Reducing Crystal Structure Overprediction of Ibuprofen with Large Scale Molecular Dynamics Simulations

Crystal Structures ◽

Finite Temperature ◽

Structure Prediction ◽

Large Scale ◽

Lattice Energy ◽

Racemic Mixture ◽

The control of the crystal form is a central issue in the pharmaceutical industry. The identification of putative polymorphs through Crystal Structure Prediction (CSP) methods is based on lattice energy calculations, which are known to significantly over-predict the number of plausible crystal structures. A valuable tool to reduce overprediction is to employ physics-based, dynamic simulations to coalesce lattice energy minima separated by small barriers into a smaller number of more stable geometries once thermal effects are introduced. Molecular dynamics simulations and enhanced sampling methods can be employed in this context to simulate crystal structures at finite temperature and pressure. Here we demonstrate the applicability of approaches based on molecular dynamics to systematically process realistic CSP datasets containing several hundreds of crystal structures. The system investigated is ibuprofen, a conformationally flexible active pharmaceutical ingredient that crystallises both in enantiopure forms and as a racemic mixture. By introducing a hierarchical approach in the analysis of finite-temperature supercell configurations, we can post-process a dataset of 555 crystal structures, identifying 65% of the initial structures as labile, while maintaining all the experimentally known crystal structures in the final, reduced set. Moreover, the extensive nature of the initial dataset allows one to gain quantitative insight into the persistence and the propensity to transform of crystal structures containing common hydrogen-bonded intermolecular interaction motifs.

Reducing Crystal Structure Overprediction of Ibuprofen with Large Scale Molecular Dynamics Simulations

CrystEngComm ◽

10.1039/d1ce00616a ◽

2021 ◽

Author(s):

Nicholas Francesco Francia ◽

Louise Price ◽

Matteo Salvalaglio

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Pharmaceutical Industry ◽

Structure Prediction ◽

Large Scale ◽

Lattice Energy ◽

Crystal Form ◽

Crystal Structure Prediction ◽

The control of the crystal form is a central issue in the pharmaceutical industry. The identification of putative polymorphs through Crystal Structure Prediction (CSP) methods is based on lattice energy...

Systematic Finite-Temperature Reduction of Crystal Energy Landscapes.

10.26434/chemrxiv.12609833.v1 ◽

2020 ◽

Author(s):

Nicholas Francia ◽

Louise S. Price ◽

Jonas Nyman ◽

Sarah (Sally) Price ◽

Matteo Salvalaglio

Keyword(s):

Molecular Dynamics ◽

Finite Temperature ◽

Structure Prediction ◽

Lattice Energy ◽

Biased Sampling ◽

Energy Landscapes ◽

Polymorphic Transformations ◽

Temperature And Pressure ◽

Dynamics Simulations ◽

The Impact

Crystal structure prediction methods are prone to overestimate the number of potential polymorphs of organic molecules. In this work, we aim to reduce the overprediction by systematically applying molecular dynamics simulations and biased sampling methods to cluster subsets of structures that can easily interconvert at finite temperature and pressure. Following this approach, we rationally reduce the number of predicted putative polymorphs in CSP-generated crystal energy landscapes. This uses an unsupervised clustering approach to analyze independent finite-temperature molecular dynamics trajectories and hence identify a representative structure of each cluster of distinct lattice energy minima that are effectively equivalent at finite temperature and pressure. Biased simulations are used to reduce the impact of limited sampling time and to estimate the work associated with polymorphic transformations. We demonstrate the proposed systematic approach by studying the polymorphs of urea and succinic acid, reducing an initial set of over 100 energetically plausible CSP structures to 12 and 27 respectively, including the experimentally known polymorphs. The simulations also indicate the types of disorder and stacking errors that may occur in real structures.

Systematic Finite-Temperature Reduction of Crystal Energy Landscapes.

10.26434/chemrxiv.12609833 ◽

2020 ◽

Author(s):

Nicholas Francia ◽

Louise S. Price ◽

Jonas Nyman ◽

Sarah (Sally) Price ◽

Matteo Salvalaglio

Keyword(s):

Molecular Dynamics ◽

Finite Temperature ◽

Structure Prediction ◽

Lattice Energy ◽

Biased Sampling ◽

Energy Landscapes ◽

Polymorphic Transformations ◽

Temperature And Pressure ◽

Dynamics Simulations ◽

The Impact

Crystal structure prediction methods are prone to overestimate the number of potential polymorphs of organic molecules. In this work, we aim to reduce the overprediction by systematically applying molecular dynamics simulations and biased sampling methods to cluster subsets of structures that can easily interconvert at finite temperature and pressure. Following this approach, we rationally reduce the number of predicted putative polymorphs in CSP-generated crystal energy landscapes. This uses an unsupervised clustering approach to analyze independent finite-temperature molecular dynamics trajectories and hence identify a representative structure of each cluster of distinct lattice energy minima that are effectively equivalent at finite temperature and pressure. Biased simulations are used to reduce the impact of limited sampling time and to estimate the work associated with polymorphic transformations. We demonstrate the proposed systematic approach by studying the polymorphs of urea and succinic acid, reducing an initial set of over 100 energetically plausible CSP structures to 12 and 27 respectively, including the experimentally known polymorphs. The simulations also indicate the types of disorder and stacking errors that may occur in real structures.

Water structure in solution and crystal molecular dynamics simulations compared to protein crystal structures

RSC Advances ◽

10.1039/c9ra09601a ◽

2020 ◽

Vol 10 (14) ◽

pp. 8435-8443

Author(s):

Octav Caldararu ◽

Majda Misini Ignjatović ◽

Esko Oksanen ◽

Ulf Ryde

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Crystal Structures ◽

Water Structure ◽

Protein Crystal ◽

Local Clustering ◽

Dynamics Simulations ◽

Structure In Solution

Molecular dynamics simulations can reproduce the water structure around proteins in crystal structure only if a local clustering is performed.

Exploring New Crystal Structures of Glycine via Electric Field-Induced Structural Transformations with Molecular Dynamics Simulations

Processes ◽

10.3390/pr7050268 ◽

2019 ◽

Vol 7 (5) ◽

pp. 268 ◽

Cited By ~ 2

Author(s):

Pelin Su Bulutoglu ◽

Conor Parks ◽

Nandkishor K. Nere ◽

Shailendra Bordawekar ◽

Doraiswami Ramkrishna

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Solid State ◽

Electric Field ◽

Physical Properties ◽

Crystal Structures ◽

Electric Fields ◽

High Intensity ◽

Being able to control polymorphism of a crystal is of great importance to many industries, including the pharmaceutical industry, since the crystal’s structure determines significant physical properties of a material. While there are many conventional methods used to control the final crystal structure that comes out of a crystallization unit, these methods fail to go beyond a few known structures that are kinetically accessible. Recent studies have shown that externally applied fields have the potential to effectively control polymorphism and to extend the set of observable polymorphs that are not accessible through conventional methods. This computational study focuses on the application of high-intensity dc electric fields (e-fields) to induce solid-state transformation of glycine crystals to obtain new polymorphs that have not been observed via experiments. Through molecular dynamics simulations of solid-state α -, β -, and γ -glycine crystals, it has been shown that the new polymorphs sustain their structures within 125 ns after the electric field has been turned off. It was also demonstrated that strength and direction of the electric field and the initial structure of the crystal are parameters that affect the resulting polymorph. Our results showed that application of high-intensity dc electric fields on solid-state crystals can be an effective crystal structure control method for the exploration of new crystal structures of known materials and to extend the range of physical properties a material can have.

The relationship between water bridges and the polyproline II conformation: a large-scale analysis of molecular dynamics simulations and crystal structures

Protein Engineering Design and Selection ◽

10.1093/protein/gzp069 ◽

2009 ◽

Vol 23 (1) ◽

pp. 27-33 ◽

Cited By ~ 16

Author(s):

Peter B. Law ◽

Valerie Daggett

Keyword(s):

Molecular Dynamics ◽

Crystal Structures ◽

Large Scale ◽

Scale Analysis ◽

Polyproline Ii ◽

Large Scale Analysis ◽

Dynamics Simulations ◽

The Relationship ◽

Water Bridges

Systematic Finite-Temperature Reduction of Crystal Energy Landscapes.

10.26434/chemrxiv.12609833.v2 ◽

2020 ◽

Author(s):

Nicholas Francia ◽

Louise S. Price ◽

Jonas Nyman ◽

Sarah (Sally) Price ◽

Matteo Salvalaglio

Keyword(s):

Molecular Dynamics ◽

Finite Temperature ◽

Structure Prediction ◽

Lattice Energy ◽

Biased Sampling ◽

Energy Landscapes ◽

Polymorphic Transformations ◽

Temperature And Pressure ◽

Dynamics Simulations ◽

The Impact

Crystal structure prediction methods are prone to overestimate the number of potential polymorphs of organic molecules. In this work, we aim to reduce the overprediction by systematically applying molecular dynamics simulations and biased sampling methods to cluster subsets of structures that can easily interconvert at finite temperature and pressure. Following this approach, we rationally reduce the number of predicted putative polymorphs in CSP-generated crystal energy landscapes. This uses an unsupervised clustering approach to analyze independent finite-temperature molecular dynamics trajectories and hence identify a representative structure of each cluster of distinct lattice energy minima that are effectively equivalent at finite temperature and pressure. Biased simulations are used to reduce the impact of limited sampling time and to estimate the work associated with polymorphic transformations. We demonstrate the proposed systematic approach by studying the polymorphs of urea and succinic acid, reducing an initial set of over 100 energetically plausible CSP structures to 12 and 27 respectively, including the experimentally known polymorphs. The simulations also indicate the types of disorder and stacking errors that may occur in real structures.

Combined Use of Structure Analysis, Studies of Molecular Association in Solution, and Molecular Modelling to Understand the Different Propensities of Dihydroxybenzoic Acids to Form Solid Phases

Pharmaceutics ◽

10.3390/pharmaceutics13050734 ◽

2021 ◽

Vol 13 (5) ◽

pp. 734

Author(s):

Aija Trimdale ◽

Anatoly Mishnev ◽

Agris Bērziņš

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Structure Analysis ◽

Crystal Structure Analysis ◽

Molecular Association ◽

Hydroxyl Groups ◽

Solid Phases ◽

Solvent Molecules ◽

The arrangement of hydroxyl groups in the benzene ring has a significant effect on the propensity of dihydroxybenzoic acids (diOHBAs) to form different solid phases when crystallized from solution. All six diOHBAs were categorized into distinctive groups according to the solid phases obtained when crystallized from selected solvents. A combined study using crystal structure and molecule electrostatic potential surface analysis, as well as an exploration of molecular association in solution using spectroscopic methods and molecular dynamics simulations were used to determine the possible mechanism of how the location of the phenolic hydroxyl groups affect the diversity of solid phases formed by the diOHBAs. The crystal structure analysis showed that classical carboxylic acid homodimers and ring-like hydrogen bond motifs consisting of six diOHBA molecules are prominently present in almost all analyzed crystal structures. Both experimental spectroscopic investigations and molecular dynamics simulations indicated that the extent of intramolecular bonding between carboxyl and hydroxyl groups in solution has the most significant impact on the solid phases formed by the diOHBAs. Additionally, the extent of hydrogen bonding with solvent molecules and the mean lifetime of solute–solvent associates formed by diOHBAs and 2-propanol were also investigated.