Fully quantum mechanical approaches to calculating protein–ligand free energies of binding have the potential to reduce empiricism and explicitly account for all physical interactions responsible for protein–ligand binding. In this study, we show a realistic test of the linear-scaling DFT-based QM-PBSA method to estimate quantum mechanical protein–ligand binding free energies for a set of ligands binding to the pharmaceutical drug-target bromodomain containing protein 4 (BRD4). We show that quantum mechanical QM-PBSA is a significant improvement over traditional MM-PBSA in terms of accuracy against experiment and ligand rank ordering and that the quantum and classical binding energies are converged to a similar degree. We test the interacti...
Molecular dynamics-based approaches to calculate absolute protein-ligand binding free energy often r...
Most drugs act on biomacromolecules. The Cost of developing new drugs is very high. A method to accu...
Importance of the field. The development of quantum mechanics (QM) was perhaps the greatest intellec...
Electronic Supporting Information for Publication "BRD4: Quantum mechanical protein-ligand bind...
The accurate prediction of protein–ligand binding free energies with tractable computational methods...
The calculation of binding affinities for flexible ligands has hitherto required the availability of...
A modification of the MM-PBSA technique for calculating binding affinities of biomolecular complexes...
In this paper, we review our efforts to use quantum mechanical (QM) methods to improve free-energy e...
In drug optimization calculations, the molecular mechanics Poisson-Boltzmann surface area (MM-PBSA) ...
We review the first successes and failures of a “new wave” of quantum chemistry-based approaches to ...
We present a molecular simulation protocol to compute free energies of binding, which combines a QM/...
Computing accurate protein-ligand interaction energies is essential for virtual drug design. For thi...
Experimental drug discovery is very time-consuming, risky and comes at a huge cost, typically severa...
Today computational chemistry is a consolidated tool in drug lead discovery endeavors. Due to method...
One of the largest challenges of computational chemistry is calculation of accurate free energies fo...
Molecular dynamics-based approaches to calculate absolute protein-ligand binding free energy often r...
Most drugs act on biomacromolecules. The Cost of developing new drugs is very high. A method to accu...
Importance of the field. The development of quantum mechanics (QM) was perhaps the greatest intellec...
Electronic Supporting Information for Publication "BRD4: Quantum mechanical protein-ligand bind...
The accurate prediction of protein–ligand binding free energies with tractable computational methods...
The calculation of binding affinities for flexible ligands has hitherto required the availability of...
A modification of the MM-PBSA technique for calculating binding affinities of biomolecular complexes...
In this paper, we review our efforts to use quantum mechanical (QM) methods to improve free-energy e...
In drug optimization calculations, the molecular mechanics Poisson-Boltzmann surface area (MM-PBSA) ...
We review the first successes and failures of a “new wave” of quantum chemistry-based approaches to ...
We present a molecular simulation protocol to compute free energies of binding, which combines a QM/...
Computing accurate protein-ligand interaction energies is essential for virtual drug design. For thi...
Experimental drug discovery is very time-consuming, risky and comes at a huge cost, typically severa...
Today computational chemistry is a consolidated tool in drug lead discovery endeavors. Due to method...
One of the largest challenges of computational chemistry is calculation of accurate free energies fo...
Molecular dynamics-based approaches to calculate absolute protein-ligand binding free energy often r...
Most drugs act on biomacromolecules. The Cost of developing new drugs is very high. A method to accu...
Importance of the field. The development of quantum mechanics (QM) was perhaps the greatest intellec...