Elucidating an Amorphous Form Stabilization Mechanism for Tenapanor Hydrochloride: Crystal Structure Analysis Using X-ray Diffraction, NMR Crystallography, and Molecular Modeling

Lill, Sten O. Nilsson; Widdifield, Cory M.; Pettersen, Anna; Ankarberg, Anna Svensk; Lindkvist, Maria; Aldred, Peter; Gracin, Sandra; Shankland, Norman; Shankland, Kenneth; Schantz, Staffan; Emsley, Lyndon

doi:10.1021/acs.molpharmaceut.7b01047

Cited by 36 publications

(31 citation statements)

References 60 publications

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“…A revolution in solid-state NMR has occurred with the introduction of accurate methods to calculate chemical shifts 1 – 3 , in particular using plane wave density functional theory (DFT) methods developed for periodic systems based on the projected augmented wave (PAW)/gauge including PAW (GIPAW) approach 4 – 6 . This has enabled very rapid development of chemical shift-based NMR crystallography, which is now widely used to validate structures of molecular solids and identify known polymorphs 7 – 26 , or more recently in combination with crystal structure prediction (CSP) protocols, to determine de novo crystal structures from powders 27 – 32 . Recent studies also suggest that the structural accuracy of chemical shift-based solid-state NMR crystallography is at least comparable with more traditional methods, such as single crystal X-ray diffraction 33 .…”

Section: Introductionmentioning

confidence: 99%

Chemical shifts in molecular solids by machine learning

et al. 2018

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Due to their strong dependence on local atonic environments, NMR chemical shifts are among the most powerful tools for strucutre elucidation of powdered solids or amorphous materials. Unfortunately, using them for structure determination depends on the ability to calculate them, which comes at the cost of high accuracy first-principles calculations. Machine learning has recently emerged as a way to overcome the need for quantum chemical calculations, but for chemical shifts in solids it is hindered by the chemical and combinatorial space spanned by molecular solids, the strong dependency of chemical shifts on their environment, and the lack of an experimental database of shifts. We propose a machine learning method based on local environments to accurately predict chemical shifts of molecular solids and their polymorphs to within DFT accuracy. We also demonstrate that the trained model is able to determine, based on the match between experimentally measured and ML-predicted shifts, the structures of cocaine and the drug 4-[4-(2-adamantylcarbamoyl)-5-tert-butylpyrazol-1-yl]benzoic acid.

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Section: Introductionmentioning

confidence: 99%

Chemical shifts in molecular solids by machine learning

et al. 2018

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“…This approach was the subject of recent reviews by Ashbrook et al [5] and by Bryce [6]. Additionally, some of its notable applications were most recently discussed by Brown et al [7] and by Emsley et al [8]. Our group successfully employed NMR crystallography in the structural elucidation/refinement of framework materials [9], bioactive compounds [10], and drugs [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

NMR Crystallography of the Polymorphs of Metergoline

2018

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Two polymorphs of the drug compound metergoline (C25H29N3O2) were investigated in detail by solid-state NMR measurements. The results have been analysed by an advanced procedure, which uses experimental input together with the results of quantum chemical calculations that were performed for molecular crystals. In this way, it was possible to assign the total of 40 1H–13C correlation pairs in a highly complex system, namely, in the dynamically disordered polymorph with two independent molecules in the unit cell of a large volume of 4234 Å3. For the simpler polymorph, which exhibits only small-amplitude motions and has just one molecule in the unit cell with a volume of 529.0 Å3, the values of the principal elements of the 13C chemical shift tensors were measured. Additionally, for this polymorph, a set of crystal structure predictions were generated, and the {13C, 1H} isotropic and 13C anisotropic chemical shielding data were computed while using the gauge-including projector augmented-wave approach combined with the “revised Perdew-Burke-Ernzerhof“ exchange-correlation functional (GIPAW-RPBE). The experimental and theoretical results were combined in an application of the newly developed strategy to polymorph discrimination. This research thus opens up new routes towards more accurate characterization of the polymorphism of drug formulations.

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“…Nowadays various drug delivery systems are developed and in many aspects the research in this field can be supported by theoretical calculations [117,118]. This means from one side, the description of API, which could change its molecular structure, for example, upon uploading into drug carriers, as it takes place in case of ellipticine [119].…”

Section: Drug Delivery Systemsmentioning

confidence: 99%

Periodic DFT Calculations—Review of Applications in the Pharmaceutical Sciences

2020

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In the introduction to this review the complex chemistry of solid-state pharmaceutical compounds is summarized. It is also explained why the density functional theory (DFT) periodic calculations became recently so popular in studying the solid APIs (active pharmaceutical ingredients). Further, the most popular programs enabling DFT periodic calculations are presented and compared. Subsequently, on the large number of examples, the applications of such calculations in pharmaceutical sciences are discussed. The mentioned topics include, among others, validation of the experimentally obtained crystal structures and crystal structure prediction, insight into crystallization and solvation processes, development of new polymorph synthesis ways, and formulation techniques as well as application of the periodic DFT calculations in the drug analysis.

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Elucidating an Amorphous Form Stabilization Mechanism for Tenapanor Hydrochloride: Crystal Structure Analysis Using X-ray Diffraction, NMR Crystallography, and Molecular Modeling

Cited by 36 publications

References 60 publications

Chemical shifts in molecular solids by machine learning

Chemical shifts in molecular solids by machine learning

NMR Crystallography of the Polymorphs of Metergoline

Periodic DFT Calculations—Review of Applications in the Pharmaceutical Sciences

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