Towards crystal structure prediction of complex organic compounds--a report on the fifth blind test.

David A Bardwell,John Kendrick,Louise S Price,Claire S Adjiman,Fridolin Hofmann,Sharmarke Mohamed,Anita M Orendt,Andrei V Kazantsev,Tejender S Thakur,Graeme M Day,Constantinos C Pantelides,Jacco Van De Streek,Gautam R Desiraju,K V Jovan Jose,Harold A Scheraga,Marcus A Neumann,Julio C Facelli,Alston J Misquitta,Detlef W M Hofmann,Denis Nikylov,Panagiotis G Karamertzanis,Sarah L Price,Rumpa Pal,Yelena A Arnautova,Marta B Ferraro,Matthew Habgood,Frank J J Leusen,Siddharth Tiwari,Elisabetta Venuti,Chris J Pickard,Doris E Braun,Stephan X M Boerrigter,Damián Grillo ,Aurora J Cruz‐Cabeza ,R J Needs ,L N Kuleshova ,Raffaele Guido Della Valle ,A V Maleev ,Е В Барташевич ,B.p Van Eijck ,I K Zhitkov

doi:10.1107/s0108768111042868

Abstract

Following on from the success of the previous crystal structure prediction blind tests (CSP1999, CSP2001, CSP2004 and CSP2007), a fifth such collaborative project (CSP2010) was organized at the Cambridge Crystallographic Data Centre. A range of methodologies was used by the participating groups in order to evaluate the ability of the current computational methods to predict the crystal structures of the six organic molecules chosen as targets for this blind test. The first four targets, two rigid molecules, one semi-flexible molecule and a 1:1 salt, matched the criteria for the targets from CSP2007, while the last two targets belonged to two new challenging categories - a larger, much more flexible molecule and a hydrate with more than one polymorph. Each group submitted three predictions for each target it attempted. There was at least one successful prediction for each target, and two groups were able to successfully predict the structure of the large flexible molecule as their first place submission. The results show that while not as many groups successfully predicted the structures of the three smallest molecules as in CSP2007, there is now evidence that methodologies such as dispersion-corrected density functional theory (DFT-D) are able to reliably do so. The results also highlight the many challenges posed by more complex systems and show that there are still issues to be overcome.

Highlights

This paper reports on the results of the fifth blind test of crystal structure prediction (CSP), an international test hosted periodically by the Cambridge Crystallographic Data Centre (CCDC)
Crystal structure search + energy minimization 2 intel1 core2 i5cpu 750 at 2.67 GHz processors and each has 2 GB of memory AIRSS/DFT-D search: 130 000 core hours First search using structures obtained with FIT+Q potential: 30 000 core hours Post-Blind test analysis: < 2000 core hours Calculations were carried out on Intel Xeon 2.4 GHz processors (XVI:) 150 h (XVII): 150 h (XVIII): 610 h (XIX): 720 h
For each of the six target crystal structures, there was at least one successful prediction under the criteria stated for success at the start of the test [ for the hydrate (XXI) certain protons were incorrectly placed]

Summary

Introduction

This paper reports on the results of the fifth blind test of crystal structure prediction (CSP), an international test hosted periodically by the Cambridge Crystallographic Data Centre (CCDC). The grand aim is to develop the ability to reliably predict, by computational methods, how a molecule will crystallize in the solid state, with only the chemical diagram and the crystallization conditions known. This would allow for the prediction of solid-state properties before the molecule or molecules in question had even been synthesized, and could help determine the likelihood that different polymorphic forms, or as yet unseen polymorphs of currently known structures, exist. This application is of particular importance in the pharmaceutical industry where the presence of different polymorphs can lead to very different and potentially undesirable physical properties of new drugs

Results

Discussion

Conclusion