Eleanor R. Turpin scite author profile

The problem of predicting small molecule-polymer compatibility is relevant to many areas of chemistry and pharmaceutical science but particularly drug delivery. Computational methods based on Hildebrand and Hansen solubility parameters, and the estimation of the Flory-Huggins parameter, χ, have proliferated across the literature. Focusing on the need to develop amorphous solid dispersions to improve the bioavailability of poorly soluble drug candidates, an innovative, high-throughput 2D printing method has been employed to rapidly assess the compatibility of 54 drug-polymer pairings (nine drug compounds in six polymers). In this study, the first systematic assessment of the in silico methods for this application, neither the solubility parameter approach nor the calculated χ, correctly predicted drug-polymer compatibility. The theoretical limitations of the solubility parameter approach are discussed and used to explain why this approach is fundamentally unsuitable for predicting polymer-drug interactions. Examination of the original sources describing the method for calculating χ shows that only the enthalpic contributions to the term have been included, and the corrective entropic term is absent. The development and application of new in silico techniques, that consider all parts of the free energy of mixing, are needed in order to usefully predict small molecule-polymer compatibility and to realize the ambition of a drug-polymer screening method.

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New N-acyl amino acid-functionalized biodegradable polyesters for pharmaceutical and biomedical applications

Taresco

Suksiriworapong

Styliari

et al. 2016

RSC Adv.

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New CHARMM force field parameters for dehydrated amino acid residues, the key to lantibiotic molecular dynamics simulations

et al. 2014

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Cooperativity and Site Selectivity in the Ileal Lipid Binding Protein

et al. 2013

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The ileal lipid binding protein (ILBP or I-BABP) binds bile salts with positive cooperativity and has unusual site selectivity, whereby cholic acid binds preferentially in one site and chenodeoxycholic in another, despite both sites having an affinity for both ligands and the ligands only differing by a single hydroxyl group. Previous studies of the human variant have assumed that the ligand/protein binding ratio is 2:1, but we show, using electrospray ionization mass spectroscopy, that human ILBP binds bile acids with a 3:1 ratio, even at low protein and ligand concentrations. Docking calculations and molecular dynamics (MD) simulations identify an allosterically active binding site on the protein exterior that induces a change from a closed conformation to an open one, characterized by a movement of one of the α-helices by ~10° with respect to the β-clam shell. Additional independent MD simulations of several hundred nanoseconds implicate the change between conformations in the mechanisms of both cooperativity and ligand site selectivity.

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Eleanor R. Turpin

In Silico Screening for Solid Dispersions: The Trouble with Solubility Parameters and χFH

New N-acyl amino acid-functionalized biodegradable polyesters for pharmaceutical and biomedical applications

New CHARMM force field parameters for dehydrated amino acid residues, the key to lantibiotic molecular dynamics simulations

Cooperativity and Site Selectivity in the Ileal Lipid Binding Protein

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