Classical molecular dynamics (MD) simulations based on atomistic models are increasingly used to study a wide range of biological systems. A prerequisite for meaningful results from such simulations is an accurate molecular mechanical force field. Most biomolecular simulations are currently based on the widely used AMBER and CHARMM force fields, which were parametrized and optimized to cover a small set of basic compounds corresponding to the natural amino acids and nucleic acid bases. Atomic models of additional compounds are commonly generated by analogy to the parameter set of a given force field. While this procedure yields models that are internally consistent, the accuracy of the resulting models can be limited. In this work, we propo...
Protein modeling with molecular mechanics force fields plays an important role in computational biol...
<div>Computer simulations of bio-molecular systems often use force fields, which are combinations of...
The most important requirement of biomolecular modeling is to deal with electrostatic energies. The ...
Meaningful efforts in computer-aided drug design (CADD) require accurate molecular mechanical force ...
Molecular mechanics force fields, which are commonly used in biomolecular modeling and computer-aide...
We introduce a novel procedure to parametrize biomolecular force fields. We perform finite-temperatu...
Simulations of molecular systems using electronic structure methods are still not feasible for many ...
Computer simulations of biomolecular systems often use force fields, which are combinations of simpl...
Modeling structural and thermodynamic properties of nucleic acids has long been a challenge in the d...
We present the AMBER ff15ipq force field for proteins, the second-generation force field developed u...
Abstract: We present the derivation of a new molecular mechanical force field for simulating the str...
Driven by the constant increase in computational resources and power, modeling of biomolecular syste...
In this work, we report two polarizable molecular mechanics (polMM) force field models for estimatin...
A set of atomic polarizability parameters for a new polarizable Gaussian model (pGM) has been develo...
Protein modeling with molecular mechanics force fields plays an important role in computational biol...
<div>Computer simulations of bio-molecular systems often use force fields, which are combinations of...
The most important requirement of biomolecular modeling is to deal with electrostatic energies. The ...
Meaningful efforts in computer-aided drug design (CADD) require accurate molecular mechanical force ...
Molecular mechanics force fields, which are commonly used in biomolecular modeling and computer-aide...
We introduce a novel procedure to parametrize biomolecular force fields. We perform finite-temperatu...
Simulations of molecular systems using electronic structure methods are still not feasible for many ...
Computer simulations of biomolecular systems often use force fields, which are combinations of simpl...
Modeling structural and thermodynamic properties of nucleic acids has long been a challenge in the d...
We present the AMBER ff15ipq force field for proteins, the second-generation force field developed u...
Abstract: We present the derivation of a new molecular mechanical force field for simulating the str...
Driven by the constant increase in computational resources and power, modeling of biomolecular syste...
In this work, we report two polarizable molecular mechanics (polMM) force field models for estimatin...
A set of atomic polarizability parameters for a new polarizable Gaussian model (pGM) has been develo...
Protein modeling with molecular mechanics force fields plays an important role in computational biol...
<div>Computer simulations of bio-molecular systems often use force fields, which are combinations of...
The most important requirement of biomolecular modeling is to deal with electrostatic energies. The ...