Topological characterization of electron density, electrostatic potential and intermolecular interactions of 2-nitroimidazole: an experimental and theoretical study

Kalaiarasi, Chinnasamy; Pavan, Mysore S.; Kumaradhas, Poomani

doi:10.1107/s2052520616010581

Cited by 28 publications

(23 citation statements)

References 73 publications

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“…It is found that at all temperatures the ESPs of all static and dynamic charge densities possess similar features on the 0.5 e Å À3 isosurfaces of the electron densities: the most negative values appear near O atoms and the most positive values appear near H atoms. These features are in agreement with the presence of intermolecular hydrogen bonds in the crystal, and they are in line with similar features observed for static ESPs of other molecules (Kalaiarasi et al, 2016;Niranjana Devi et al, 2017;Zhurova et al, 2016). Major differences between ESPs on these isosurfaces are found between MEM densities and model densities, with a 60% larger range of values ÁV S for the MEM densities.…”

Section: Discussionsupporting

confidence: 77%

“…Quantitative measures of the ESP have been obtained as integral properties over this surface according to Politzer et al (2001) (see Table 1 Table 1 Definitions of integral quantities of the ESP, integrated over isosurfaces of the electron density according to Politzer et al (2001 Sum of positive and negative variances of the ESP Degree of the electrostatic balance derived from the variances of the ESP atoms act as acceptors of intermolecular hydrogen bonds, and these three H atoms are part of a hydrogen bond too (Mondal et al, 2012). These features of the molecular ESP are in agreement with similar features of ESPs of other molecules (Kalaiarasi et al, 2016;Niranjana Devi et al, 2017;Zhurova et al, 2016). The ESP of the static electron density of AH (20) has also been computed for a cluster of 3 Â 3 Â 3 unit cells.…”

Section: Computational Details 31 Details Of the Algorithmsupporting

confidence: 68%

“…One method of analysis comprises the consideration of the ESP on a surface enveloping the molecule. In applications to small and large molecules up to proteins, the ESP has thus been used to identify electrophilic and nucleophilic sides, to characterize hydrogen bonds, and to analyse intermolecular interactions (Du et al, 2016;Kalaiarasi et al, 2016;Kirby et al, 2014;Malinska & Dauter, 2016;Niranjana Devi et al, 2017;Sirohiwal et al, 2017;Zarychta et al, 2015;Zhurova et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Electrostatic potential of dynamic charge densities

Hübschle¹,

Smaalen²

2016

Acta Cryst Sect A

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Section: Discussionsupporting

confidence: 77%

Section: Computational Details 31 Details Of the Algorithmsupporting

confidence: 68%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Electrostatic potential of dynamic charge densities

Hübschle¹,

Smaalen²

2016

Acta Cryst Sect A

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“…Electrostatic potential. The electrostatic potential (ESP) of molecules provides rich information about the binding ability of molecules with the neighboring molecules in solids as well as the binding of ligands in the active site of enzymes (Arputharaj et al, 2012;Zhurova et al, 2016Zhurova et al, , 2009Zhurova, Matta et al, 2006;Yearley et al, 2007;Kalaiarasi et al, 2016;Kumar & Dominiak, 2016;Rajalakshmi, Hathwar et al, 2014b;Rajalakshmi, Pavan & Kumaradhas, 2014;Rajalakshmi, Hathwar et al, 2014a;Dominiak et al, 2007;Fournier et al, 2009). Furthermore, in drug-receptor interactions, the ESP of a drug molecule allows molecular recognition in the biological environment (active site of receptor) to be predicted and, specifically, the reactive locations of the molecule to be identified; this information shows how the drug molecules interact with the receptor.…”

Section: Topological Bond Order and Atomic Valence Indexmentioning

confidence: 99%

“…Thus, the polarization effects on the molecule due to crystalline and the drug-receptor interaction environment are comparable. Experimental electron density studies of several drug and bio-molecules, such as estrone (Zhurova, Matta et al, 2006), 17-estradiolÁ0.5H 2 O (Zhurova et al, 2009), genistein (Yearley et al, 2007), paracetamol (Bouhmaida et al, 2009), aziridine, oxirane, olefin (Grabowsky et al, 2008), aspirin (Arputharaj et al, 2012), isoniazid (Rajalakshmi, Hathwar et al, 2014b), pyrazinamide (Rajalakshmi, Hathwar et al, 2014a), ethionamide (Rajalakshmi, Pavan & Kumaradhas, 2014), 2nitroimidazole (Kalaiarasi et al, 2016), 16,17-estriol (Zhurova et al, 2016), have been carried out and successfully established the importance of the electron density studies for understanding the nature of a molecule. The origin for the molecular recognition of a drug molecule is the structural and electrostatic complementarity with the receptor site aminoacid residues.…”

Section: Introductionmentioning

confidence: 99%

Charge density and electrostatic potential of hepatitis C anti-viral agent andrographolide: an experimental and theoretical study

Saravanan

Kalaiarasi

Pavan

et al. 2018

Acta Crystallogr Sect B

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Andrographolide (AGH) is a hepatitis C anti-viral agent which targets the host cell by covalently binding with the NF-Breceptor. The experimental electron density distribution study of AGH has been carried out from high-resolution X-ray diffraction data collected at 110.2 (3) K. The unit-cell packing of AGH was stabilized by strong O-HÁ Á ÁO and weak C-HÁ Á ÁO types of intermolecular interactions. The dissociation energy of the strong hydrogen bond O2-H22Á Á ÁO1 is very high, 32 kJ mol À1 . The percentage occupancy of HÁ Á ÁH interactions is found to be maximum (68.5%) when it comparing with the other types of interactions occurring in the AGH crystalline phase. The atomic valance index (V topo ) of the C16 atom is low compared with other carbon atoms; this shows that C16 could be the possible reactive location of the AGH molecule. All atoms in the OH groups have very low V topo values; this indicates their role in strong hydrogen bonding interactions. The electrostatic potential (ESP) surface of AGH shows the polarization of the C16 C17 bond and ESP contour map shows several maxima at the vicinity of the C16 atom; these results strongly demonstrate that the C16 atom is the reactive location of the AGH molecule. The molecular covalent docking analysis of AGH with the NF-B receptor has been performed and confirmed this result. The highly electronegative region around -butyrolactone can be helpful for initial alignment of the AGH molecule in NF-B receptor active site. The atomic volumes of the hydrogen atoms which participate in the HÁ Á ÁH interaction are found to be low.

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Structure, charge density, and Hirshfeld surface analysis of proton transfer complex 2‐amino‐4‐methylpyridinium 2‐(3‐methylphenyl)‐acetate

Anzline

Samuel

Sujatha³

et al. 2022

J Chinese Chemical Soc

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The compounds m-Tolylacetic acid and 2-amino-4-Picoline were used as a precursor to synthesize the molecular complex 2-amino-4-methylpyridinium 2-(3-methylphenyl)-acetate by means of proton transfer. High-resolution X-ray diffraction data were collected for the crystallized complex at 100 K. The structure was solved spherically and further an aspherical model refinement was performed using Hansen and Coppens multipole formalism. Topological properties using AIM analysis were carried out for the title compound to understand the atom-atom interactions and the strength of the bond. The structure exhibits interesting patterns of N-H…O and C-H…O hydrogen bonds. A pair of N-H…O hydrogen bonds links the anion and cation of the molecular complex generating an R 2 2 (8) ring motif. These ring motifs are linked to adjacent anions and cations through another intermolecular N-H…O hydrogen bond generating a bifurcated R 2 2 (8)ring motif. Hirshfeld surface analysis was carried out to understand the types of inter-molecular interactions and their strengths.

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Topological characterization of electron density, electrostatic potential and intermolecular interactions of 2-nitroimidazole: an experimental and theoretical study

Cited by 28 publications

References 73 publications

Electrostatic potential of dynamic charge densities

Electrostatic potential of dynamic charge densities

Charge density and electrostatic potential of hepatitis C anti-viral agent andrographolide: an experimental and theoretical study

Structure, charge density, and Hirshfeld surface analysis of proton transfer complex 2‐amino‐4‐methylpyridinium 2‐(3‐methylphenyl)‐acetate

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