Optimal designs for pairwise calculation: An application to free energy perturbation in minimizing prediction variability

Yang, Qingyi; Burchett, Woodrow; Steeno, Gregory S.; Liu, Shuai; Yang, Mingjun; Mobley, David L.; Hou, Xinjun

doi:10.1002/jcc.26095

Cited by 35 publications

(78 citation statements)

References 36 publications

(41 reference statements)

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“…In this way the top-ranking examples can be readily identified and submitted to additional calculations in a second round. Alternatively, if the goal is to achieve the smallest possible error with minimal computational expense, certain graph topologies provide benefits [94,95]…”

Section: Input Setup and Scale Of Calculationsmentioning

confidence: 99%

“…Based on the input ligand series, a perturbation map or network can be planned. Recent heuristics have shown the more connected the perturbation network the better, however, there is a way to optimize network structure while minimizing the number of perturbations that need to be computed reducing the resulting computational cost [94,95]. Sometimes the introduction of intermediates that are not part of the original congeneric series are essential to avoid ring breaking, or deal with perturbations that would otherwise result in large numbers of atoms being inserted or deleted.…”

Section: Perturbation Mapsmentioning

confidence: 99%

“…5 B. Methods in experimental design have been applied to the construction of the perturbation maps. Yang et al [94] optimized the perturbation map by selecting a fixed number of calculations from the pairwise perturbations so that the resulting set of calculations minimize the total variance. Xu [95] optimized the perturbation map by allocating different amounts of simulation time to different pairwise perturbations so as to minimize the total variance, given the total simulation time of all the perturbation calculations.…”

Section: Perturbation Mapsmentioning

confidence: 99%

“…An alternative approach computes the free energy change between a target and reference compound as a weighted average over all unique paths in the network, with the weights derived from the propagated uncertainties of each node [16]. Approaches as illustrated by Yang et al for perturbation map design can also be used to compute relative free energies between target and reference compounds [94].…”

Section: Cycle Closure Errormentioning

confidence: 99%

See 3 more Smart Citations

Best Practices for Alchemical Free Energy Calculations [Article v1.0]

Mey¹,

et al. 2020

Self Cite

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Section: Input Setup and Scale Of Calculationsmentioning

confidence: 99%

Section: Perturbation Mapsmentioning

confidence: 99%

Section: Perturbation Mapsmentioning

confidence: 99%

Section: Cycle Closure Errormentioning

confidence: 99%

See 2 more Smart Citations

Best Practices for Alchemical Free Energy Calculations [Article v1.0]

Mey¹,

et al. 2020

Self Cite

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“…The ability to efficiently calculate the associated binding free energy [22][23][24] can provide valuable contributions to the ligand optimization phase, allowing to rank ligands, optimize selectivity, and estimate off-target interactions. With recent advances in the free energy methods and underlying simulation models, the calculation of free energies from atomistic MD simulations has become a reliable tool with several examples of successful industrial applications [25][26][27][28][29]. Multi-scale approaches in which atomistic force fields are combined with coarse-grained models that were built for specific applications can further reduce the computational cost and allow to study even larger systems such as membrane-bound ion channels [30].…”

Section: Mm-based Simulationsmentioning

confidence: 99%

Machine learning-accelerated quantum mechanics-based atomistic simulations for industrial applications

Morawietz

Artrith

2020

J Comput Aided Mol Des

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Atomistic simulations have become an invaluable tool for industrial applications ranging from the optimization of protein-ligand interactions for drug discovery to the design of new materials for energy applications. Here we review recent advances in the use of machine learning (ML) methods for accelerated simulations based on a quantum mechanical (QM) description of the system. We show how recent progress in ML methods has dramatically extended the applicability range of conventional QM-based simulations, allowing to calculate industrially relevant properties with enhanced accuracy, at reduced computational cost, and for length and time scales that would have otherwise not been accessible. We illustrate the benefits of ML-accelerated atomistic simulations for industrial R&D processes by showcasing relevant applications from two very different areas, drug discovery (pharmaceuticals) and energy materials. Writing from the perspective of both a molecular and a materials modeling scientist, this review aims to provide a unified picture of the impact of ML-accelerated atomistic simulations on the pharmaceutical, chemical, and materials industries and gives an outlook on the exciting opportunities that could emerge in the future.

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Relative free-energy calculations for scaffold hopping-type transformations with an automated RE-EDS sampling procedure

Ries

Normak

Weiß

et al. 2022

J Comput Aided Mol Des

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The calculation of relative free-energy differences between different compounds plays an important role in drug design to identify potent binders for a given protein target. Most rigorous methods based on molecular dynamics simulations estimate the free-energy difference between pairs of ligands. Thus, the comparison of multiple ligands requires the construction of a “state graph”, in which the compounds are connected by alchemical transformations. The computational cost can be optimized by reducing the state graph to a minimal set of transformations. However, this may require individual adaptation of the sampling strategy if a transformation process does not converge in a given simulation time. In contrast, path-free methods like replica-exchange enveloping distribution sampling (RE-EDS) allow the sampling of multiple states within a single simulation without the pre-definition of alchemical transition paths. To optimize sampling and convergence, a set of RE-EDS parameters needs to be estimated in a pre-processing step. Here, we present an automated procedure for this step that determines all required parameters, improving the robustness and ease of use of the methodology. To illustrate the performance, the relative binding free energies are calculated for a series of checkpoint kinase 1 inhibitors containing challenging transformations in ring size, opening/closing, and extension, which reflect changes observed in scaffold hopping. The simulation of such transformations with RE-EDS can be conducted with conventional force fields and, in particular, without soft bond-stretching terms.

show abstract

Optimal designs for pairwise calculation: An application to free energy perturbation in minimizing prediction variability

Cited by 35 publications

References 36 publications

Best Practices for Alchemical Free Energy Calculations [Article v1.0]

Best Practices for Alchemical Free Energy Calculations [Article v1.0]

Machine learning-accelerated quantum mechanics-based atomistic simulations for industrial applications

Relative free-energy calculations for scaffold hopping-type transformations with an automated RE-EDS sampling procedure

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