Integrating the Impact of Lipophilicity on Potency and Pharmacokinetic Parameters Enables the Use of Diverse Chemical Space during Small Molecule Drug Optimization

Miller, Randy R.; Madeira, Maria; Wood, Harold B.; Geissler, Wayne M.; Raab, Conrad E.; Martin, Iain

doi:10.1021/acs.jmedchem.9b01813

Cited by 67 publications

(65 citation statements)

References 65 publications

(128 reference statements)

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“…This method is not without its limitations, since alterations to lipophilicity has a downstream impact on the PK properties of a molecule. [125,126] Therefore, increasing hydrophilicity might not always be a suitable method if improving solubility. In these instances, an alternative strategy involves reducing molecular planarity and symmetry, thus disrupting crystal packing, and reducing the energy barrier to dissolution.…”

Section: Hydrophilicity Hydrophobicity and Solubilitymentioning

confidence: 99%

Into the Fray! A Beginner's Guide to Medicinal Chemistry

Veale

2021

ChemMedChem

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Modern medicinal chemistry is a complex, multidimensional discipline that operates at the interface of the chemical and biological sciences. The medicinal chemistry contribution to drug discovery is typically described in the context of the wellrecited linear progression of the drug discovery pipeline. However, compound optimization is idiosyncratic to each project, and clear definitions of hit and lead molecules and the subsequent progress along the pipeline becomes easily blurred. In addition, this description lacks insight into the entangled relationship between chemical and pharmacological properties, and thus provides limited guidance on how innovative medicinal chemistry strategies can be applied to solve optimization problems, regardless of the stage in the pipeline. Through discussion and illustrative examples, this article seeks to provide insights into the finesse of medicinal chemistry and the subtlety of balancing chemical properties pharmacology. In so doing, it aims to serve as an accessible and simple-to-digest guide for anyone who wishes to learn about the underlying principles of medicinal chemistry, in a context that has been decoupled from the pipeline description.

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Section: Hydrophilicity Hydrophobicity and Solubilitymentioning

confidence: 99%

Into the Fray! A Beginner's Guide to Medicinal Chemistry

Veale

2021

ChemMedChem

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“…Thus, log P N has been used for predicting the ability of bioorganic compounds to cross cell membranes [ 3 ]. Nowadays, it is still being used for assessing the impact on pharmacokinetic parameters and potency [ 4 ], metabolism and excretion[ 5 , 6 ], and toxicity [ 7 ] of research compounds.…”

Section: Introductionmentioning

confidence: 99%

Multiple linear regression models for predicting the n‑octanol/water partition coefficients in the SAMPL7 blind challenge

Lopez

Pinheiro

Zamora

2021

J Comput Aided Mol Des

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A multiple linear regression model called MLR-3 is used for predicting the experimental n-octanol/water partition coefficient (log P N ) of 22 N-sulfonamides proposed by the organizers of the SAMPL7 blind challenge. The MLR-3 method was trained with 82 molecules including drug-like sulfonamides and small organic molecules, which resembled the main functional groups present in the challenge dataset. Our model, submitted as "TFE-MLR", presented a root-mean-square error of 0.58 and mean absolute error of 0.41 in log P units, accomplishing the highest accuracy, among empirical methods and also in all submissions based on the ranked ones. Overall, the results support the appropriateness of multiple linear regression approach MLR-3 for computing the n-octanol/water partition coefficient in sulfonamide-bearing compounds. In this context, the outstanding performance of empirical methodologies, where 75% of the ranked submissions achieved root-mean-square errors < 1 log P units, support the suitability of these strategies for obtaining accurate and fast predictions of physicochemical properties as partition coefficients of bioorganic compounds.

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“…14 We hypothesize that the cellular assay does not accurately reflect the complex tissue environment where TRPA1 channels reside in vivo and that lower lipophilicity compounds may possess a decreased ability to access the membrane-bound TRPA1 channel within the target tissues. 21 In support of this hypothesis, we noticed that larger in vivo potency shifts correlated with lower measured log D 7.4 . While log D 7.4 is a common measure of bulk hydrophobicity, it does not accurately model interactions with zwitterionic phospholipids (i.e., phospholipophilicity) which may impact target access for TRPA1 antagonists bound at the membrane.…”

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confidence: 99%

“…22 We thought that unbound volume of distribution (V ss,u = V ss /f u ), an in vivo measure of drug distribution in the body, might be a better reflection of the overall tissue (i.e., membrane) binding. 21,23,24 Using rat PK data, we found that molecules with a higher V ss,u possess a reduced potency shift in vivo (see data Table 1). While both log D 7.4 and V ss,u show similar trends, we found V ss,u to be a useful measure of in vivo lipophilicity that helped reconcile PKPD disconnects observed in the program.…”

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confidence: 99%

A Retrospective Look at the Impact of Binding Site Environment on the Optimization of TRPA1 Antagonists

Villemure¹,

Terrett²,

Larouche‐Gauthier

et al. 2021

ACS Med. Chem. Lett.

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Transient receptor potential ankyrin 1 (TRPA1) antagonists have generated broad interest in the pharmaceutical industry for the treatment of both pain and asthma. Over the past decade, multiple antagonist classes have been reported in the literature with a wide range of structural diversity. Our own work has focused on the development of proline sulfonamide and hypoxanthine-based antagonists, two antagonist classes with distinct physicochemical properties and pharmacokinetic (PK) trends. Late in our discovery program, cryogenic electron microscopy (cryoEM) studies revealed two different antagonist binding sites: a membrane-exposed proline sulfonamide transmembrane site and an intracellular hypoxanthine site near the membrane interface. A retrospective look at the discovery program reveals how the different binding sites, and their location relative to the cell membrane, influenced the optimization trajectories and overall drug profiles of each antagonist class.

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Integrating the Impact of Lipophilicity on Potency and Pharmacokinetic Parameters Enables the Use of Diverse Chemical Space during Small Molecule Drug Optimization

Cited by 67 publications

References 65 publications

Into the Fray! A Beginner's Guide to Medicinal Chemistry

Into the Fray! A Beginner's Guide to Medicinal Chemistry

Multiple linear regression models for predicting the n‑octanol/water partition coefficients in the SAMPL7 blind challenge

A Retrospective Look at the Impact of Binding Site Environment on the Optimization of TRPA1 Antagonists

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