Multi-level grid algorithms for faster molecular energetics

Symposium on Solid and Physical Modeling Pub Date : 2010-09-01 DOI:10.1145/1839778.1839799

R. Chowdhury, C. Bajaj

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引用次数: 4

Abstract

Bio-molecules reach their stable configuration in solvent which is primarily water with a small concentration of salt ions. One approximation of the total free energy of a bio-molecule includes the classical molecular mechanical energy E_MM (which is understood as the self intra-molecular energy in vacuum) and the solvation energy G_sol which is caused by the change of the environment of the molecule from vacuum to solvent (and hence also known as the molecule-solvent interaction energy). This total free energy is used to model and study the stability of bio-molecules in isolation or in their interactions with drugs. In this paper we present fast O (N log N) multi-level grid based approximation algorithms (where N is the number of atoms) for efficiently estimating the compute-intensive terms of E_MM and G_sol. The fast octree-based algorithm for G_sol is additionally dependent on an O (N) size computation of the biomolecular surface and its spatial derivatives (normals). We also provide several examples with timing results, and speed/accuracy tradeoffs, demonstrating the efficiency and scalability of our fast free energy estimation of bio-molecules, potentially with millions of atoms.

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更快分子能量学的多级网格算法

生物分子在溶剂中达到稳定构型，溶剂主要是水和少量盐离子。生物分子总自由能的一种近似包括经典的分子机械能EMM(被理解为真空中的自身分子内能量)和溶剂化能Gsol，这是由分子从真空到溶剂的环境变化引起的(因此也称为分子-溶剂相互作用能)。该总自由能用于模拟和研究生物分子在分离或与药物相互作用中的稳定性。在本文中，我们提出了快速的O (N log N)基于多级网格的近似算法(其中N是原子数)，用于有效地估计EMM和Gsol的计算密集型项。基于八叉树的快速Gsol算法还依赖于生物分子表面及其空间衍生物(法线)的O (N)大小的计算。我们还提供了几个计时结果和速度/精度权衡的例子，展示了我们对生物分子的快速自由能估计的效率和可扩展性，可能有数百万个原子。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Symposium on Solid and Physical Modeling

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