The multiscale coarse-graining method. I. A rigorous bridge between atomistic and coarse-grained models

Noid, W. G.; Chu, Jhih‐Wei; Ayton, Gary S.; Krishna, Vinod; Izvekov, Sergei; Voth, Gregory A.; Das, Avisek; Andersen, Hans Christian

doi:10.1063/1.2938860

Cited by 740 publications

(1,191 citation statements)

References 69 publications

(97 reference statements)

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“…The pressure correction was applied at every cycle and the convergence was measured as the root mean square deviation (RMSD) Force matching. Force matching 40,41 is another technique to construct CG potentials. It also uses information from reference atomistic simulations to construct the effective CG interaction.…”

Section: Coarse Grained Potentialsmentioning

confidence: 99%

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Hybrid simulations: combining atomistic and coarse-grained force fields using virtual sites

Rzepiela

Louhivuori

Peter

et al. 2011

Phys. Chem. Chem. Phys.

189

198

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Hybrid simulations, in which part of the system is represented at atomic resolution and the remaining part at a reduced, coarse-grained, level offer a powerful way to combine the accuracy associated with the atomistic force fields to the sampling speed obtained with coarse-grained (CG) potentials. In this work we introduce a straightforward scheme to perform hybrid simulations, making use of virtual sites to couple the two levels of resolution. With the help of these virtual sites interactions between molecules at different levels of resolution, i.e. between CG and atomistic molecules, are treated the same way as the pure CG-CG interactions. To test our method, we combine the Gromos atomistic force field with a number of coarse-grained potentials, obtained through several approaches that are designed to obtain CG potentials based on an existing atomistic model, namely iterative Boltzmann inversion, force matching, and a potential of mean force subtraction procedure (SB). We also explore the use of the MARTINI force field for the CG potential. A simple system, consisting of atomistic butane molecules dissolved in CG butane, is used to study the performance of our hybrid scheme. Based on the potentials of mean force for atomistic butane in CG solvent, and the properties of 1 : 1 mixtures of atomistic and CG butane which should exhibit ideal mixing behavior, we conclude that the MARTINI and SB potentials are particularly suited to be combined with the atomistic force field. The MARTINI potential is subsequently used to perform hybrid simulations of atomistic dialanine peptides in both CG butane and water. Compared to a fully atomistic description of the system, the hybrid description gives similar results provided that the dielectric screening of water is accounted for. Within the field of biomolecules, our method appears ideally suited to study e.g. protein-ligand binding, where the active site and ligand are modeled in atomistic detail and the rest of the protein, together with the solvent, is coarse-grained.

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Section: Coarse Grained Potentialsmentioning

confidence: 99%

“…Thus it aims at reproducing the multibody potential of mean force with a set of CG interaction functions, in the present case with effective pair interaction functions. 41 In order to evaluate FM CG potentials, first reference forces on CG beads are calculated as a sum of atomistic forces f g…”

Section: Coarse Grained Potentialsmentioning

confidence: 99%

Hybrid simulations: combining atomistic and coarse-grained force fields using virtual sites

Rzepiela

Louhivuori

Peter

et al. 2011

Phys. Chem. Chem. Phys.

189

198

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“…94 To compare the methods more closely, it is useful to define exactly what we would like to achieve with systematic coarse graining. The logical definition is the reproduction of the equilibrium probability distribution functions of the coarse-grained coordinates 95 (for this discussion, we neglect the momentum part of the Hamiltonian). Following the presentation by Noid et al, 95 let R N be the coarse-grained degrees of freedom and r n the detailed degrees of freedom, and define a mapping operator M N that maps the detailed model to the coarse-grained model: R N = M N (r n ).…”

Section: E Is There More To Pair Potentials?mentioning

confidence: 99%

Multiscale modeling of emergent materials: biological and soft matter

Murtola

Bunker

Vattulainen

et al. 2009

Phys. Chem. Chem. Phys.

258

234

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On using a too large integration time step in molecular dynamics simulations of coarse-grained molecular models Moritz Winger, Daniel Trzesniak, Riccardo Baron and Wilfred F. In this review, we focus on four current related issues in multiscale modeling of soft and biological matter. First, we discuss how to use structural information from detailed models (or experiments) to construct coarse-grained ones in a hierarchical and systematic way. This is discussed in the context of the so-called Henderson theorem and the inverse Monte Carlo method of Lyubartsev and Laaksonen. In the second part, we take a different look at coarse graining by analyzing conformations of molecules. This is done by the application of self-organizing maps, i.e., a neural network type approach. Such an approach can be used to guide the selection of the relevant degrees of freedom. Then, we discuss technical issues related to the popular dissipative particle dynamics (DPD) method. Importantly, the potentials derived using the inverse Monte Carlo method can be used together with the DPD thermostat. In the final part we focus on solvent-free modeling which offers a different route to coarse graining by integrating out the degrees of freedom associated with solvent.

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“…Boltzmann inversion and reverse Monte Carlo have been used to develop isotropic pairwise water−water interaction potentials directly from the radial distribution functions calculated from atomistic simulations. 9,10 Coarse-graining methods such as force matching (FM) 11,12 and relative entropy minimization (REM) 4 are gaining use and have been employed for the development of water models. 2, 3,13,14 The primary limitation of REM and FM methods is that although they are grounded in well-established statistical mechanical formalisms, they are not trivial to implement in practice and do not necessarily produce properties in good agreement with the target finer-grained model from which they are derived.…”

Section: Introductionmentioning

confidence: 99%

How Short Is Too Short for the Interactions of a Water Potential? Exploring the Parameter Space of a Coarse-Grained Water Model Using Uncertainty Quantification

2014

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Coarse-grained models are becoming increasingly popular due to their ability to access time and length scales that are prohibitively expensive with atomistic models. However, as a result of decreasing the degrees of freedom, coarse-grained models often have diminished accuracy, representability, and transferability compared with their finer grained counterparts. Uncertainty quantification (UQ) can help alleviate this challenge by providing an efficient and accurate method to evaluate the effect of model parameters on the properties of the system. This method is useful in finding parameter sets that fit the model to several experimental properties simultaneously. In this work we use UQ as a tool for the evaluation and optimization of a coarse-grained model. We efficiently sample the five-dimensional parameter space of the coarse-grained monatomic water (mW) model to determine what parameter sets best reproduce experimental thermodynamic, structural and dynamical properties of water. Generalized polynomial chaos (gPC) was used to reconstruct the analytical surfaces of density, enthalpy of vaporization, radial and angular distribution functions, and diffusivity of liquid water as a function of the input parameters. With these surfaces, we evaluated the sensitivity of these properties to perturbations of the model input parameters and the accuracy and representability of the coarse-grained models. In particular, we investigated what is the optimum length scale of the water−water interactions needed to reproduce the properties of liquid water with a monatomic model with two-and three-body interactions. We found that there is an optimum cutoff length of 4.3 Å, barely longer than the size of the first neighbor shell in water. As cutoffs deviate from this optimum value, the ability of the model to simultaneously reproduce the structure and thermodynamics is severely diminished.

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The multiscale coarse-graining method. I. A rigorous bridge between atomistic and coarse-grained models

Cited by 740 publications

References 69 publications

Hybrid simulations: combining atomistic and coarse-grained force fields using virtual sites

Hybrid simulations: combining atomistic and coarse-grained force fields using virtual sites

Multiscale modeling of emergent materials: biological and soft matter

How Short Is Too Short for the Interactions of a Water Potential? Exploring the Parameter Space of a Coarse-Grained Water Model Using Uncertainty Quantification

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