在水溶液中研究 DNA 碱基-Li 掺杂的碳化硅纳米管：计算机模拟研究。

Study of DNA base-Li doped SiC nanotubes in aqueous solutions: a computer simulation study.

机构信息

Department of Chemistry, East Tehran Branch, Islamic Azad University, Tehran, Iran.

出版信息

J Mol Model. 2013 Apr;19(4):1605-15. doi: 10.1007/s00894-012-1721-8. Epub 2013 Jan 3.

Abstract

Due to the importance of soluble nanotubes in biological systems, computational research on DNA base functionalized nanotubes is of interest. This study presents the quantitative results of Monte Carlo simulations of Li-doped silicon carbide nanotubes and its nucleic acid base complexes in water. Each species was first modeled by quantum mechanical calculations and then Monte Carlo simulations were applied to study their properties in aqueous solution. Solvation free energies were computed to indicate the solvation behavior of these compounds. The computations show that solvation free energies of the complexes of DNA bases with Li-doped SiC nanotubes are in the order: thymine > cytosine > adenine > guanine. The results of complexation free energies were also used to study the stability of related structures, which indicate that thymine-Li-doped SiC nanotubes produce the most stable compound among the four DNA base complexes.

摘要

由于可溶性纳米管在生物系统中的重要性，对 DNA 碱基功能化纳米管的计算研究很有意义。本研究提出了在水中掺杂锂的碳化硅纳米管及其核酸碱基配合物的蒙特卡罗模拟的定量结果。首先通过量子力学计算对每种物质进行建模，然后应用蒙特卡罗模拟来研究它们在水溶液中的性质。计算了溶剂化自由能以表明这些化合物的溶剂化行为。计算表明，与掺杂锂的 SiC 纳米管形成复合物的 DNA 碱基的溶剂化自由能顺序为：胸腺嘧啶>胞嘧啶>腺嘌呤>鸟嘌呤。配合物自由能的结果也用于研究相关结构的稳定性，表明胸腺嘧啶-掺杂锂的 SiC 纳米管在四种 DNA 碱基配合物中产生最稳定的化合物。

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在水溶液中研究 DNA 碱基-Li 掺杂的碳化硅纳米管：计算机模拟研究。

Study of DNA base-Li doped SiC nanotubes in aqueous solutions: a computer simulation study.

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