Perils of Polymorphism: Size Matters

Ward, Michael D.

doi:10.1002/ijch.201600071

Cited by 10 publications

(12 citation statements)

References 58 publications

(55 reference statements)

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“…McCrone postulated many years ago that the number of polymorphic forms found is generally proportional to the effort expended in finding them . Still, seeing ten true polymorphs of any molecule is rare, even for those which have been intensively screened. , A substantially greater effort had gone into finding different polymorphs of GAL than, for example, ROY, where as many as 7 of 11 polymorphs have crystallized concomitantly from the same liquid. ,, Yet, we did not resort to exotic techniques, such as heteronucleation onto isostructural templates , or polymers, crystallization from complex mixtures, , or nucleation under confinement , to produce ten different polymorphs. All of the neat forms of GAL , with the notable exception of form X, were produced by conventional methods adapted to the formation of multiple solvates.…”

Section: Discussionmentioning

confidence: 99%

A Prolific Solvate Former, Galunisertib, under the Pressure of Crystal Structure Prediction, Produces Ten Diverse Polymorphs

et al. 2019

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The solid form screening of galunisertib produced many solvates, prompting an extensive investigation into possible risks to the development of the favored monohydrate form. Inspired by crystal structure prediction, the search for neat polymorphs was expanded to an unusual range of experiments, including melt crystallization under pressure, to work around solvate formation and the thermal instability of the molecule. Ten polymorphs of galunisertib were found; however, the structure predicted to be the most stable has yet to be obtained. We present the crystal structures of all ten unsolvated polymorphs of galunisertib, showing how state-of-the-art characterization methods can be combined with emerging computational modeling techniques to produce a complete structure landscape and assess the risk of lateappearing, more stable polymorphs. The exceptional conformational polymorphism of this prolific solvate former invites further development of methods, computational and experimental, that are applicable to larger, flexible molecules with complex solid form landscapes.

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Section: Discussionmentioning

confidence: 99%

A Prolific Solvate Former, Galunisertib, under the Pressure of Crystal Structure Prediction, Produces Ten Diverse Polymorphs

et al. 2019

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“…This could be possible as crystallisation in the confinement of nanopores can result in a change in the stability ranking of polymorphs. 9,51,52 Nonetheless, we do not believe that this is the case here. Another explanation would be that the β form requires homogeneous nucleation, which would be in the absence of surface or foreign particles.…”

Section: Resultsmentioning

confidence: 68%

Crystallisation in printed droplets: understanding crystallisation of d-mannitol polymorphs

2019

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“…The relative stability of polymorphs can depend on the size of the crystal [ 72 ] and solvent at nanoscale sizes where the proportion of surface to bulk molecules is not negligible. This can help explain why confinement in nano-pores or droplets can affect the polymorph formed [ 73 ]. However, the observation of metastable polymorphs in tiny droplets can just reflect the inhibition of the transformation or lack of replenishment of the supersaturation [ 74 ].…”

Section: Why Does Csp Often Over-predict Polymorphism?mentioning

confidence: 99%

Control and prediction of the organic solid state: a challenge to theory and experiment

Price¹

2018

Proc. R. Soc. A.

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The ability of theoretical chemists to quantitatively model the weak forces between organic molecules is being exploited to predict their crystal structures and estimate their physical properties. Evolving crystal structure prediction methods are increasingly being used to aid the design of organic functional materials and provide information about thermodynamically plausible polymorphs of speciality organic materials to aid, for example, pharmaceutical development. However, the increasingly sophisticated experimental studies for detecting the range of organic solid-state behaviours provide many challenges for improving quantitative theories that form the basis for the computer modelling. It is challenging to calculate the relative thermodynamic stability of different organic crystal structures, let alone understand the kinetic effects that determine which polymorphs can be observed and are practically important. However, collaborations between experiment and theory are reaching the stage of devising experiments to target the first crystallization of new polymorphs or create novel organic molecular materials.

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Perils of Polymorphism: Size Matters

Cited by 10 publications

References 58 publications

A Prolific Solvate Former, Galunisertib, under the Pressure of Crystal Structure Prediction, Produces Ten Diverse Polymorphs

A Prolific Solvate Former, Galunisertib, under the Pressure of Crystal Structure Prediction, Produces Ten Diverse Polymorphs

Crystallisation in printed droplets: understanding crystallisation of d-mannitol polymorphs

Control and prediction of the organic solid state: a challenge to theory and experiment

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