Abstract
Despite the numerous scientific and technological advances made within the last decade the attrition rates for new drug discovery remain as high as 95% for anticancer drugs. Recent drug development has been in part guided by Lipinski’s Rule of 5 (Ro5) even though many approved drugs do not comply to these rules. With Covid-19 vaccine development strategy dramatically accelerating drug development perhaps it is timely to question the generic drug development process itself to find a more efficient, cost effective, and successful approach. It is widely believed that drugs permeate cells via two methods: phospholipid bilayer diffusion and carrier mediated transporters. However, emerging evidence suggests that carrier mediated transport may be the primary mechanism of drug uptake and not diffusion as long believed. Computational biology increasingly assists drug design to achieve desirable absorption, distribution, metabolism, elimination and toxicity (ADMET) properties. Perfecting drug entry into target cells as a prerequisite to intracellular drug action is a logical and compelling route and is expected to reduce drug attrition rates, particularly gaining favour amongst chronic lifelong therapeutics. Novel drug development is rapidly expanding from the utilisation of beyond the rule of five (bRo5) to pulsatile drug delivery systems and fragment based drug design. Utilising transporters as drug targets and advocating bRo5 molecules may be the solution to increasing drug specificity, reducing dosage and toxicity and thus revolutionising drug development. This review explores the development of cell surface transporter exploitation in drug development and the relationship with improved therapeutic index.
Highlights
Cell Surface Transporters and Novel Drug DevelopmentsSpecialty section: This article was submitted to Drug Metabolism and Transport, a section of the journal Frontiers in Pharmacology
This review explores the development of cell surface transporter exploitation in drug development and the relationship with improved therapeutic index
In 1997 Lipinski’s rule of 5 (Ro5) helped transform the world of drug development, stating that poor permeation/absorption is likely if a drug has more than 5 H bond donors (HBD), 10 H bond acceptors (HBA), a molecular weight (MW) greater than 500 Da or a calculated logP value greater than 5 (Benet et al, 2016)
Summary
Specialty section: This article was submitted to Drug Metabolism and Transport, a section of the journal Frontiers in Pharmacology. In 1997 Lipinski’s rule of 5 (Ro5) helped transform the world of drug development, stating that poor permeation/absorption is likely if a drug has more than 5 H bond donors (HBD), 10 H bond acceptors (HBA), a molecular weight (MW) greater than 500 Da or a calculated logP value (water: octanol partition) greater than 5 (Benet et al, 2016). There have been statistically significant increases for MW and HBA whilst HBD and cLogP have remained fairly constant (Shultz, 2019), such that 50% of current orally administered drugs do not obey Lipinski’s rule (Zhang and Wilkinson, 2007) whilst the increase in FDA approved oral drugs since 1997 is wholly due to molecules with a molecular weight (MW) greater than 500 Da. Modern day “drug like” properties have changed greatly over recent decades, and away from those originally specified in the Ro5
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