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Minimizing polymorphic risk through cooperative computational and experimental exploration

Minimizing polymorphic risk through cooperative computational and experimental exploration
Minimizing polymorphic risk through cooperative computational and experimental exploration
We combine state-of-the-art computational crystal structure prediction (CSP) techniques with a wide range of experimental crystallization methods to understand and explore crystal structure in pharmaceuticals and minimize the risk of unanticipated late-appearing polymorphs. Initially, we demonstrate the power of CSP to rationalize the difficulty in obtaining polymorphs of the well-known pharmaceutical isoniazid and show that CSP provides the structure of the recently obtained, but unsolved, Form III of this drug despite there being only a single resolved form for almost 70 years. More dramatically, our blind CSP study predicts a significant risk of polymorphism for the related iproniazid. Employing a wide variety of experimental techniques, including high-pressure experiments, we experimentally obtained the first three known non-solvated crystal forms of iproniazid, all of which were successfully predicted in the CSP procedure. We demonstrate the power of CSP methods and free energy calculations to rationalize the observed elusiveness of the third form of iproniazid, the success of high-pressure experiments in obtaining it, and the ability of our synergistic computational-experimental approach to “de-risk” solid form landscapes.
0002-7863
16668-16680
Taylor, Christopher
95bebf3a-a98a-453c-acb6-aebc451bd5a8
Mulvee, Matthew T.
c1a663af-73d4-4902-b077-5e9497e9b10d
Perenyi, Domonkos S.
8a225392-81a6-4cac-9329-a532acde3258
Probert, Michael R.
a86a95c0-5692-4e4c-9279-a02faf70274c
Day, Graeme M.
e3be79ba-ad12-4461-b735-74d5c4355636
Steed, Jonathan
6863ad93-90f1-4e8c-8915-d1455542beee
Taylor, Christopher
95bebf3a-a98a-453c-acb6-aebc451bd5a8
Mulvee, Matthew T.
c1a663af-73d4-4902-b077-5e9497e9b10d
Perenyi, Domonkos S.
8a225392-81a6-4cac-9329-a532acde3258
Probert, Michael R.
a86a95c0-5692-4e4c-9279-a02faf70274c
Day, Graeme M.
e3be79ba-ad12-4461-b735-74d5c4355636
Steed, Jonathan
6863ad93-90f1-4e8c-8915-d1455542beee

Taylor, Christopher, Mulvee, Matthew T., Perenyi, Domonkos S., Probert, Michael R., Day, Graeme M. and Steed, Jonathan (2020) Minimizing polymorphic risk through cooperative computational and experimental exploration. Journal of the American Chemical Society, 142 (39), 16668-16680. (doi:10.1021/jacs.0c06749).

Record type: Article

Abstract

We combine state-of-the-art computational crystal structure prediction (CSP) techniques with a wide range of experimental crystallization methods to understand and explore crystal structure in pharmaceuticals and minimize the risk of unanticipated late-appearing polymorphs. Initially, we demonstrate the power of CSP to rationalize the difficulty in obtaining polymorphs of the well-known pharmaceutical isoniazid and show that CSP provides the structure of the recently obtained, but unsolved, Form III of this drug despite there being only a single resolved form for almost 70 years. More dramatically, our blind CSP study predicts a significant risk of polymorphism for the related iproniazid. Employing a wide variety of experimental techniques, including high-pressure experiments, we experimentally obtained the first three known non-solvated crystal forms of iproniazid, all of which were successfully predicted in the CSP procedure. We demonstrate the power of CSP methods and free energy calculations to rationalize the observed elusiveness of the third form of iproniazid, the success of high-pressure experiments in obtaining it, and the ability of our synergistic computational-experimental approach to “de-risk” solid form landscapes.

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Accepted/In Press date: 8 September 2020
e-pub ahead of print date: 8 September 2020
Published date: 30 September 2020

Identifiers

Local EPrints ID: 443835
URI: http://eprints.soton.ac.uk/id/eprint/443835
DOI: doi:10.1021/jacs.0c06749
ISSN: 0002-7863
PURE UUID: b11a7b04-2bb9-4622-881a-8de627ba66eb
ORCID for Christopher Taylor: ORCID iD orcid.org/0000-0001-9465-5742
ORCID for Graeme M. Day: ORCID iD orcid.org/0000-0001-8396-2771

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Date deposited: 14 Sep 2020 16:36
Last modified: 17 Mar 2024 03:37

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Contributors

Author: Christopher Taylor ORCID iD
Author: Matthew T. Mulvee
Author: Domonkos S. Perenyi
Author: Michael R. Probert
Author: Graeme M. Day ORCID iD
Author: Jonathan Steed

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