Add to ORKGFew methods use molecular dynamics simulations based on atomically detailed force fields to study the proteinligand docking process because they are considered too time demanding despite their accuracy. In this paper we present a docking algorithm based on molecular dynamics simulations which has a highly flexible computational granularity. We compare the accuracy and the time required with well-known, commonly used docking methods like AutoDock, DOCK, FlexX, ICM, and GOLD. We show that our algorithm is accurate, fast and, because of its flexibility, applicable even to loosely coupled distributed systems like desktop grids for docking
It is well known that computer-aided docking of large ligands, with many rotatable bonds, is extreme...
AbstractBackground: Molecular docking seeks to predict the geometry and affinity of the binding of a...
We previously developed Upside, a near-atomic, fast molecular dynamics algorithm for protein folding...
Few methods use molecular dynamics simulations based on atomically detailed force fields to study th...
The generation of molecular conformations and the evaluation of interaction potentials are common ta...
The binding of small molecule ligands to large protein targets is central to numerous biological pro...
We present the novel docking algorithm based on the Tensor Train decomposition and the TT-Cross glob...
In this dissertation a novel approach to protein-ligand docking is presented. First an existing meth...
In this dissertation a novel approach to protein-ligand docking is presented. First an existing meth...
In this dissertation a novel approach to protein-ligand docking is presented. First an existing meth...
With the rapid development of structural determination of target proteins for human diseases, high t...
A rational approach is needed to maximize the chances of finding new drugs, and to exploit the oppor...
Molecular docking is central to rational drug design. Current docking techniques suffer, however, fr...
Molecular docking is central to rational drug design. Current docking techniques suffer, however, fr...
It is well known that computer-aided docking of large ligands, with many rotatable bonds, is extreme...
It is well known that computer-aided docking of large ligands, with many rotatable bonds, is extreme...
AbstractBackground: Molecular docking seeks to predict the geometry and affinity of the binding of a...
We previously developed Upside, a near-atomic, fast molecular dynamics algorithm for protein folding...
Few methods use molecular dynamics simulations based on atomically detailed force fields to study th...
The generation of molecular conformations and the evaluation of interaction potentials are common ta...
The binding of small molecule ligands to large protein targets is central to numerous biological pro...
We present the novel docking algorithm based on the Tensor Train decomposition and the TT-Cross glob...
In this dissertation a novel approach to protein-ligand docking is presented. First an existing meth...
In this dissertation a novel approach to protein-ligand docking is presented. First an existing meth...
In this dissertation a novel approach to protein-ligand docking is presented. First an existing meth...
With the rapid development of structural determination of target proteins for human diseases, high t...
A rational approach is needed to maximize the chances of finding new drugs, and to exploit the oppor...
Molecular docking is central to rational drug design. Current docking techniques suffer, however, fr...
Molecular docking is central to rational drug design. Current docking techniques suffer, however, fr...
It is well known that computer-aided docking of large ligands, with many rotatable bonds, is extreme...
It is well known that computer-aided docking of large ligands, with many rotatable bonds, is extreme...
AbstractBackground: Molecular docking seeks to predict the geometry and affinity of the binding of a...
We previously developed Upside, a near-atomic, fast molecular dynamics algorithm for protein folding...