生物大分子相互作用分析(BIA)技术可以实时观察分子间相互作用。
The technique of biomolecular interaction analysis (BIA) can observe real time biomolecular interactions.
小分子化合物与生物大分子相互作用的研究已经成为了化学生物学中重要的研究课题。
The study of interaction of small molecular compound and biologic big molecular has been the important research in the biochemistry.
荧光共振能量转移(FRET)技术作为一种高效的光学“分子尺”,在生物大分子相互作用、免疫分析、核酸检测等方面有广泛的应用。
Fluorescence resonance energy transfer (FRET) has broad applications in the study of the interactions of biological macromolecules, immunoassay, nucleic acid detection and so on.
调整胶原蛋白和壳聚糖的用量比例,可以改变大分子间的相互作用,从而调整纸浆纤维的稳定性。
Adjusting use level of collagen and chitosan, the interaction of macromolecular could be changed, and stability of pulp could be adjusted.
不知为何这两个复杂大分子不得不在发生化学反应的活性位点以外的地方发生特定的相互作用。
Somehow these two large complicated molecules had to also interact specifically somewhere other than the site where the chemistry occurs.
通过研究大分子铬鞣助剂ECPA 与皮胶原、铬鞣剂间相互作用以及ECPA 助鞣的革坯铬结合牢度,探讨了ECPA 的高吸收铬鞣机理。
The high exhaustion chrome tanning mechanism of ECPA auxiliary was explored by means of investigating the interaction among the auxiliary, collagen and the chrome tanning agent.
血浆生物大分子可以加强血细胞之间约相互作用。
Plasma macromolecular substances might advance the interaction among blood cells.
生物大分子的功能主要取决于它们的三维结构、运动及相互作用。
The functions of biomacromolecules are mainly determined by their 3D structures, movements and interactions.
蛋白质的功能往往体现在与其他蛋白质或其它的生物大分子之间的相互作用中。
Usually, the functions of proteins behave themselves as the interactions with other proteins and biomacromolecules.
分子识别引导着所有生理过程中大分子间的选择性相互作用。
Molecular recognition leads the selective interaction between biomoleculars in all physiological process.
化学家在生物体系自集现象的启示下,用各种类型的相互作用去创造整齐排列的大分子,用于构筑纳米结构的材料。
Under the inspiration of self assembly in biology, chemists are now making use of weak interaction between different moleculars to get well arrayed supramolecular to construct nano-structure.
大分子量的PEG与蒙脱石层间表面有更强的相互作用。
Polyethylene glycol of higher molecular weight showed stronger interaction with the surface of montmorillonite plates.
DSC表明,剥离型纳米复合材料的热稳定性提高,这是由于蒙脱土纳米片层与基体大分子链相互作用的结果。
DSC indicates that thermal stability of the composites is enhanced. This is due to the intercalation of molecular chains of matrix with exfoliated layers of MMT.
DSC表明,剥离型纳米复合材料的热稳定性提高,这是由于蒙脱土纳米片层与基体大分子链相互作用的结果。
DSC indicates that thermal stability of the composites is enhanced. This is due to the intercalation of molecular chains of matrix with exfoliated layers of MMT.
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