Balaglitazone (DRF-2593) is a novel partial agonist of PPAR-gamma (γ), which is developed by Dr. Reddy's laboratories India. Balaglitazone is a second generation peroxisome proliferator-activated receptor (PPAR) gamma agonist with only partial agonistic properties. Balaglitazone is currently being evaluated in phase III clinical trial in United States and Europe. Selective PPAR-γ modulators bind in distinct manners to the ligand-binding pocket of PPAR-γ, leading to alternative receptor conformations, differential cofactor recruitment/displacement, differential gene expression, and ultimately differential biological responses. Based on this concept, new and improved novel antidiabetic agents are in current development. Clinical studies conducted with 409 subjects of randomized, double blind, parallel-group placebo and active comparator-controlled subject groups to determine the efficacy and safety of Balaglitazone. The study showed that the trial met its primary endpoint. Balaglitazone treated groups shown significantly reduce of HbA1c (%), FSG (mmol/L), postprandial glucose as comparison to pioglitazone. Phase III clinical studies data clearly shows that Balaglitazone provides robust glycemic control as an add-on to insulin therapy. Balaglitazone 10 mg and 20 mg show the similar magnitudes of the effects which comparable to the effects seen in the pioglitazone 45 mg group. The incidence of fluid retention and fat accumulation fewer than those observed with pioglitazone 45 mg. Hence, Balaglitazone is prominent candidate of new glitazone which requires fewer doses as comparison pioglitazone and shows better safety profile less incidence of special adverse effect like heart failure, peripheral oedema, and myocardial infarction. Unlike other marketed PPAR gamma agonists, Balaglitazone shows less fluid retention, less heart enlargement and no reduction of bone formation than full PPAR gamma agonists in preclinical studies. In present review, we have tried to cover classification PPARs various ligands, chemistry, physical properties, commercial synthesis, current patent status, polymorphic information, receptor interaction, pharmacophore rational, mechanism, adverse effect and clinical status of Balaglitazone, giving emphasis on medicinal chemistry aspect.
Chemically, methylxanthine nucleus based Linagliptin (BI-1356, BI-1356-BS) is a dipeptidyl peptidase-IV inhibitor, which has been developed by Boehringer Ingelheim in association with Lilly for the treatment of Type-II Diabetes. Linagliptin was marketed by Lilly under the trade name Tradjenta and Trajenta. Linagliptin was approved as the once-daily dose by USFDA on 2 May 2011, for the treatment of Type-II Diabetes. Linagliptin 5mg once daily dose was approved based on a clinical trial program, which was conducted on approximately 4,000 adults with Type-II Diabetes. Linagliptin demonstrated statistically significant mean difference in HbA1c from placebo of up to 0.72 percent, when it was used monotherapically. In patients, who were not adequately controlled on metformin or metformin plus sulphonylurea, the addition of Linagliptin resulted in a statistically significant mean difference in HbA1c from placebo of -0.6 percent. Linagliptin was observed to produce significant reduction in fasting plasma glucose (FPG) compared to placebo, when used as a monotherapy in combination with metformin, sulfonylurea and/or pioglitazone. Linagliptin demonstrated significant reduction post-prandial glucose (PPG) levels in two hours as compared with placebo in monotherapy as well as in combination with metformin. In vitro assays also anticipated that Linagliptin is a potent DPPIV inhibitor as well as it exhibits good selectivity for DPP-IV as compared with other DPPs. The in-vivo studies also demonstrated same anticipation with respect to Linagliptin. Consequently, increasing the GLP-1 levels so far improved glucose tolerance in both healthy animals. X-ray crystallography anticipates that Linagliptin complexes with human DPPIV enzyme, e.g. butynyl substituent occupies the S1 hydrophobic pocket of the enzyme; the aminopiperidine substituent in the xanthine scaffold occupies the S2 subsite and its primary amine interacts with the key amino acid residues, which involves in the recognition of peptide substrates. In the present review, we have tried to cover comparative study of DPPIV inhibitors, chemistry, physical properties, commercial synthesis, patent portfolio, crystalline polymorphic forms of Linagliptin and its receptor interaction, Pharmacophore rational, mechanism, clinical studies, preclinical, adverse effect, available formulations, dose regimen, co-therapy of Linagliptin, giving emphasis on the medicinal chemistry aspects.
Apixaban (BMS-562247-01) is a compound being investigated as an anticoagulant. Apixaban molecule is developed in a joint venture by Pfizer and Bristol-Myers Squibb. Apixaban, a coagulation factor Xa inhibitor, approved in the E.U. in 2011 for the prevention of venous thromboembolic events in adult patients, who have undergone elective hip or knee replacement. The Apixaban based drug will be marketed under the brand name Eliquis® and is expected to rack up annual sales of over $2.5 billion. Apixaban is expected to provide stiff competition to warfarin, a popular blood thinner used in Europe. Warfarin is known to cause some serious side effects in patients. Apixaban, as compared with aspirin, reduced the risk of stroke or systemic embolism in patients experiencing atrial fibrillation by more than 50% (from 3.7% per annum with aspirin to 1.6% per annum with apixaban). Apixaban exhibits superiority to enoxaparin in preventing thrombosis in patients undergoing elective hip replacement surgery with similar bleeding rates. Apixaban is a highly selective and potent Factor Xa Inhibitor with Ki=0 8nM to both free as well as prothrombinase bound FXa. In X-ray crystal structure studies indicate that the pyrazole N-2 nitrogen atom interacts with backbone of Gln192 and the carbonyl oxygen of carboxamide interacts with NH of Gly216. The orientation of phenyllactum in the S4 region indiacates an edge to face interaction with Trp215, which is positioned between the Tyr99 and Phe174. In the present review, we have tried to cover comparative study of various FXa-inhibitors and point out apixaban in the various aspect including molecular chemistry, physical properties, commercial synthesis, current patent status, crystalline polymorphic forms, molecular receptor interaction, pharmacophore rational, mechanism of action, clinical studies, preclinical, adverse effect, available formulation, dose regimen and co-therapy, thus giving emphasis on medicinal chemistry aspects.
Alogliptin (codenamed SYR-322) is a recently approved anti-diabetic drug in Japan, which has been under clinical development phase III in USA and Europe. Alogliptin has been developed by Takeda under the brand name "Nesina". Alogliptin is a highly selective ( > 10,000-time selectivity, potent, reversible and durable serine protease dipeptidyl peptidase IV enzyme is compared to DPP-8 and DPP-9) inhibitor, which has been developed as an alternative second-line to metformin in place of a sulphonylurea. Alogliptin has been observed to increase and prolong the action of incretin hormone by inhibiting the DPP-IV enzyme activity. Alogliptin has been observed to well absorb and show low plasma protein binding, which displays slow-binding properties to DPP-IV enzyme. The X-ray crystallography studies have been revealed that Alogliptin binds to DPP-IV active site by non-covalently and provides sustained reduction of plasma DPP-IV activity as well as lowering of blood glucose, in drug-naive patients with T2DM and inadequate glycemic control, once daily oral dosing regimen with varying levels of doses ranging from 25-800 mg. Alogliptin is approved as monotherapy and in combination with alpha-glucosidase & thiazolidinediones. The 26 week clinical study of Alogliptin revealed that Alogliptin doesn't increase the weight and well tolerated. In the present review, we have tried to cover biology of DPP-IV, molecular chemistry, chemical characterization, crystal polymorphic information, interaction studies, commercial synthesis, current patent status, adverse effects and clinical status of Alogliptin giving emphasis on the medicinal chemistry aspect.
Three-dimensional pharmacophore hypothesis was established based on a set of known DPP-IV inhibitor using PharmaGist software program understanding the essential structural features for DPP-IV inhibitor. The various marketed or under developmental status, potential gliptins have been opted to build a pharmacophore model, e.g. Sitagliptin (MK- 0431), Saxagliptin, Melogliptin, Linagliptin (BI-1356), Dutogliptin, Carmegliptin, Alogliptin and Vildagliptin (LAF237). PharmaGist web based program is employed for pharmacophore development. Four points pharmacophore with the hydrogen bond acceptor (A), hydrophobic group (H), Spatial Features and aromatic rings (R) have been considered to develop pharmacophoric features by PharmaGist program. The best pharmacophore model bearing the Score 16.971, has been opted to screen on ZincPharmer database to derive the novel potential anti-diabetic ligands. The best pharmacophore bear various Pharmacophore features, including General Features 3, Spatial Features 1, Aromatic 1 and Acceptors 2. The PharmaGist employed algorithm to identify the best pharmacophores by computing multiple flexible alignments between the input ligands. The multiple alignments are generated by combining alignments pair-wise between one of the gliptin input ligands, which acts as pivot and the other gliptin as ligand. The resulting multiple alignments reveal spatial arrangements of consensus features shared by different subsets of input ligands. The best pharmacophore model has been derived using both pair-wise and multiple alignment methods, which have been weighted in Pharmacophore Generation process. The highest-scoring pharmacophore model has been selected as potential pharmacophore model. In conclusion, 3D structure search has been performed on the "ZincPharmer Database" to identify potential compounds that have been matched with the proposed pharmacophoric features. The 3D ZincPharmer Database has been matched with various thousands of Ligands hits. Those matches were screened through the RMSD and max hits per molecule. The physicochemical properties of various "ZincPharmer Database" screened ligands have been calculated by PaDELDescriptor software. The all "ZincPharmer Database" screened ligands have been filtered based on the Lipinski's rule-of-five criteria (i.e. Molecular Weight < 500, H-bond acceptor ≤ 10, H-bond donor ≤ 5, Log P ≤ 5) and were subjected to molecular docking studies to get the potential antidiabetic ligands. We have found various substituted as potential antidiabetic ligands, which can be used for further development of antidiabetic agents. In the present research work, we have covered rational of DPP-IV inhibitor based on Ligand-Based Pharmacophore detection, which is validated via the Docking interaction studies as well as Maximal Common Substructure (MCS).
The article describes the development of a robust pharmacophore model and the investigation of structure activity relationship analysis of 46 xanthine derivatives reported for DPP-IV inhibition using PHASE module of Schrodinger software. The present works also encompasses molecular interaction of 46 xanthine ligand through maestro 8.5 software. The QSAR study comprises AHHR.7 pharmacophore hypothesis, which elaborates the three points, e.g. one hydrogen bond acceptor (A), two hydrophobic rings (H) and one aromatic ring (R). The discrete geometries as pharmacophoric feature were developed and the generated pharmacophore model was used to derive a predictive atom-based 3D QSAR model for the studied data set. The obtained 3D QSAR model has an excellent correlation coefficient value (r(2)= 0.9995) along with good statistical significance which is indicated by high Fisher ratio (F= 8537.4). The model also exhibits good predictive power confirmed by the high value of cross validated correlation coefficient (q(2) = 0.6919). The QSAR model suggests that hydrophobic character is crucial for the DPP-IV inhibitory activity exhibited by these compounds and inclusion of hydrophobic substituents will enhance the DPP-IV inhibition. In addition to the hydrophobic character, electron withdrawing groups positively contribute to the DPP-IV inhibition potency. The findings of the QSAR study provide a set of guidelines for designing compounds with better DPP-IV inhibitory potency.
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