Browsing by Author "Ajmer Singh Grewal"
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Item Design, Synthesis and Antidiabetic Activity of Novel Sulfamoyl Benzamide Derivatives as Glucokinase Activators(Chitkara University Publications, 2018-11-02) Ajmer Singh Grewal; Kapil Sharma; Sukhbir Singh; Vikramjeet Singh; Deepti Pandita; Viney LatherThe present work has been planned to design, synthesize and evaluate the antidiabetic potential of a series of sulfamoyl benzamide derivatives as potential glucokinase (GK) activators. A new series of sulfamoyl benzamide derivatives was synthesized starting from 3-nitrobenzoic acid and characterized. In silico docking studies were performed to determine the binding interactions for the best fit conformations in the allosteric site of GK enzyme. Based on the results of in silico studies, the selected molecules were tested for their antidiabetic activity in animal studies (alloxan induced diabetic animal model). Compound 7 exhibited highest antidiabetic activity in animal studies. The results of in vivo antidiabetic activity studies were found to be in parallel to that of docking studies. These newly synthesized sulfamoyl benzamide derivatives thus can be treated as the initial hits for the development of novel, safe, effective and orally bioavailable GK activators as therapeutic agents for the treatment of type 2 diabetes.Item In Silico Designing of Novel Thiazolidine-2-one Derivatives as Dual PDE4/7 Inhibitors for Inflammatory Disorders(Chitkara University Publications, 2017-11-02) Ajmer Singh Grewal; Neelam Sharma; Sukhbir Singh; Sandeep AroraPhosphodiesterase 4 (PDE4) and phosphodiesterase 7 (PDE7), members of PDE super family, catalyse metabolism of secondary messenger cyclic adenosine monophosphate leading to augmented inflammatory processes in pro-inflammatory and immune-modulatory cells. Dual inhibitors of PDE4/7 are a novel class of drug candidates which can regulate pro-inflammatory as well as function of immune T-cell and are particularly beneficial for the treatment of various inflammatory diseases devoid of unwanted actions. Intense efforts have been directed towards the development of effective dual inhibitors of both PDE4 and PDE7, but not much success has been reported till yet. The aim of present study was to design some newer substituted thiazolidine-2-one derivatives as dual inhibitors of PDE4/7 using structure based rational drug design approach. A new series of thiazolidine-2-one analogues were designed and molecular docking was performed using AutoDock Vina to explore the bonding interactions of the designed molecules with the amino acid residues in the active site of target proteins. The docking study indicated that all the substituted thiazolidine-2-one derivatives have appreciable binding interactions with protein residues of both PDE4 and PDE7. The newly designed compounds could be used as lead molecules for development potent and non-toxic dual inhibitors of PDE4/7 for the management of various inflammatory conditions.Item Molecular Docking Evaluation of Some Natural Phenolic Compounds as Aldose Reductase Inhibitors for Diabetic Complications(Chitkara University Publications, 2017-11-02) Ajmer Singh Grewal; Neelam Sharma; Sukhbir Singh; Sandeep AroraThe enzyme aldose reductase (AR) is a member of aldoketoreductase super-family which catalyzes the formation of sorbitol from glucose through polyol pathway of glucose catabolism. Reduced sorbitol production via polyol pathway due to AR inhibition is a target of choice for controlling major complications of diabetes. Epalrestat is the only commercially available inhibitor of AR till date,thus, there is a great need to search for more economical, nontoxic and safer inhibitors of AR enzyme. Flavonoids, the polyphenol compounds in plants have been reported for inhibitory effects against AR. The objective of this study is to explore the binding modes of natural phenolic compounds with AR to design safer natural drugs as alternatives to synthetic drugs. We conducted a molecular docking study on some natural phenolic compounds with AR enzyme in complex with the synthetic inhibitor. The overlay of the docked pose of the selected natural phenols with the ARreference inhibitor complex showed that the selected natural compounds have the similar binding pattern with the active site residues of the enzyme as that of co-crystallized inhibitor. The results of docking study showed the best binding affinity of AR with that of 2-(4-hydroxy-3-methoxyphenyl) ethanoic acid and butein, having the lowest binding free energy of –9.8 kcal/mol and–9.7 kcal/mol, respectively. This information can be utilized to design potent, economical and non-toxic natural AR inhibitors from natural phenols for the therapeutics of diabetic complications.Item Molecular Docking Studies of Phenolic Compounds from Syzygium cumini with Multiple Targets of Type 2 Diabetes(Chitkara University Publications, 2018-11-02) Ajmer Singh Grewal; Neelam Sharma; Sukhbir Singh; Sandeep AroraTreatment of type 2 diabetes without any side effects is still a challenge to the medical system. This leads to increasing demand for natural products with antidiabetic activity with fewer side effects. Syzygium cumini is a traditional herbal medicinal plant and is reported to possess a variety of pharmacological actions. It contains various types of chemical constituents including terpenoids, tannins, anthocyanins, flavonoids and other phenolic compounds. Some flavonoids and other phenolic compounds from S. cumini were reported in literature to have type 2 antidiabetic potential. The main objective of the current investigation was in silico screening of some phenolic compounds from S. cumini against multiple targets associated with type 2 diabetes to explore the mechanism of antidiabetic action and prediction of binding mode using molecular docking studies. In silico docking studies were performed for the selected molecules in the binding site of multiple targets associated with type 2 diabetes (α-glucosidas , dipeptidyl peptidase 4, glycogen synthase kinase 3, glucokinase and glucagon receptor). Amongst the compounds tested in silico, rutin showed appreciable binding with multiple targets of type 2 diabetes including α-glucosidase, dipeptidyl peptidase 4, glycogen synthase kinase 3, and glucagon receptor. Catechin was found to inhibit both α-glucosidase, and dipeptidyl peptidase 4. This information can be utilized for the design and development of potent multi-functional candidate drugs with minimal side effects for type 2 diabetes therapeuticsa.