Novel Macrocyclic Bidentate Schiff’s base Hg (II) Complexes, Hirshfeld surface analysis, NCI analysis, and Antimicrobial activity studies

IF 2.4 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR Polyhedron Pub Date : 2024-09-07 DOI:10.1016/j.poly.2024.117194

Anil Kumar Pal , Amit Jaiswal , Ritu Ravi , Kapil Kumar Yadav , Dharmendra Kumar Sahu , Ranjeet Kumar , Monika Singh

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Abstract

The authors synthesized and characterized macrocyclic complex compounds of the general formula [M-LX2], where M is Hg (II). They created a number of unimolecular Schiff base complexes of mercury (II) comprising bidentate ligands with N donors. The macrocyclic ligands were used to create the complexes (MCl2L) in methanol. This includes various experimental techniques such as spectroscopy (UV–Vis, IR, and NMR), powder-XRD to characterize the complexes and verify theoretical predictions. By further studying how intermolecular contacts impact the crystal packing of ligand, we used Hirshfeld surface analysis and corresponding 2D fingerprint plots of trimesic acid. The antimicrobial findings for Gram-positive and Gram-negative bacterial and fungal strains were also analyzed using Protein-Ligand Interaction Profilers (PLIP) and Molecular Docking (MD). In silico investigations employ molecular docking to establish a connection between the targeted proteins accountable for bacterial or cancerous characteristics and the experimental binding outcomes of complexes. The study specifically focused on the E. coli enzyme (PDB: 3T88).

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新型大环双齿席夫碱 Hg (II) 配合物、Hirshfeld 表面分析、NCI 分析和抗菌活性研究

作者合成并鉴定了通式为 [M-LX2]（其中 M 为汞（II））的大环络合物。他们创造了许多单分子希夫碱汞 (II) 配合物，这些配合物由带有 N 给体的双齿配体组成。大环配体用于在甲醇中生成络合物（MCl2L）。这包括各种实验技术，如光谱（紫外-可见光、红外和核磁共振）、粉末 X 射线衍射，以确定配合物的特性并验证理论预测。通过进一步研究分子间接触如何影响配体的晶体堆积，我们使用了 Hirshfeld 表面分析和相应的三美酸二维指纹图谱。我们还使用蛋白质配体相互作用剖析器（PLIP）和分子对接（MD）分析了对革兰氏阳性和革兰氏阴性细菌及真菌菌株的抗菌结果。硅学研究采用分子对接技术，在细菌或癌症特征的目标蛋白质与复合物的实验结合结果之间建立联系。这项研究特别关注大肠杆菌酶（PDB：3T88）。

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来源期刊

Polyhedron 化学-晶体学

CiteScore

4.90

自引率

7.70%

发文量

515

审稿时长

2 months

期刊介绍： Polyhedron publishes original, fundamental, experimental and theoretical work of the highest quality in all the major areas of inorganic chemistry. This includes synthetic chemistry, coordination chemistry, organometallic chemistry, bioinorganic chemistry, and solid-state and materials chemistry. Papers should be significant pieces of work, and all new compounds must be appropriately characterized. The inclusion of single-crystal X-ray structural data is strongly encouraged, but papers reporting only the X-ray structure determination of a single compound will usually not be considered. Papers on solid-state or materials chemistry will be expected to have a significant molecular chemistry component (such as the synthesis and characterization of the molecular precursors and/or a systematic study of the use of different precursors or reaction conditions) or demonstrate a cutting-edge application (for example inorganic materials for energy applications). Papers dealing only with stability constants are not considered.