development. We also list possible data sources, describe good practices for ML model development and validation, and share a reproducible example. A companion article will summarize applications of ML in drug discovery, drug development, and postapproval phase., Laboratorio de Investigación y Desarrollo de Bioactivos

Published

2020

3. Quantitative systems toxicology

Author

Conrad Housand, John M. Burke, Joshua F. Apgar, Peter Bloomingdale, Dhaval K. Shah, Bjorn L. Millard, and Donald E. Mager

Subjects

0301 basic medicine, Drug, Systems toxicology, business.industry, media_common.quotation_subject, Pharmacology, Toxicology, 030226 pharmacology & pharmacy, Article, 3. Good health, 03 medical and health sciences, Patient safety, 030104 developmental biology, 0302 clinical medicine, Drug development, Risk analysis (engineering), Organ specific, Medicine, Experimental methods, business, Adverse effect, media_common, Systems pharmacology

Abstract

The overarching goal of modern drug development is to optimize therapeutic benefits while minimizing adverse effects. However, inadequate efficacy and safety concerns remain to be the major causes of drug attrition in clinical development. For the past 80 years, toxicity testing has consisted of evaluating the adverse effects of drugs in animals to predict human health risks. The U.S. Environmental Protection Agency recognized the need to develop innovative toxicity testing strategies and asked the National Research Council to develop a long-range vision and strategy for toxicity testing in the 21st century. The vision aims to reduce the use of animals and drug development costs through the integration of computational modeling and in vitro experimental methods that evaluates the perturbation of toxicity-related pathways. Towards this vision, collaborative quantitative systems pharmacology and toxicology modeling endeavors (QSP/QST) have been initiated amongst numerous organizations worldwide. In this article, we discuss how quantitative structure-activity relationship (QSAR), network-based, and pharmacokinetic/pharmacodynamic modeling approaches can be integrated into the framework of QST models. Additionally, we review the application of QST models to predict cardiotoxicity and hepatotoxicity of drugs throughout their development. Cell and organ specific QST models are likely to become an essential component of modern toxicity testing, and provides a solid foundation towards determining individualized therapeutic windows to improve patient safety.

Published

2017