2011
DOI: 10.1039/c0cp02981e
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Hybrid simulations: combining atomistic and coarse-grained force fields using virtual sites

Abstract: 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 molecule… Show more

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Cited by 191 publications
(204 citation statements)
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“…Recently Noid and coworkers have analyzed these aspects using concepts from liquid state theory [100,120]. One more note concerning Henderson's theorem: even though there is in principle one exact solution for the effective pair potential that reproduces a given pair correlation function, different potentials might give a reasonably close representation of the structure, i.e., the above inverse problem is mathematically ill-posed [116,121].This effect becomes even more pronounced in complex systems where several interaction functions corresponding to several RDFs need to be numerically determined. This can to some extent be turned into an advantage since it allows one to impose thermodynamic constraints in the parametrization procedure.…”
Section: Boltzmann-inversion Based Methodsmentioning
confidence: 99%
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“…Recently Noid and coworkers have analyzed these aspects using concepts from liquid state theory [100,120]. One more note concerning Henderson's theorem: even though there is in principle one exact solution for the effective pair potential that reproduces a given pair correlation function, different potentials might give a reasonably close representation of the structure, i.e., the above inverse problem is mathematically ill-posed [116,121].This effect becomes even more pronounced in complex systems where several interaction functions corresponding to several RDFs need to be numerically determined. This can to some extent be turned into an advantage since it allows one to impose thermodynamic constraints in the parametrization procedure.…”
Section: Boltzmann-inversion Based Methodsmentioning
confidence: 99%
“…In addition, it is of particular methodological interest because for single bead models of water it is known that three-body correlations play a decisive role and the potential compromise between reproducing pair-or higher order structural correlations is particularly relevant for the properties of the model [101,116,117]. Different studies have been carried out that compare structure-motivated and thermodynamics-based CG models [121,136,137]. While CG models where the parametrization targets had been solvation and partitioning properties are particularly well suited to reproduce processes where for example hydrophilicity/hydrophobicity arguments play a decisive role, they do not per se reproduce the structure of the system [121,136].…”
Section: Transferability Of Coarse-grained Modelsmentioning
confidence: 99%
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“…Hybrid models are, in principle, a very powerful simulation strategy because they combine the best of both worlds -sampling globally at a low resolution (for instance, the bulk membrane and solvent) with only a local high resolution in defined areas of interest (for instance, at the protein-lipid interface). Either a static division of the all-atom and coarse-grained degrees of freedom can be used (Han and Schulten, 2012;Rzepiela et al, 2011;Wassenaar et al, 2013), akin to the wellestablished hybrid quantum mechanics/molecular mechanics (QM/ MM) method, or an adaptive boundary that allows particles to change resolution during the simulation (Praprotnik et al, 2008;Zavadlav et al, 2014). A number of pioneering hybrid studies of the static kind have appeared, in which all-atom/based membrane proteins are embedded in a coarse-grained model membrane environment (Han and Schulten, 2012;Wassenaar et al, 2013).…”
Section: Multi-resolution Methodsmentioning
confidence: 99%
“…However, it typically comprises most of the particles in the simulated system and thus the majority of the computational effort is spent on obtaining water-water interactions in distal regions that are not relevant for the problem under consideration. This realization led to the development of several multiscale simulation methods, which reduce the number of degrees of freedom for distal water and at the same time keep the atomistic (AT) resolution where it is necessary [5][6][7][8][9]. The speedup of such multiscale simulations with respect to all-atom simulations is proportional to the reduction of the interaction sites in the coarse-grained (CG) model of water.…”
mentioning
confidence: 99%