Synthesis, Spectral Investigations, Biological Potential and Molecular
Docking Study of Novel Schiff Base and its Transition Metal Complexes

Kumar, Manoj; Aggarwal, Pallvi; Varol, Mehmet; Sharma, Shashi; Rani, Anita; Abbas, Zahoor; Prakash, V.; Tuli, Hardeep Singh

doi:10.2174/2211352519666211104090749

Cited by 2 publications

(1 citation statement)

References 44 publications

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“…Due to the presence of azomethine linkage (>C=N-), complexes have been found to inhibit microbial growth. Different mechanisms have been suggested including the inhibition of cell wall synthesis and loss of the bioactivity of fundamental enzymes, such as dihydropteroate synthase [49,50]. In the current study, the examined ligand and their metal complexes possess strong anti-microbial activities.…”

Section: Antimicrobial Assaymentioning

confidence: 82%

Synthesis, Structural Investigations, and In Vitro/In Silico Bioactivities of Flavonoid Substituted Biguanide: A Novel Schiff Base and Its Diorganotin (IV) Complexes

et al. 2022

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Quercetin is one of the most powerful bioactive dietary flavonoids. The in vivo biological study of quercetin is extremely difficult due to its very low solubility. However, diorganotin complexes of quercetin are more useful when contrasted with quercetin due to increased solubility. In the present study, quercetin, substituted biguanide synthesized in the form of Schiff base and its di-alkyl/aryl tin (IV) complexes were obtained by condensing Schiff base with respective di-alkyl/aryl tin (IV) dichloride. Advanced analytical techniques were used for structural elucidation. The results of biological screening against Gram-positive/Gram-negative bacteria and fungi showed that these diorganotin (IV) derivatives act as potent antimicrobial agents. The in silico investigation with dihydropteroate (DHPS) disclosed a large ligand–receptor interaction and revealed a strong relationship between the natural exercises and computational molecular docking results.

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Section: Antimicrobial Assaymentioning

confidence: 82%

Synthesis, Structural Investigations, and In Vitro/In Silico Bioactivities of Flavonoid Substituted Biguanide: A Novel Schiff Base and Its Diorganotin (IV) Complexes

et al. 2022

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New Schiff Base Derived Organotin (IV) Complexes: Synthesis, Characterization, In vitro and In silico Biological Studies

Kumar,

Siwach,

Sharma

et al. 2024

AIA

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Aims: The creation and testing of new Schiff base-based antibacterial organotin (IV) complexes were the objectives of this investigation. background: Due to developed resistance, antibiotics that were once often used to treat microorganisms are no longer effective against them. It is thought that organotin compounds synthesized from Schiff bases have significant pharmacological effectiveness and work well as antibacterial agents Background: Due to developed resistance, antibiotics that were once often used to treat microor-ganisms are no longer effective against them. It is thought that organotin compounds synthesized from Schiff bases have significant pharmacological effectiveness and work well as antibacterial agents. Methods: Thiocarbohydrazide and dehydroacetic acid were condensed to create the Schiff base, followed by processing with dialkyltin(IV)dichloride to synthesize the final product. Modern an-alytical techniques were used to clarify the compounds' probable structural details. The crystalline nature of the produced compounds was tested using PXRD. Results: All of the compounds were thermally stable up to 300°C. All of the synthesized com-plexes showed potent antibacterial activity in the range of 250 to 400 μg/ml. Furthermore, the computational biology research showed that, in contrast to ligands, which had a binding energy of -7.3 to -7.4 kcal/mol, complexes interacted well with dihydropteroate synthase and DNA gy-rase. Conclusion: The current study offered a unique technique for synthesizing diorganotin(IV) de-rivatives of N-substituted Schiff bases that are physiologically active. The results show that the chemicals created are promising antibacterial mediators against diseases that affect humans in the modern world. It might also open the door to future studies on drug-resistant microorganisms that could have biological uses.

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Synthesis, Spectral Investigations, Biological Potential and Molecular Docking Study of Novel Schiff Base and its Transition Metal Complexes

Cited by 2 publications

References 44 publications

Synthesis, Structural Investigations, and In Vitro/In Silico Bioactivities of Flavonoid Substituted Biguanide: A Novel Schiff Base and Its Diorganotin (IV) Complexes

Synthesis, Structural Investigations, and In Vitro/In Silico Bioactivities of Flavonoid Substituted Biguanide: A Novel Schiff Base and Its Diorganotin (IV) Complexes

New Schiff Base Derived Organotin (IV) Complexes: Synthesis, Characterization, In vitro and In silico Biological Studies

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