We present two new implementations of the virtual sites technique which completely suppresses the degrees of freedom of the hydrogen atoms in a lipid bilayer allowing for an increased time step of 5 fs in all-atom simulations of the CHARMM36 force field. One of our approaches uses the derivation of the virtual sites used in GROMACS while the other uses a new definition of the virtual sites of the CH2 groups. Our methods is tested on a DPPC (no unsaturated chain), a POPC (one unsaturated chain), and a DOPC (two unsaturated chains) lipid bilayers. We calculate various physical properties of the membrane of our simulations with and without virtual sites and explain the differences and similarity observed. The best agreements are obtained for t...
AbstractA recently defined charge set, to be used in conjunction with the all-atom CHARMM27r force f...
Biological membranes are versatile in composition and host intriguing molecular processes. In order ...
The sensitivity of the structure and dynamics of a fully hydrated pure bilayer of 1,2-dipalmitoyl-sn...
<p>The performance of all-atom molecular dynamics simulations is limited by an integration time step...
The performance of all-atom molecular dynamics simulations is limited by an integration time step of...
All-atomistic (AA) and coarse-grain (CG) simulations have been successfully applied to investigate a...
AbstractA novel protocol has been developed for comparing the structural properties of lipid bilayer...
In this data article we provide topologies and force field parameters files for molecular dynamics s...
Asymmetric membranes consisting of DOPC, cholesterol, and a lipid with a varying level of unsaturati...
AbstractWe have recently shown that current molecular dynamics (MD) atomic force fields are not yet ...
Molecular dynamics (MD) simulations have become a standard method to explore the detailed atomic pro...
Membranes consisting of 260 phospholipids varying levels of chain unsaturation together with 28 (10 ...
United-atom force fields for molecular dynamics (MD) simulations provide a higher computational effi...
The all-atomic force field Slipids (Stockholm Lipids) for lipid bilayers simulations has been extend...
An all-atomistic force field (FF) has been developed for fully saturated phospholipids. The parametr...
AbstractA recently defined charge set, to be used in conjunction with the all-atom CHARMM27r force f...
Biological membranes are versatile in composition and host intriguing molecular processes. In order ...
The sensitivity of the structure and dynamics of a fully hydrated pure bilayer of 1,2-dipalmitoyl-sn...
<p>The performance of all-atom molecular dynamics simulations is limited by an integration time step...
The performance of all-atom molecular dynamics simulations is limited by an integration time step of...
All-atomistic (AA) and coarse-grain (CG) simulations have been successfully applied to investigate a...
AbstractA novel protocol has been developed for comparing the structural properties of lipid bilayer...
In this data article we provide topologies and force field parameters files for molecular dynamics s...
Asymmetric membranes consisting of DOPC, cholesterol, and a lipid with a varying level of unsaturati...
AbstractWe have recently shown that current molecular dynamics (MD) atomic force fields are not yet ...
Molecular dynamics (MD) simulations have become a standard method to explore the detailed atomic pro...
Membranes consisting of 260 phospholipids varying levels of chain unsaturation together with 28 (10 ...
United-atom force fields for molecular dynamics (MD) simulations provide a higher computational effi...
The all-atomic force field Slipids (Stockholm Lipids) for lipid bilayers simulations has been extend...
An all-atomistic force field (FF) has been developed for fully saturated phospholipids. The parametr...
AbstractA recently defined charge set, to be used in conjunction with the all-atom CHARMM27r force f...
Biological membranes are versatile in composition and host intriguing molecular processes. In order ...
The sensitivity of the structure and dynamics of a fully hydrated pure bilayer of 1,2-dipalmitoyl-sn...