Differential geometry-based solvation and electrolyte transport models for biomolecular modeling: A review

G. Wei, Nathan A. Baker
{"title":"Differential geometry-based solvation and electrolyte transport models for biomolecular modeling: A review","authors":"G. Wei, Nathan A. Baker","doi":"10.1201/b21343-15","DOIUrl":null,"url":null,"abstract":"This chapter reviews the differential geometry-based solvation and electrolyte transport for biomolecular solvation that have been developed over the past decade. A key component of these methods is the differential geometry of surfaces theory, as applied to the solvent-solute boundary. In these approaches, the solvent-solute boundary is determined by a variational principle that determines the major physical observables of interest, for example, biomolecular surface area, enclosed volume, electrostatic potential, ion density, electron density, etc. Recently, differential geometry theory has been used to define the surfaces that separate the microscopic (solute) domains for biomolecules from the macroscopic (solvent) domains. In these approaches, the microscopic domains are modeled with atomistic or quantum mechanical descriptions, while continuum mechanics models (including fluid mechanics, elastic mechanics, and continuum electrostatics) are applied to the macroscopic domains. This multiphysics description is integrated through an energy functional formalism and the resulting Euler-Lagrange equation is employed to derive a variety of governing partial differential equations for different solvation and transport processes; e.g., the Laplace-Beltrami equation for the solvent-solute interface, Poisson or Poisson-Boltzmann equations for electrostatic potentials, the Nernst-Planck equation for ion densities, and the Kohn-Sham equation for solute electron density. Extensive validation of these models has been carried out over hundreds of molecules, including proteins and ion channels, and the experimental data have been compared in terms of solvation energies, voltage-current curves, and density distributions. We also propose a new quantum model for electrolyte transport.","PeriodicalId":8447,"journal":{"name":"arXiv: Biomolecules","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2014-11-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"4","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv: Biomolecules","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1201/b21343-15","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 4

Abstract

This chapter reviews the differential geometry-based solvation and electrolyte transport for biomolecular solvation that have been developed over the past decade. A key component of these methods is the differential geometry of surfaces theory, as applied to the solvent-solute boundary. In these approaches, the solvent-solute boundary is determined by a variational principle that determines the major physical observables of interest, for example, biomolecular surface area, enclosed volume, electrostatic potential, ion density, electron density, etc. Recently, differential geometry theory has been used to define the surfaces that separate the microscopic (solute) domains for biomolecules from the macroscopic (solvent) domains. In these approaches, the microscopic domains are modeled with atomistic or quantum mechanical descriptions, while continuum mechanics models (including fluid mechanics, elastic mechanics, and continuum electrostatics) are applied to the macroscopic domains. This multiphysics description is integrated through an energy functional formalism and the resulting Euler-Lagrange equation is employed to derive a variety of governing partial differential equations for different solvation and transport processes; e.g., the Laplace-Beltrami equation for the solvent-solute interface, Poisson or Poisson-Boltzmann equations for electrostatic potentials, the Nernst-Planck equation for ion densities, and the Kohn-Sham equation for solute electron density. Extensive validation of these models has been carried out over hundreds of molecules, including proteins and ion channels, and the experimental data have been compared in terms of solvation energies, voltage-current curves, and density distributions. We also propose a new quantum model for electrolyte transport.
生物分子建模中基于微分几何的溶剂化和电解质传输模型:综述
本章回顾了过去十年来基于微分几何的溶剂化和电解质运输的生物分子溶剂化。这些方法的一个关键组成部分是应用于溶剂-溶质边界的曲面微分几何理论。在这些方法中,溶剂-溶质边界由变分原理决定,该原理决定了感兴趣的主要物理观察值,例如,生物分子表面积、封闭体积、静电势、离子密度、电子密度等。最近,微分几何理论已被用于定义生物分子的微观(溶质)域与宏观(溶剂)域之间的表面。在这些方法中,微观领域用原子力学或量子力学描述建模,而连续介质力学模型(包括流体力学、弹性力学和连续介质静电学)应用于宏观领域。这种多物理场描述通过能量泛函形式系统集成,得到的欧拉-拉格朗日方程用于推导不同溶剂化和输运过程的各种控制偏微分方程;例如,溶剂-溶质界面的拉普拉斯-贝尔特拉米方程,静电势的泊松或泊松-玻尔兹曼方程,离子密度的能斯特-普朗克方程,以及溶质电子密度的科恩-沙姆方程。这些模型已经在数百个分子上进行了广泛的验证,包括蛋白质和离子通道,并且实验数据已经在溶剂化能,电压-电流曲线和密度分布方面进行了比较。我们还提出了一种新的电解质输运量子模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
求助全文
约1分钟内获得全文 求助全文
来源期刊
自引率
0.00%
发文量
0
×
引用
GB/T 7714-2015
复制
MLA
复制
APA
复制
导出至
BibTeX EndNote RefMan NoteFirst NoteExpress
×
提示
您的信息不完整,为了账户安全,请先补充。
现在去补充
×
提示
您因"违规操作"
具体请查看互助需知
我知道了
×
提示
确定
请完成安全验证×
copy
已复制链接
快去分享给好友吧!
我知道了
右上角分享
点击右上角分享
0
联系我们:info@booksci.cn Book学术提供免费学术资源搜索服务,方便国内外学者检索中英文文献。致力于提供最便捷和优质的服务体验。 Copyright © 2023 布克学术 All rights reserved.
京ICP备2023020795号-1
ghs 京公网安备 11010802042870号
Book学术文献互助
Book学术文献互助群
群 号:481959085
Book学术官方微信