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Abstract
Steered molecular dynamics (SMD) simulation has been applied to molecular dissociation events by adding harmonic forces to molecules, and within most SMDs, molecules are pulled at a constant velocity. Instead of the constant-velocity pulling, a constant force can also be utilized in SMD, which we call constant-force SMD (CF-SMD) simulation. CF-SMD employs a constant force that reduces activation barriers, enhancing a dissociation event. Here, we present the capability of CF- SMD simulation to estimate a dissociation rate in equilibrium. We performed all-atom CF-SMD simulations for an NaCl system and protein-ligand systems, producing dissociation rates under various forces. We extrapolated them to the dissociation rate in the absence of a constant force, using Dudko-Hummer-Szabo model. We demonstrated that CF-SMD simulations combined with the model predicted a dissociation rate in equilibrium. CF-SMD simulation would be a powerful tool to estimate dissociation rate in a direct and computationally efficient manner.
Supplementary materials
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Supporting information
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Figure S1-6; Table S1-5
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