Medicinal chemistry is a complex science that lies at the very heart of drug discovery. Poor solubility, complex metabolism, tissue retention and slow elimination are just some of the properties of investigational compounds that present a challenge to the design and conduct of ADMET studies. Medicinal chemistry experience and knowledge relating to how a lead structure was modified to solve a specific problem is generally very challenging to retrieve. Presented in a visual and accessible style, this book provides rapid solutions to overcome the universal challenges to optimizing ADMET.
The Medicinal Chemist’s Guide to Solving ADMET Challenges summarizes a series of design strategies and tactics that have been successfully employed across pharmaceutical and academic laboratories to solve common ADMET issues. These are exemplified with a curated collection of concrete examples displayed in a highly visual “table-of-contents” style format, allowing readers to rapidly identify the most promising approaches applicable to their own challenges. Each ADMET parameter is introduced in a concise yet comprehensive manner and includes background, relevance and screening strategies. Medicinal chemistry knowledge of how best to modify molecular structure to solve ADMET issues is challenging to retrieve from the literature, public databases and even corporate data warehouses. The Medicinal Chemist’s Guide to Solving ADMET Challenges addresses this gap by presenting state-of-the-art design strategies put together by a global group of experienced medicinal chemists and ADMET experts across academia and the pharmaceutical industry.
This contributed volume offers a comprehensive discussion on how to design and discover pharmaceuticals using computational modeling techniques. The different chapters deal with the classical and most advanced techniques, theories, protocols, databases, and tools employed in computer-aided drug design (CADD) covering diverse therapeutic classes. Multiple components of Structure-Based Drug Discovery (SBDD) along with its workflow and associated challenges are presented while potential leads for Alzheimer’s disease (AD), antiviral agents, anti-human immunodeficiency virus (HIV) drugs, and leads for Severe Fever with Thrombocytopenia Syndrome Virus (SFTSV) disease are discussed in detail. Computational toxicological aspects in drug design and discovery, screening adverse effects, and existing or future in silico tools are highlighted, while a novel in silico tool, RASAR, which can be a major technique for small to big datasets when not much experimental data are present, is presented. The book also introduces the reader to the major drug databases covering drug molecules, chemicals, therapeutic targets, metabolomics, and peptides, which are great resources for drug discovery employing drug repurposing, high throughput, and virtual screening. This volume is a great tool for graduates, researchers, academics, and industrial scientists working in the fields of cheminformatics, bioinformatics, computational biology, and chemistry.
New antiviral drugs are urgently needed. Recent outbreaks caused by viruses with great epidemiological impact such as Zika, or extraordinary virulence such as Ebola, Nipah, Lassa, Crimean-Congo haemorrhagic fever highlight the current lack of clinically proven vaccines and treatments for these potentially catastrophic agents. Antiviral Discovery for Highly Pathogenic Emerging Viruses comprehensively outlines the state of the art in antiviral drug discovery including identification of targets, screening strategies and the current pipeline of antiviral candidates including regulatory issues. The book also addresses the challenges faced in proceeding from pre-clinical studies to animal models and clinical trials with these highly pathogenic agents. Ideal for drug discovery scientists and medicinal chemists with an interest in antiviral drug discovery and development, this book provides a complete overview of the latest progress in the field, recent advances and the challenges that remain in developing these highly pathogenic agents. Illustrated throughout with case studies this book is a valuable resource in this complex and multidisciplinary field.
The covalent conjugation of potent cytotoxic agents to monoclonal antibodies, known as antibody-drug conjugates (ADCs) is a powerful approach in the field of targeted treatment of cancer. Clearly, both monoclonal antibody and cytotoxic payload are crucial elements in determining the clinical value of an ADC and have receive ample attention. However, the structural element connecting the two –the chemical linker– also plays an essential role in mode-of-action, efficacy, pharmacokinetics and safety profile of an ADC, but is often underappreciated in considerations of ADC design. Chemical Linkers in Antibody–Drug Conjugates aims to shine a detailed light on the various key attributes of chemical linkers in ADCs, for drug-to-antibody ratio, for stability, for release mechanism of payload, for pharmacokinetics, for stability determination, and for efficacy and safety. Ideal for postgraduate students and active researchers in drug discovery and development, this book provides a comprehensive description of linkers used in ADCs (clinical and late preclinical), insight into key quality attributes of linkers for ADCs, and aids the reader in understanding the role of linker chemistry and designing new ADCs.
Drug repurposing is the development of existing drugs for new uses: given that 9 in 10 drugs that enter drug development are never marketed and therefore represent wasted effort, it is an attractive as well as inherently more efficient process. Three repurposed drugs can be brought to market for the same cost as one new chemical entity; and they can also be identified more quickly, an important benefit for patients whose diseases are progressing faster than therapeutic innovation. But repurposing also requires a fresh look at configuring pharmaceutical R&D, considering clinical, regulatory and patent issues much earlier than would otherwise be the case; a holistic gedanken experiment almost needs to be undertaken at the very start of any repurposing development. In addition to new ways of thinking, the discovery of repurposing opportunities can take advantage of artificial intelligence techniques to match the perfect new use for an existing drug. And while repurposing of medicines has been in the mind of every doctor since Hypocrates, modern clinical practice will simply have to adapt to new repurposing techniques in an age where the number of known diseases is increasing much faster than the healthcare dollars available.
Toxicodynamics in Drug Research, Volume 2: Public Health and Toxicology Issues examines the implications of public health issues and the impact of pharmaceuticals, chemical and food toxicants, dietary phytochemicals, and medical treatments on human health. Volume 2: Public Health and Toxicology Issues in Drug Research: Toxicity and Toxicodynamics covers topics on pharmacokinetics and toxicokinetics such as population pharmacokinetics/toxicokinetics, the design of toxicokinetic studies, and the use of toxicokinetic data in preclinical safety assessments. The book investigates the health effect caused by the bioaccumulation of pharmaceutical and personal care products and the impact of drug-induced toxicity on different systems of the body. It discusses the mechanistic pathways of food toxicants and illustrates the molecular mechanisms of the chemopreventive role of dietary phytochemicals. It also delves into the toxic effects of medical treatments and materials. Ethical, legal, societal, and professional issues in toxicology round off the coverage providing a valuable resource to interested in learning more about the health impact and public health issues related to the toxicity of pharmaceuticals, dietary supplements, personal care products, and medical treatments. - Discusses the impact of pharmaceuticals, food, and chemical toxicants on human health - Examines the toxic effects of medical treatments, clinical administrations, and materials - Explores public health issues around drug safety and toxicology
Epigenetics is one of the fastest moving fields in drug discovery, with almost every large pharmaceutical company, and a substantial number of biotechnology companies, targeting epigenetic processes to treat diseases ranging from cancer to Huntington’s disease and from inflammation to sickle cell anaemia. This book aims to provide an overview of the key topics adopted in current epigenetic drug discovery programmes with a focus on major developments and new technologies. Importantly, the book incorporates case studies and outlines the key challenges and techniques employed to overcome them. The book is an ideal resource for researchers in both industry and academia with an interest in epigenetic and genetic factors involved in drug discovery, target ID and validation. The book is also an excellent introduction for postgraduates interested in the interface between epigenetics and pharmaceuticals.
Polymers for Oral Drug Delivery Technologies covers the fundamentals of oral drug delivery and various aspects of polymer technology in oral drug delivery, from classification and synthesis, to applications and regulatory factors. It presents the oral delivery?of therapeutics for treating a number of diseases, along with the challenges of oral drug administration to assure a predictive and reproducible pharmacokinetic profile of active pharmaceutical ingredients (API).Polymers play an important role to achieve the targeted release profile consistently of an API in vivo by various functionalities like drug protection from gastric juice, fast release and supersaturation or release within a targeted area of the GI tract. - Provides a comprehensive update on the state of polymer technology for oral drug delivery, bringing the reader up-to-speed via a single reference - Covers a range of polymer technology types, including capsule forming polymers, matrix formers, functional polymer coatings, and more - Contains contributions from global experts spanning academia and industry, offering an interdisciplinary and translational approach to polymers for oral drug delivery
Helps you choose the right computational tools and techniques to meet your drug design goals Computational Drug Design covers all of the major computational drug design techniques in use today, focusing on the process that pharmaceutical chemists employ to design a new drug molecule. The discussions of which computational tools to use and when and how to use them are all based on typical pharmaceutical industry drug design processes. Following an introduction, the book is divided into three parts: Part One, The Drug Design Process, sets forth a variety of design processes suitable for a number of different drug development scenarios and drug targets. The author demonstrates how computational techniques are typically used during the design process, helping readers choose the best computational tools to meet their goals. Part Two, Computational Tools and Techniques, offers a series of chapters, each one dedicated to a single computational technique. Readers discover the strengths and weaknesses of each technique. Moreover, the book tabulates comparative accuracy studies, giving readers an unbiased comparison of all the available techniques. Part Three, Related Topics, addresses new, emerging, and complementary technologies, including bioinformatics, simulations at the cellular and organ level, synthesis route prediction, proteomics, and prodrug approaches. The book's accompanying CD-ROM, a special feature, offers graphics of the molecular structures and dynamic reactions discussed in the book as well as demos from computational drug design software companies. Computational Drug Design is ideal for both students and professionals in drug design, helping them choose and take full advantage of the best computational tools available. Note: CD-ROM/DVD and other supplementary materials are not included as part of eBook file.