丙氨酸氨基酸在碳纳米管内封装的建模

Hakim AL Garalleh, Mazen Garalehab
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引用次数: 0

摘要

碳纳米管在促进和控制药物和生物分子通过其内外表面的运输方面发挥着重要作用。碳纳米管也是一种选择性纳米器件,因为它具有优异的性能,在许多生物医学和药物输送应用中具有巨大的潜在用途。该模型旨在研究丙氨酸分子在单壁碳纳米管内的封装,并确定丙氨酸与半径r不同的单壁碳纳米管相互作用时产生的最小能量。我们考虑了两种可能的丙氨酸模型,即球形壳和离散构型,由三个组成部分组成:线性分子、圆柱形基团和CH3分子作为一个球体,与无限圆柱形单壁碳纳米管相互作用。根据纳米管半径r和氨基酸与圆柱形纳米管中心轴形成的取向角φ,计算了氨基酸对丙氨酸的吸附量和各取向的总能量大小。结果表明,丙氨酸分子被包裹在半径大于3.75 A的纳米管内,这与最近的研究结果非常吻合。
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Modeling of Encapsulation of Alanine Amino Acid inside a CarbonNanotube
Carbon nanotubes play a significant role in facilitating and controlling the transportation of drugs and biomolecules through their internal and external surfaces. Carbon nanotubes are also selective nano-devices because of their outstanding properties and huge potential use in many bio-medical and drug delivery applications. The proposed model aims to investigate the encapsulation of Alanine molecule inside a single-walled carbon nanotube, and to determine the minimum energy arising from the Alanine interacting with single-walled carbon nanotubes with variant radius r. We consider two possible structures as models of Alanine amino acid which are a spherical shell and discrete configuration modelled as comprising three components: the linear molecule, cylindrical group and CH3 molecule as a sphere, all interacting with infinite cylindrical single-walled carbon nanotube. The adsorption of Alanine amino acid and magnitude of total energy for each orientation calculated based on the nanotube radius r and the orientation angle φ which the amino acid makes with central axis of the cylindrical nanotube. Our results indicate that the Alanine molecule encapsulated inside the nanotubes of radius greater than 3.75 A, which is in excellent agreement with recent findings.
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