Molecular dynamics (MD) simulations face significant challenges in capturing rare events hindered by high energy barriers. While traditional enhanced sampling methods─whether biased or unbiased─typically rely on collective variables (CVs) for guidance, identifying optimal CVs for complex systems remains a formidable task. Here we propose a novel unbiased enhanced sampling methodology that circumvents the CV-related challenge through an iterative approach: projecting unbiased sampling data onto multiple low-dimensional CV spaces to calculate their sampling density distributions, integrating these distributions to guide subsequent sampling, and repeating the cycle. Conceptualizing MD-based conformational sampling as diffusion in high-dimensional space implies that our methodology accelerates diffusive exploration in all relevant CV spaces simultaneously. This method overcomes the exponential efficiency decay in high-dimensional CV spaces while offering several key advantages over existing methods: (1) it applies all CV guidance to the same unbiased ensemble, eliminating the need for replica exchange; (2) it accelerates diffusion in multiple CV spaces simultaneously, rather than being confined to one-dimensional "tube"-like pathway-based CVs, thus making it applicable to general multibasin systems. In addition, the method's ability to dynamically adjust CV spaces during sampling, along with its provision of well-classified, high-quality unbiased ensembles, greatly facilitates on-the-fly CV generation. In summary, this method provides a new paradigm for addressing CV-related challenges by leveraging the synergistic interplay between unbiased sampling and CV algorithms: On one hand, unbiased sampling enables simultaneous utilization of multiple CVs and enhances the effectiveness of CV generation methods while preserving the primary advantage─low CV dependence (yielding accurate results even with imperfect CVs). On the other hand, the optimized CV guidance effectively resolves the CV-related efficiency problems of unbiased sampling. As an additional benefit, the method provides weighted trajectory ensembles that retain complete system information. Validations through high-dimensional/multibasin model potentials and a coarse-grained protein system demonstrate the method's capability to accurately extract both thermodynamic properties (e.g., free energy landscapes) and kinetic properties (e.g., transition rates) with remarkable sampling efficiency.
Zhu et al. (Fri,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: