Author: tianli

Application of 23002-78-0. The fused heterocycle is formed by combining a benzene ring with a single heterocycle, or two or more single heterocycles. Compound: 1-(2-Methylthiazol-4-yl)ethanone, is researched, Molecular C6H7NOS, CAS is 23002-78-0, about Heterocycles from amino ketones. XIV. Thiazolyl- and pyrrolylquinolines. Author is Kempter, Gerhard; Schaefer, Harry; Sarodnick, Gerhard.

2-(R-Substituted)-4-(R1-substituted)-quinolines (I) [where R = 2-methylthiazol-4-yl (II), 2-phenylthiazol-4-yl, 2,4-dimethylthiazol-5-yl, 2-phenyl-4-methylthiazol-5-yl, 2-amino-4-methylthiazol-5-yl, or 2-pyrryl (III); and R1 = Me or Ph] were prepared by the method of K. et al. (1964). I showed pronounced fluorescence and were tested as fluorescence indicators. Reaction of MeCSNH2 with BrCH2COC(NOH)Me gave 2-methyl-4-acetylthiazole-3-oxime, which was saponified to 2-methyl-4-acetylthiazole.

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In organic chemistry, atoms other than carbon and hydrogen are generally referred to as heteroatoms. The most common heteroatoms are nitrogen, oxygen and sulfur. Now I present to you an article called The reduction of pyridine derivatives with lithium aluminum hydride, published in 1953, which mentions a compound: 1195-58-0, mainly applied to , Quality Control of Pyridine-3,5-dicarbonitrile.

When pyridine derivatives (I) with CO2Et or CN groups at the 3- and 5-positions are treated with LiAlH4 (II) the ring system is attacked first; when the 2-, 4-, and 6-positions are substituted, the functional group are reduced. The reductions are carried out by adding a large excess of II in ether to the I in absolute ether with stirring and ice-cooling, treating the mixture with saturated NH4Cl solution, and evaporating the washed ether solution Reduction of 5 g. di-Et 2,6-lutidine-3,5-dicarboxylate in 50 cc. ether with 780 mg. II in 40 cc. ether gives 40% Et 3-hydroxymethyl-2,6-lutidine-5-carboxylate, m. 100-1°; when the mixture is refluxed 2 hrs. 65% 3,5-bis(hydroxymethyl)-2,6-lutidine, m. 141-2°, is obtained. Reduction of di-Me dinicotinate gives 50% di-Me 1,4-dihydrodinicotinate, m. 150-60°, λmaximum 220, 375 mμ (MeOH). Reduction of di-Me 2-methyl-dinicotinate also gives a dihydro derivative, b0.02 115-20°, yellow needles, m. 126°, λmaximum 220, 375 mμ (MeOH). Reduction of 10 g. 2-chloropyridine (III) with 1 g. II at 0° gives unchanged III. Reduction of 1 g. Et picolinate gives 2-pyridine methanol (picrate m. 159°). Reduction of Et 2-pyridyl-acetate gives 2-pyridineëthanol, b15 120° (picrate, m. 120°). Refluxing 50 g. dinicotinic acid with 150 cc. SOCl2 15 hrs. and treating the acid chloride with NH4OH give 26 g. diamide, m. 302°, which, warmed in 130 cc. C5H5N with 19 cc. POCl3 3 hrs at 60°, yields 15 g. dinitrile (IV), m. 113° after sublimation at 70°/1 mm. Reduction of 1 g. IV in 20 cc. ether with 300 mg. II in 10 cc. ether gives 1,4-dihydrodinicotinonitrile, yellow crystals, m. 197°, λmaximum 360 mμ (MeOH). Similar reduction of 0.43 g. 2,6-lutidine-3,5-dicarbonitrile gives the 1,4-dihydro derivative, yellow crystals, m. 225°, λmaximum 362.5 mμ (MeOH). Catalytic hydrogenation of 0.5 g. IV in 20 cc. MeOH 3 hrs. with 50 mg. PtO2, 0.5 g., gives a dihydro derivative with λmax. 360 mμ which reduces neutral AgNO3. Adding (0.5 hr.) 6.5 g. II in 300 cc. ether to 46 g. Me nicotinate in 300 cc. ether at 0°, decomposing the mixture with NH4Cl, and distilling the residue of the ether extract give 31.3 g. 3-pyridine methanol, b0.1 110° (picrate, m. 158-60°). The difference in the behavior of the pyridine esters and nitriles toward II is explained as resulting from the different polarization of the pyridine rings in these compounds

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Computed Properties of C8H12Cl2Pt. Aromatic heterocyclic compounds can also be classified according to the number of heteroatoms contained in the heterocycle: single heteroatom, two heteroatoms, three heteroatoms and four heteroatoms. Compound: Dichloro(1,5-cyclooctadiene)platinum(II), is researched, Molecular C8H12Cl2Pt, CAS is 12080-32-9, about Reactions of [Ru6(μ6–C)(C6H5CH3)(CO)14]: Synthesis of some new Ru-Pt carbonyl clusters and diphosphine substitution. Author is Ji, Radhe Shyam; Raghuvanshi, Abhinav; Jha, Badrinath; Mathur, Pradeep.

Three new RuPt clusters [Ru6Pt(μ6-C)(C6H5CH3)(CO)13(COD)] (2), [Ru6Pt(μ6-C)(C6H5CH3)(CO)14(PPh3)] (3) and [Ru6Pt2(μ6-C)(C6H5CH3)(CO)13(PPh3)3] (4) were obtained from the reaction of [Ru6(μ6-C)(C6H5CH3)(CO)14] (1) with two different Pt precursors. Both 2 and 3 consists of a Ru6Pt cluster with face capped octahedron metal core, whereas, 4 has a unique Ru6Pt2 cluster core structure with doubly capped octahedron. Further, CO substitution behavior of 1 was studied with diphosphine ligands, which results in the formation of mono and bi substituted products, which also show the removal of the toluene cap by the dppe ligand. All the compounds were characterized structurally by x-ray diffraction anal.

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Category: alcohols-buliding-blocks. Aromatic heterocyclic compounds can also be classified according to the number of heteroatoms contained in the heterocycle: single heteroatom, two heteroatoms, three heteroatoms and four heteroatoms. Compound: 3-Bromo-4-chloronitrobenzene, is researched, Molecular C6H3BrClNO2, CAS is 16588-26-4, about Development of a Tripeptide Mimetic Strategy for the Inhibition of Protein Farnesyltransferase. Author is Kothare, Mohit A.; Ohkanda, Junko; Lockman, Jeffrey W.; Qian, Yimin; Blaskovich, Michelle A.; Sebti, Said M.; Hamilton, Andrew D..

This paper describes the development of a novel terphenyl-based tripeptide mimetic of the CAAX carboxy terminal sequence of Ras. We employ a concise synthesis to form a series of differently functionalized terphenyl inhibitors of protein farnesyltransferase (PFTase), exemplified by I [R = (S)-HSCH2CH(NH2)CH2- (II); R = HS-3-C6H4C(O)- (III); R = HSCH2CH2C(O)- (IV)]. The key reaction in the synthesis of the terphenyl Me ester, and therefore III and IV, was the Pd-catalyzed chemoselective Suzuki cross-coupling of 3-bromo-4-chloronitrobenzene with an appropriate boronic acid derivative utilizing a com. available, electron rich phosphine ligand. We further show that II is a potent inhibitor of PFTase.

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Product Details of 16588-26-4. The reaction of aromatic heterocyclic molecules with protons is called protonation. Aromatic heterocycles are more basic than benzene due to the participation of heteroatoms. Compound: 3-Bromo-4-chloronitrobenzene, is researched, Molecular C6H3BrClNO2, CAS is 16588-26-4, about Optimization of 5-(2,6-dichlorophenyl)-3-hydroxy-2-mercaptocyclohex-2-enones as potent inhibitors of human lactate dehydrogenase. Author is Labadie, Sharada; Dragovich, Peter S.; Chen, Jinhua; Fauber, Benjamin P.; Boggs, Jason; Corson, Laura B.; Ding, Charles Z.; Eigenbrot, Charles; Ge, HongXiu; Ho, Qunh; Lai, Kwong Wah; Ma, Shuguang; Malek, Shiva; Peterson, David; Purkey, Hans E.; Robarge, Kirk; Salphati, Laurent; Sideris, Steven; Ultsch, Mark; VanderPorten, Erica; Wei, BinQing; Xu, Qing; Yen, Ivana; Yue, Qin; Zhang, Huihui; Zhang, Xuying; Zhou, Aihe.

Optimization of 5-(2,6-dichlorophenyl)-3-hydroxy-2-mercaptocyclohex-2-enone using structure-based design strategies resulted in inhibitors with considerable improvement in biochem. potency against human lactate dehydrogenase A (LDHA). These potent inhibitors were typically selective for LDHA over LDHB isoform (4-10 fold) and other structurally related malate dehydrogenases, MDH1 and MDH2 (>500 fold). An X-ray crystal structure of enzymically most potent mol. bound to LDHA revealed two addnl. interactions associated with enhanced biochem. potency.

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Formula: C10H10ClNO. The mechanism of aromatic electrophilic substitution of aromatic heterocycles is consistent with that of benzene. Compound: 1-(4-Chlorophenyl)pyrrolidin-2-one, is researched, Molecular C10H10ClNO, CAS is 7661-33-8, about Mild and Efficient Cobalt-Catalyzed Cross-Coupling of Aliphatic Amides and Aryl Iodides in Water. Author is Tan, Bryan Yong-Hao; Teo, Yong-Chua.

A convenient protocol for the C-N cross-coupling of aliphatic amides and iodobenzene is demonstrated using a simple and inexpensive Co(C2O4)·2H2O/N,N’-dimethylethylenediamine (DMEDA) catalytic system in water. Good yields of N-arylated products I [R1 = Pr, i-Pr, Bu, etc; R2 = Ph, 2-F-C6H4, 4-Me-C6H4, etc.] were isolated (up to 85%) and the protocol has been successfully applied to the synthesis of the anticancer drug, flutamide.

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In general, if the atoms that make up the ring contain heteroatoms, such rings become heterocycles, and organic compounds containing heterocycles are called heterocyclic compounds. An article called Regioselective metalation of the 4-position of pyridine. New and convenient alkylation and acylation of 3-amino-5-methoxypyridine, published in 1981-08-14, which mentions a compound: 77903-28-7, Name is 5-Methoxy-4-methylpyridin-3-amine, Molecular C7H10N2O, COA of Formula: C7H10N2O.

The reaction of 3-methoxy-5-pivaloylaminopyridine with BuLi at low temperature in THF gives the 4-lithiopyridines, which react with various electrophiles to give the corresponding 4-substituted 3-methoxy-5-pivaloylaminopyridines. The conversion of the 5-pivaloylamino group to other substituents via the pyridyl radical was also examined

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Reference of 1-(4-Chlorophenyl)pyrrolidin-2-one. Aromatic compounds can be divided into two categories: single heterocycles and fused heterocycles. Compound: 1-(4-Chlorophenyl)pyrrolidin-2-one, is researched, Molecular C10H10ClNO, CAS is 7661-33-8, about Selective synthesis of pyrrolidin-2-ones and 3-iodopyrroles via the ring contraction and deformylative functionalization of piperidine derivatives. Author is Wang, Fang; Zhang, Xinying; He, Yan; Fan, Xuesen.

In this paper, a selective synthesis of pyrrolidin-2-ones and 3-iodopyrroles via the cascade reactions of N-substituted piperidines is presented [e.g., N-phenylpiperidine → N-phenyl-2-pyrrolidinone (58%) in presence of Cu(OAc)2/KI/Oxone/O2 in MeCN and N-phenylpiperidine → 3-iodo-N-phenylpyrrole (65%) in presence of Cu(OAc)2/I2/DMAP/O2 in MeCN]. Mechanistically, the formation of pyrrolidin-2-ones involves a domino process including the in situ formation of pyrrolidine-2-carbaldehyde followed by carboxylic acid formation, decarboxylation and ipso-oxidation On the other hand, 3-iodopyrroles are believed to be formed via the initial generation of pyrrolidine-2-carbaldehyde followed by carboxylic acid formation, decarboxylation, dehydrogenation, iodination and aromatization. Interestingly, either pyrrolidin-2-ones or 3-iodopyrroles could be obtained selectively from the same substrates, and the selectivity was easily tuned by using a specific oxidant and additive.

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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Reaction of Grignard reagent with 3,5-dicyanopyridines》. Authors are Lukes, R.; Kuthan, J..The article about the compound:Pyridine-3,5-dicarbonitrilecas:1195-58-0,SMILESS:N#CC1=CC(C#N)=CN=C1).Related Products of 1195-58-0. Through the article, more information about this compound (cas:1195-58-0) is conveyed.

Et2O solutions of 3,5-dicyanopyridines reacted at 20-40° with MeMgI (Ia) or EtMgBr (Ib) in 4-6-fold excess to form NH.CR1:C(CN).CR2:C(CN).CHR3 or NH.CR1:C(CN).CHR2.C(CN):CR3. The following were prepared: R1 = R2 = R3 = H (I); R1 = R2 = H, R3 = Me (II); R1 = R3 = H, R2 = Et (III); R1 = Me, R2 = R3 = H (IV); R1 = R3 = Me, R3 = H (V); R1 = R3 = Me, R2 = H (VI); R1 = H, R2 = R3 = Me (VII); R1 = H, R2 = Me, R3 = Et (VIII); R1 = H, R2 = Et, R3 = Me (IX); R1 = R3 = Me, R2 = H (X); R1 = R2 = R3 = Me (XI); R1 = R2 = H, R3 = Me (XII); R1 = R3 = H, R2 = Et (XIII); R1 = R2 = Me, R3 = H (XIV); R1 = R2 = R3 = Me (XV). I with Ia gave 76% XII, I with Ib 65% XIII, II with Ia 66% VII, II with Ib 48% VIII, III with Ia 89% IX, IV with Ia about 43% X and XIV, V with Ia 82% XI, VI with Ia 35% XV.

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Safety of 1-(4-Chlorophenyl)pyrrolidin-2-one. So far, in addition to halogen atoms, other non-metallic atoms can become part of the aromatic heterocycle, and the target ring system is still aromatic. Compound: 1-(4-Chlorophenyl)pyrrolidin-2-one, is researched, Molecular C10H10ClNO, CAS is 7661-33-8, about Ruthenium-catalyzed synthesis of N-substituted lactams by acceptorless dehydrogenative coupling of diols with primary amines.

The first example of synthesis of N-substituted lactams I (R = Ph, 4-(propan-2-yl)phenyl, 2H-1,3-benzodioxol-5-yl, naphthalen-2-yl, etc.; n = 1,2,3) and N-(p-tolyl)isoindolin-2-one via an acceptorless dehydrogenative coupling of diols HO(CH2)2(CH2)nCH2OH and [2-(hydroxymethyl)phenyl]methanol with primary amines RNH2 in one step, which was enabled by combining Ru3(CO)12 with a hybrid N-heterocyclic carbene-phosphine-phosphine ligand as the catalyst have been reported.

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