Prodrugs and Targeted Delivery
Towards Better ADME Properties
Methods and Principles in Medicinal Chemistry (Series Nr. 47)
1. Edition December 2010
XXIV, 496 Pages, Hardcover
176 Pictures (2 Colored Figures)
22 tables
Handbook/Reference Book
ISBN:
978-3-527-32603-7
Wiley-VCH, Weinheim
Short Description
The practice-oriented guide to a key strategy in modern drug development: The rational design of prodrugs with enhanced site selectivity and improved ADMET performance.
Further versions
This topical reference and handbook addresses the chemistry, pharmacology, toxicology and the patentability of prodrugs, perfectly mirroring the integrated approach prevalent in today's drug design. It summarizes current experiences and strategies for the rational design of prodrugs, beginning at the early stages of the development process, as well as discussing organ- and site-selective prodrugs.
Every company employing medicinal chemists will be interested in this practice-oriented overview of a key strategy in modern drug discovery and development.
Preface
PART ONE: Prodrug Design and Intellectual Property
PRODRUG STRATEGIES IN DRUG DESIGN
Prodrug Concept
Basics of Prodrug Design
Rationale for Prodrug Design
History of Prodrug Design
Recently Marketed Prodrugs
Concluding Remarks
THE MOLECULAR DESIGN OF PRODRUGS BY FUNCTIONAL GROUP
Introduction
The Prodrug Concept and Basics of Design
Common Functional Group Approaches in Prodrug Design
Conclusions
INTELLECTUAL PROPERTY PRIMER ON PHRAMACEUTICAL PATENTS WITH A SPECIAL EMPHASIS ON PRODRUGS AND METABOLITES
Introduction
Patents and FDA Approval Process
Obtaining a Patent
Conclusion
PART TWO: Prodrugs Addressing ADMET Issues
INCREADING LIPOPHILICITY FOR ORAL DRUG DELIVERY
Introduction
pKa, Degree of Ionization, Partition Coefficient, and Distribution Coefficient
Prodrug Strategies to Enhance Lipid Solubility
Prodrug Examples for Antibiotics
Antiviral Related Prodrugs
Cardiovascular Related Prodrugs
Lipophilic Prodrugs of Benzamidine Drugs
Miscellaneous Examples
Summary and Conclusion
MODULATING SOLUBILITY THROUGH PRODRUGS FOR ORAL AND IV DRUG DELIVERY
Introduction
Basics of Solubility and Oral/IV Drug Delivery
Prodrug Applications for Enhanced Aqueous Solubility
Challenges with Solubilizing Prodrugs of Insoluble Drugs
Additional Applications of Prodrugs for Modulating Solubility
Parallel Exploration of Analogues and Prodrugs in Drug Discovery (Commentary)
Conclusions
PRODRUGS DESIGNED TO TARGET TRANSPORTERS FOR ORAL DRUG DELIVERY
Introduction
Serendipity: An Actively Transported Prodrug
Requirements for Actively Transported Prodrugs
Peptide Transporters: PEPT1 and PEPT2
Monocarboxylate Transporters
Bile Acid Transporters
Conclusions
TOPICAL AND TRANSDERMAL DELIVERY USING PRODRUGS: MECHANISM OF ENHANCEMENT
Introduction
Arrangement of Water in the Stratum Corneum
A New Model for Diffusion Through the Stratum Corneum: The Biphasic Solubility Model
Equations for Quantifying Effects of Solubility on Diffusion Through the Stratum Corneum
Design of Prodrugs for Topical and Transdermal Delivery Based on the Biphasic Solubility Model
Comparison of Human and Mouse Skin Experiments
Summary
OCULAR DELIVERY USING PRODRUGS
Introduction
Criteria for an Ideal Ophthalmic Prodrug
Anatomy and Physiology of the Eye
Barriers to Ocular Drug Delivery
Influx and Efflux Transporters on the Eye
Transporter-Targeted Prodrug Approach
Drug Disposition in Ocular Delivery
Effect of Physiochemical Factors on Drug Disposition in Eye
Prodrug Strategy to Improve Ocular Bioavailability (Nontransporter-Targeted Approach)
Recent Patents and Marketed Ocular Prodrugs
Novel Formulation Approaches for Sustained Delivery of Prodrugs
Conclusion
REDUCING PRESYSTEMIC DRUG METABOLISM
Introduction
Presystemic Metabolic Barriers
Prodrug Approaches to Reduce Presystemic Drug Metabolism
Targeting Colon
Targeting Lymphatic Route
Conclusion
ENZYME-ACTIVATED PRODRUG STRATEGIES FOR SITE-SELECTIVE DRUG DELIVERY
Introduction
General Requirements for Enzyme-Activated Targeted Prodrug Strategy
Examples of Targeted Prodrug Strategies
Summary
PRODRUG APPROACHES FOR CENTRAL NERVOUS SYSTEM DELIVERY
Blood-Brain Barrier in CNS Drug Development
Prodrug Strategies
Prodrug Strategies Based Upon BBB Nutrient Transporters
Prodrug Strategies Based Upon BBB Receptors
CNS Prodrug Summary
DIRECTED ENZYME PRODRUG THERAPIES
Introduction
Theoretical Background of DEPT
Comparison of ADEPT and GDEPT
Enzymes in ADEPT and GDEPT
Design of Prodrugs
Strategies Used for the Improvement of DEPT Systems
Biological Data for ADEPT and GDEPT
Conclusions
PART THREE: Codrugs and Soft Drugs
IMPROVING THE USE OF DRUG COMBINATIONS THROUGH THE CODRUG APPROACH
Codrugs and Codrug Strategy
Ideal Codrug Characteristics
Examples of Marketed Codrugs
Topical Codrug Therapy for the Treatment of Ophthalmic Diseases
Codrugs for Transdermal Delivery
Codrugs of L-DOPA for the Treatment of Parkinson's Disease
Analgesic Codrugs Containing Nonsteroidal Anti-Inflammatory Agents
Analgesic Codrugs of Opioids and Cannabinoids
Codrugs Containing Anti-HIV Drugs
SOFT DRUGS
Introduction
Indications
Design Considerations
Case Study: The Discovery of Esmolol
Summary
PART FOUR: Preclinical and Clinical Considerations for Prodrugs
PHARMACOKINETIC AND BIOPHARMACEUTICAL CONSIDERATIONS IN PRODRUG DISCOVERY AND DEVELOPMENT
Introduction
Understanding Pharmacokinetic/Pharmacodynamic Relationships
Pharmacokinetics
Tools for the Prodrug Scientist
Enzymes Involved with Prodrug Conversion
Use of the Caco-2 System for Permeability and Active Transport Evaluation
XP13512: Improving PK Performance by Targeting Active Transport
Prodrug Absorption: Transport/Metabolic Conversion Interplay
Preabsorptive Degradation
Biopharmaceutical-Based PK Modeling for Prodrug Design
Conclusions
THE IMPACT OF PHARMACOGENETICS ON THE CLINICAL OUTCOMES OF PRODRUGS
Introduction
Clopidogrel and CYP2C19
Codeine and CYP2D6
Tamoxifen and CYP2D6
Fluorouracil Prodrugs and Carboxylesterase
Irinotecan and Carboxylesterase 2
Others
Drug Development Implication
Conclusions
PART ONE: Prodrug Design and Intellectual Property
PRODRUG STRATEGIES IN DRUG DESIGN
Prodrug Concept
Basics of Prodrug Design
Rationale for Prodrug Design
History of Prodrug Design
Recently Marketed Prodrugs
Concluding Remarks
THE MOLECULAR DESIGN OF PRODRUGS BY FUNCTIONAL GROUP
Introduction
The Prodrug Concept and Basics of Design
Common Functional Group Approaches in Prodrug Design
Conclusions
INTELLECTUAL PROPERTY PRIMER ON PHRAMACEUTICAL PATENTS WITH A SPECIAL EMPHASIS ON PRODRUGS AND METABOLITES
Introduction
Patents and FDA Approval Process
Obtaining a Patent
Conclusion
PART TWO: Prodrugs Addressing ADMET Issues
INCREADING LIPOPHILICITY FOR ORAL DRUG DELIVERY
Introduction
pKa, Degree of Ionization, Partition Coefficient, and Distribution Coefficient
Prodrug Strategies to Enhance Lipid Solubility
Prodrug Examples for Antibiotics
Antiviral Related Prodrugs
Cardiovascular Related Prodrugs
Lipophilic Prodrugs of Benzamidine Drugs
Miscellaneous Examples
Summary and Conclusion
MODULATING SOLUBILITY THROUGH PRODRUGS FOR ORAL AND IV DRUG DELIVERY
Introduction
Basics of Solubility and Oral/IV Drug Delivery
Prodrug Applications for Enhanced Aqueous Solubility
Challenges with Solubilizing Prodrugs of Insoluble Drugs
Additional Applications of Prodrugs for Modulating Solubility
Parallel Exploration of Analogues and Prodrugs in Drug Discovery (Commentary)
Conclusions
PRODRUGS DESIGNED TO TARGET TRANSPORTERS FOR ORAL DRUG DELIVERY
Introduction
Serendipity: An Actively Transported Prodrug
Requirements for Actively Transported Prodrugs
Peptide Transporters: PEPT1 and PEPT2
Monocarboxylate Transporters
Bile Acid Transporters
Conclusions
TOPICAL AND TRANSDERMAL DELIVERY USING PRODRUGS: MECHANISM OF ENHANCEMENT
Introduction
Arrangement of Water in the Stratum Corneum
A New Model for Diffusion Through the Stratum Corneum: The Biphasic Solubility Model
Equations for Quantifying Effects of Solubility on Diffusion Through the Stratum Corneum
Design of Prodrugs for Topical and Transdermal Delivery Based on the Biphasic Solubility Model
Comparison of Human and Mouse Skin Experiments
Summary
OCULAR DELIVERY USING PRODRUGS
Introduction
Criteria for an Ideal Ophthalmic Prodrug
Anatomy and Physiology of the Eye
Barriers to Ocular Drug Delivery
Influx and Efflux Transporters on the Eye
Transporter-Targeted Prodrug Approach
Drug Disposition in Ocular Delivery
Effect of Physiochemical Factors on Drug Disposition in Eye
Prodrug Strategy to Improve Ocular Bioavailability (Nontransporter-Targeted Approach)
Recent Patents and Marketed Ocular Prodrugs
Novel Formulation Approaches for Sustained Delivery of Prodrugs
Conclusion
REDUCING PRESYSTEMIC DRUG METABOLISM
Introduction
Presystemic Metabolic Barriers
Prodrug Approaches to Reduce Presystemic Drug Metabolism
Targeting Colon
Targeting Lymphatic Route
Conclusion
ENZYME-ACTIVATED PRODRUG STRATEGIES FOR SITE-SELECTIVE DRUG DELIVERY
Introduction
General Requirements for Enzyme-Activated Targeted Prodrug Strategy
Examples of Targeted Prodrug Strategies
Summary
PRODRUG APPROACHES FOR CENTRAL NERVOUS SYSTEM DELIVERY
Blood-Brain Barrier in CNS Drug Development
Prodrug Strategies
Prodrug Strategies Based Upon BBB Nutrient Transporters
Prodrug Strategies Based Upon BBB Receptors
CNS Prodrug Summary
DIRECTED ENZYME PRODRUG THERAPIES
Introduction
Theoretical Background of DEPT
Comparison of ADEPT and GDEPT
Enzymes in ADEPT and GDEPT
Design of Prodrugs
Strategies Used for the Improvement of DEPT Systems
Biological Data for ADEPT and GDEPT
Conclusions
PART THREE: Codrugs and Soft Drugs
IMPROVING THE USE OF DRUG COMBINATIONS THROUGH THE CODRUG APPROACH
Codrugs and Codrug Strategy
Ideal Codrug Characteristics
Examples of Marketed Codrugs
Topical Codrug Therapy for the Treatment of Ophthalmic Diseases
Codrugs for Transdermal Delivery
Codrugs of L-DOPA for the Treatment of Parkinson's Disease
Analgesic Codrugs Containing Nonsteroidal Anti-Inflammatory Agents
Analgesic Codrugs of Opioids and Cannabinoids
Codrugs Containing Anti-HIV Drugs
SOFT DRUGS
Introduction
Indications
Design Considerations
Case Study: The Discovery of Esmolol
Summary
PART FOUR: Preclinical and Clinical Considerations for Prodrugs
PHARMACOKINETIC AND BIOPHARMACEUTICAL CONSIDERATIONS IN PRODRUG DISCOVERY AND DEVELOPMENT
Introduction
Understanding Pharmacokinetic/Pharmacodynamic Relationships
Pharmacokinetics
Tools for the Prodrug Scientist
Enzymes Involved with Prodrug Conversion
Use of the Caco-2 System for Permeability and Active Transport Evaluation
XP13512: Improving PK Performance by Targeting Active Transport
Prodrug Absorption: Transport/Metabolic Conversion Interplay
Preabsorptive Degradation
Biopharmaceutical-Based PK Modeling for Prodrug Design
Conclusions
THE IMPACT OF PHARMACOGENETICS ON THE CLINICAL OUTCOMES OF PRODRUGS
Introduction
Clopidogrel and CYP2C19
Codeine and CYP2D6
Tamoxifen and CYP2D6
Fluorouracil Prodrugs and Carboxylesterase
Irinotecan and Carboxylesterase 2
Others
Drug Development Implication
Conclusions
Jarkko Rautio is professor of pharmaceutical chemistry and head of the multidisciplinary Pharmaceutical and Medicinal Chemistry (PMC) research group at the School of Pharmacy, University of Eastern Finland (formerly University of Kuopio), where he received his PhD in pharmaceutical chemistry in 2000. He subsequently carried out his postdoctoral studies at the University of Maryland, Baltimore, USA, and was a visiting scientist at GlaxoSmithKline, North Carolina, while also co-founding the American Association of Pharmaceutical Scientists (AAPS) Prodrug Focus Group in 2005. Professor Rautio's research focuses on chemistry-based methods, especially prodrugs, to overcome the liabilities of drugs.
