363-45-1

Upstream product

• 28177-48-2 2,6-difluorophenol 
• 437-82-1 1,3-difluoro-2-methoxybenzene 
• 79-11-8 chloroacetic acid 

Downstream Products

• 1093409-11-0 KNI-10265 

Relevant academic research and scientific papers

Effect of o-difluoro and p-methyl substituents on the structure, optical properties and anti-inflammatory activity of phenoxy thiazole acetamide derivatives: Theoretical and experimental studies

Thiazole derivatives (6a and 6b) have been synthesized and characterised by 1H –13C NMR, as well as LC-MS spectra. The three-dimensional structures have been confirmed by single crystal X-ray diffraction method. 6a and 6b compounds have been crystallized in the Triclinic and the Orthorhombic systems with P-1 and Pbca space groups, respectively. Supramolecular structures revealed the stability of molecules with different intermolecular interactions and different crystal packing environment. Theoretical study by Density functional theory (DFT) with B3LYP functional based on highest basis set 6–311++G(d,p) was employed to calculate the geometry and compared to the experimental data. The electronic structures and intramolecular charge transfers have been investigated by using natural population and natural bond orbital analysis (NBO). Further, DFT studies were performed to assess the frontier molecular orbitals (FMOs), energy gap, softness, hardness, and others chemical reactivity. Hirshfeld surface was investigated to distinguish the different interatomic contacts and understand the crystal packing of molecules with aid of energy frameworks through different intermolecular interaction energies based on the anisotropy of the topology. Nonlinear optical property (NLO) of the synthesized molecules were predicted by (DFT) and examined experimentally by using second harmonic generation (SHG) and revealed the importance of high NLO based on the nature of substituents and conformation. Thiazole derivatives were assessed for anti-inflammation activity by in silico molecular docking studies against COX-1 and COX-2 protein receptors revealed prominent interactions with active site and further molecular dynamics confirms the stability of the protein-ligand model. In vitro assay against cyclooxygenase (COX) enzyme gave IC50 values of 6a and 6b molecules with ortho-difluoro and para-methyl positions on benzoyl group, showed better inhibitor for COX-1 and COX-2, respectively.

Antimalarial activity enhancement in hydroxymethylcarbonyl (HMC) isostere-based dipeptidomimetics targeting malarial aspartic protease plasmepsin

Plasmepsin (Plm) is a potential target for new antimalarial drugs, but most reported Plm inhibitors have relatively low antimalarial activities. We synthesized a series of dipeptide-type HIV protease inhibitors, which contain an allophenylnorstatine-dimethylthioproline scaffold to exhibit potent inhibitory activities against Plm II. Their activities against Plasmodium falciparum in the infected erythrocyte assay were largely different from those against the target enzyme. To improve the antimalarial activity of peptidomimetic Plm inhibitors, we attached substituents on a structure of the highly potent Plm inhibitor KNI-10006. Among the derivatives, we identified alkylamino compounds such as 44 (KNI-10283) and 47 (KNI-10538) with more than 15-fold enhanced antimalarial activity, to the sub-micromolar level, maintaining their potent Plm II inhibitory activity and low cytotoxicity. These results suggest that auxiliary substituents on a specific basic group contribute to deliver the inhibitors to the target Plm.

Alpha-hydroxyarylbutanamine inhibitors of aspartyl protease

Acylated α-hydroxyarylbutanamines and related sulfonamides, ureas and carbamates that inhibit aspartyl protease are disclosed, as are methods of treating diseases, particularly HIV, using these compounds. The compounds have the formula: 1A representative

Skeletal Rearrangements Preceding CO Loss from Metastable Phenoxymethylene Ions Derived from Phenoxyacetic Acid and Anisole

The loss of CHO2(.) from the molecular ion of phenoxyacetic acid and the expulsion of an H(.) atom from ionized anisole lead to phenoxymethylene ions, which fragment predominantly by CO loss on the microsecond time-scale.Carbon-13 labelling reveals that ca. 90percent of the CO molecules expelled from the metastable ions derived from phenoxyacetic acid incorporate the carbon atom from the 1-position of the phenyl group of the parent compound, whereas the residual CO molecules contain one of the other carbon atoms of the aromatic ring.The 2-fluoro- and 2-methylphenoxymethylene ions derived from the appropriate aryloxyacetic acids behave similarly, i.e. the carbon atom of the methylene group of the parent compound is not incorporated in the expelled CO molecules.In contrast, ca. 45percent of the CO molecules eliminated from the metastable phenoxymethylene ions formed from ionized anisole contain the carbon atom of the methyl group, while the remaining part contains the carbon atom from the 1-position of the phenyl ring of the parent compound.This result is taken as evidence for the occurrence of a skeletal rearrangement of the anisole molecular ion leading to an interchange between the carbon atom of the methyl group and the carbon atom at the 1-position of the ring.The elimination of CO from the metastable ions generated from either phenoxyacetic acid or anisole gives rise to a composite metastable peak.Conclusive evidence as to the formation of (+) isomers other than the phenoxymethylene ion is not obtained, indicating that the composite metastable peak is a result of two competing reactions both leading to CO loss.Possible mechanisms of these reactions are discussed together with the mechanism of the skeletal rearrangement of the molecular ion of anisole prior to H(.) loss.