Metadynamics is a powerful computational tool to obtain the free-energy landscape of complex systems. The Monte Carlo algorithm has proven useful to calculate thermodynamic quantities associated with simplified models of proteins, and thus to gain an ever-increasing understanding on the general principles underlying the mechanism of protein folding. We show that it is possible to couple metadynamics and Monte Carlo algorithms to obtain the free energy of model proteins in a way which is computationally very economical
The generation of a complete ensemble of geometrical configurations is required to obtain reliable e...
A protocol for calculating free energy landscapes (FELs) is proposed based on a combination of two c...
Metadynamics is an atomistic simulation technique that allows, within the same framework, accelerati...
Recently, we have introduced a new method, metadynamics, which is able to sample rarely occurring tr...
Over the past three decades, a number of powerful simulation algorithms have been introduced to the ...
AbstractNested sampling is a Bayesian sampling technique developed to explore probability distributi...
Computer simulation of conformational transitions in biomolecules, such as protein folding, is cons...
By suitably extending a recent approach [Bussi, G.; et al. J. Am. Chem. Soc. 2006, 128, 13435] we in...
Nested sampling is a Bayesian sampling technique developed to explore probability distributions loca...
This chapter focuses on metadynamics, which was first introduced in 2002 and then improved with seve...
The use of free-energy landscapes rationalizes a wide range of aspects of protein behavior by provid...
AbstractDifferent components of the theoretical protein folding problem are evaluated critically. It...
Monte Carlo simulation (MCS) is a common methodology to compute pathways and thermodynamic propertie...
The Metropolis implementation of the Monte Carlo algorithm has been developed to study the equilibri...
Proteins are known to fold into tertiary structures that determine their functionality in living org...
The generation of a complete ensemble of geometrical configurations is required to obtain reliable e...
A protocol for calculating free energy landscapes (FELs) is proposed based on a combination of two c...
Metadynamics is an atomistic simulation technique that allows, within the same framework, accelerati...
Recently, we have introduced a new method, metadynamics, which is able to sample rarely occurring tr...
Over the past three decades, a number of powerful simulation algorithms have been introduced to the ...
AbstractNested sampling is a Bayesian sampling technique developed to explore probability distributi...
Computer simulation of conformational transitions in biomolecules, such as protein folding, is cons...
By suitably extending a recent approach [Bussi, G.; et al. J. Am. Chem. Soc. 2006, 128, 13435] we in...
Nested sampling is a Bayesian sampling technique developed to explore probability distributions loca...
This chapter focuses on metadynamics, which was first introduced in 2002 and then improved with seve...
The use of free-energy landscapes rationalizes a wide range of aspects of protein behavior by provid...
AbstractDifferent components of the theoretical protein folding problem are evaluated critically. It...
Monte Carlo simulation (MCS) is a common methodology to compute pathways and thermodynamic propertie...
The Metropolis implementation of the Monte Carlo algorithm has been developed to study the equilibri...
Proteins are known to fold into tertiary structures that determine their functionality in living org...
The generation of a complete ensemble of geometrical configurations is required to obtain reliable e...
A protocol for calculating free energy landscapes (FELs) is proposed based on a combination of two c...
Metadynamics is an atomistic simulation technique that allows, within the same framework, accelerati...