Day: April 1, 2022

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 Chemistry of vitamin B6. IX. Derivatives of 5-deoxypyridoxine, published in 1953, which mentions a compound: 148-51-6, mainly applied to , SDS of cas: 148-51-6.

cf. C.A. 47, 8745g. The 5-deoxy derivatives (I) of pyridoxine (II), pyridoxal (III), and pyridoxamine (IV) were prepared and characterized. The I can participate normally in biochemical reactions involving the substituent at the 4-position but cannot be phosphorylated like II, III, and IV. As expected the I had no vitamin B6 activity but were effective antimetabolites. Codecarboxylase has been catalytically hydrogenated to 5-deoxypyridoxine (V); both II and III yielded under the same conditions a mixture of 4-deoxypyridoxine (VI) and V. The absorption spectra of 5-deoxypyridoxal (VII) (recorded) and pure pyridoxal-5-phosphate (codecarboxylase) (VIII) at pH 11.0 and 1.9, resp., are almost identical. The deep yellow color of both VII and VIII in alk. solution together with other absorption characteristics is ascribed to a quinoid structure. 2-Methyl-3-hydroxy-4-methoxymethyl-5-chloromethylpyridine (IX).HCl (2.38 g.) in 125 cc. MeOH was shaken with H in the presence of 2 g. 5% Pd-Darco, the mixture filtered, and the filtrate concentrated to 20 cc. to yield 1.5 g. (75%) 2,5-dimethyl-3-hydroxy-4-methoxymethylpyridine (X).HCl, m. 152-3° (from EtOH-Et2O). IX.HCl (23.7 g.) reduced similarly in 2 equal portions, each one in 600 cc. MeOH with 5 g. Pd catalyst yielded 19.0 g. (94%) X.HCl. X.HCl (1.47 g.) in 50 cc. 4N HCl heated 3 hrs. at 180-90° in a sealed tube, the colorless solution filtered, the filtrate concentrated to dryness, and the H2O removed azeotropically with EtOH and C6H6 yielded 0.96 g. (70%) V.HCl, m. 143-3.5° (from EtOH-Et2O); treated with excess NaHCO3 gave V, m. 181-2° (from EtOH). X.HCl was treated in H2O with NaHCO3, the mixture concentrated in vacuo and extracted with Et2O, the extract evaporated, 3.1 g. of the residual free base heated 18 hrs. with 50 cc. MeOH and 50 cc. liquid NH3 in a sealed tube, the mixture evaporated in vacuo to dryness, MeOH added and removed twice by distillation, and the residue extracted with Et2O to leave 1.86 g. (60%) 5-deoxypyridoxamine (XI); m. 160-1° (from MeOH); 2,5-dimethyl-3-p-toluenesulfonoxy-4-p-toluenesulfonylaminopyridine-HCl, m. 194-5° (from EtOH). A small sample of XI was heated 20 min. with Ac2O on a steam bath, the solution concentrated to dryness, the residue treated with EtOH, distilled to dryness, dissolved in HCl, treated with Darco, neutralized with NaHCO3, chilled, and the crystalline deposit recrystallized from C6H6 containing a few drops EtOH to give 2,5-dimethyl-3-acetoxy-4-acetylaminomethylpyridine, m. 174-5°. V.HCl (5.7 g.) was stirred 2 hrs. at 60-70° with 2.8 g. MnO2, 1.5 cc. H2SO4, and 75 cc. H2O, the mixture filtered, the filtrate concentrated in vacuo, the sirup taken up in 15 cc. H2O, excess solid AcONa added, and the thick, crystalline precipitate cooled, filtered off, and washed with ice water to give 1.30 g. (29%) VII, m. 108-9° (from petr. ether); the aqueous filtrate from VII gave with 2 g. NH2OH.HCl 0.9 g. (18%) oxime of VII, m. 239-40° (decomposition) (from EtOH). To the aqueous filtrate of a similar run were added 12 g. NaOAc and 4.5 g. NH2OH.HCl and the mixture was heated 10 min. on a steam bath to yield 2.43 g. (49%) oxime of VII. VII in CHCl3 treated with excess alc. HCl, the solution evaporated in vacuo to dryness, a little H2O added and removed in vacuo, and the residue treated with CHCl3 yielded VII.HCl, m. 191-3° (decomposition). VII (90 mg.) in 1 cc. H2O was cooled in ice, the pH adjusted to 11 with 6N NaOH, 4 drops 30% H2O2 added, the mixture adjusted to pH 3 with HCl and cooled, and the precipitate washed with H2O, EtOH, and Et2O to yield 70 mg. (85%) 2,5-dimethyl-3,4-dihydroxypyridine, decomposed 262-70°. Crude Ca codecarboxylase (0.5 g.) was suspended in H2O and treated with 0.7 cc. 6N HCl, the mixture filtered, the filtrate diluted to 50 cc. shaken 2.25 hrs. at atm. pressure with H and 0.5 g. 10% Pd-C, filtered and concentrated to dryness in vacuo, the residue dissolved in about 3 cc. H2O, the solution treated with excess solid NaHCO3, filtered, the filter residue washed with H2O, the combined filtrate and washings were concentrated in vacuo to 5 cc., the concentrate extracted 21 hrs. continuously with CHCl3, the extract evaporated, and the residue treated with alc. HCl and precipitated with Et2O to give 0.07 g. V.HCl, m. 140-1°. III.HCl (0.35 g.) was treated with 0.10 g. CaO and 0.17 g. H3PO4 and hydrogenated similarly to give 0.08 g. (24%) VI.HCl, m. 264-5°, and 0.11 g. (33%) V.HCl; the aqueous filtrate left from the CHCl3-extraction was concentrated to dryness, the residue extracted with EtOH, and the extract acidified with alc. HCl to give 0.11 g. (30%) I.HCl. Similar hydrogenation of 0.40 g. I.HCl in 0.3 cc. 6N HCl and 50 cc. H2O for 4-5 hrs. gave 0.16 g. (42%) VI.HCl and 0.09 g. (24%) V.HCl. Attempted similar hydrogenation of V gave only recovered starting material.

In some applications, this compound(148-51-6)SDS of cas: 148-51-6 is unique.If you want to know more details about this compound, you can contact with the author or consult more relevant literature.

Reference:
Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

The preparation of ester heterocycles mostly uses heteroatoms as nucleophilic sites, which are achieved by intramolecular substitution or addition reactions. Compound: 5-Methylfuran-2(3H)-one( cas:591-12-8 ) is researched.Name: 5-Methylfuran-2(3H)-one.Wei, Yunlong; Zhang, Hong; Wu, Xinxin; Zhu, Chen published the article 《Alkene Difunctionalization Triggered by a Stabilized Allenyl Radical: Concomitant Installation of Two Unsaturated C-C Bonds》 about this compound( cas:591-12-8 ) in Angewandte Chemie, International Edition. Keywords: radical alkynylalkenylation enynylalkenylation alkenes dual function sulfone reagent; alkene difunctionalization; alkyne; allenyl radical; radical reactions; rearrangement. Let’s learn more about this compound (cas:591-12-8).

Radical-mediated difunctionalization of alkenes provides a promising approach to introduce one alkenyl or alkynyl group to target compounds However, simultaneous installation of two unsaturated C-C bonds via alkene difunctionalization remains elusive, attributable to the high instability and transient lifetimes of alkenyl and alkynyl radicals. Herein, we report the photocatalytic 1,2-alkynylalkenylation and 1,2-enynylalkenylation of alkenes for the first time, triggered by the intermol. addition of a stabilized allenyl radical to an alkene. A portfolio of strategically designed, easily accessible dual-function reagents are applied to a radical docking-migration cascade. The protocol has broad substrate scope and efficiently increases the degree of unsaturation

In some applications, this compound(591-12-8)Name: 5-Methylfuran-2(3H)-one is unique.If you want to know more details about this compound, you can contact with the author or consult more relevant literature.

Reference:
Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Aminoalkylphenols as antimalarials. II. (Heterocyclic amino)-α-amino-ο-cresols. The synthesis of camoquin》. Authors are Burckhalter, J. H.; Tendick, F. H.; Jones, Eldon M.; Jones, Patricia A.; Holcomb, W. F.; Rawlins, A. L..The article about the compound:4-Chloro-8-methylquinolinecas:18436-73-2,SMILESS:CC1=C2N=CC=C(Cl)C2=CC=C1).Recommanded Product: 4-Chloro-8-methylquinoline. Through the article, more information about this compound (cas:18436-73-2) is conveyed.

In view of the high antimalarial activity of certain substituted α-amino-ο-cresols, earlier work (C.A. 41, 414d) has been extended to analogs containing heterocyclic nuclei. This reports the preparation of a group of 122 (heterocyclic amino)-α-amino-ο-cresols and a related group of 12 (heterocyclic amino)benzylamines, as well as the new intermediates used therein. This work has resulted in the preparation of a promising antimalarial (SN 10,751) named camoquin, as well as other compounds which are the most active 4-aminoquinoline derivatives heretofore reported in trophozoite-induced Plasmodium gallinaceum infection in the chick. Catalytic reduction of the appropriate nitrophenol in the presence of Ac2O gave these 4-acetamidophenols: 2-Cl, m. 144°, 55% yield; 2-Ph, m. 160°, 60%; and 2-acetamidophenols: 4-Cl, m. 186°, 52%; 4-Ph, m. 165°, 89%; and 4-tert-Bu, m. 170°, 79%. 2-Allyl-4-acetamidophenol, m. 93-4°, was obtained in 83% yield from the rearrangement of 4-CH2:CHCH2OC6H4NHAc. The Mannich reaction on the substituted acetamidophenols gave these 4-acetamido-α-substituted-ο-cresols: diethylamino (I), m. 135°, 82%; dibutylamino, m. 73°, 87% (picrate, m. 183-5°); dibenzylamino, m. 230°, 75%; (2-methyl-1-piperidyl) (HCl.H2O, m. 175°, 65%); 4-morpholinyl, m. 133°, 27%; [methyl(2-hydroxyethyl)amino] (HCl, m. 198°, 50%); (2-butylamino), m. 156°, 37%; (2-hydroxyethylamino) (HCl, m. 230°, 31%); the 6-allyl derivative of I, m. 86°, 58%: the 5-acetamido isomer of I (HCl, m. 210°, 33%); and these 6-acetamido-α-diethylamino-4-substituted-ο-cresols: Cl (HCl, m. 212°, 66%); tert-Bu (HCl, m. 158°, 53%); and Ph (HCl, m. 183°). Acid hydrolysis of the appropriate 4-acetamido compound gave these 4-amino-α-substituted-ο-cresols (di-HCl salts) (all m. with decomposition); diethylamino, SN 12,458, m. 218-20°, 96%; 1-piperidyl, m. 153-5°, 91%; and 4-morpholinyl, m. 259-60°, 45%. The Mannich reaction on 4-nitrophenol (A) and the reaction of the amine on 2-(chloromethyl)-4-nitrophenol (B) were used to prepare these α-substituted-4-nitro-ο-cresol HCl salts (all m. with decomposition): diethylamino, A, m. 224°, 40%; diisopropylamino, B, m. 193°, 19%; dibutylamino, B, m. 176°, 75%; diisobutylamino (free base), B, m. 113°, 43%; diisoamylamino, B, m. 132°, 32%; isopropylamino, B, m. 238°, 38%; isobutylamino, B, m. 247°, 29%; tertbutylamino, B, m. 275°, 20%; 1-piperidyl, A, m. 260°, 68%; and α-diethylamino-4-nitro-6-phenyl-ο-cresol, A, m. 125°, 21%; and 4-tert-butyl-α-diethylamino-6-nitro-ο-cresol, A, m. 103°, 50%. The method of Price and Roberts (C.A. 40, 5739.5) was used to prepare these substituted 4-chloroquinolines: 6-Me, m. 55°, 50%; 6-anilino, m. 148°, 6%; 7-EtO, m. 76°, 53%; 7-hexyloxy, a high-boiling liquid, 41%; 8-Me, m. 99°, 71%; 5,7-di-Me, m. 59°, 51%; 5,8-di-Me, m. 51°, 59%; 5-chloro-8-methoxy, m. 127°, 6%; 5-methyl-8-methoxy, m. 78°, 45%; 6,8-di-Me, m. 90°, 82%; and 6,7,8-trichloro, m. 156°, 39%. The (heterocyclic amino)-α-alkylamino-ο-cresols were prepared by minor variations of the general procedure of heating the chloroheterocycle with the amino-α-alkylamino-ο-cresols in aqueous or alc. solution on the steam bath. The latter were obtained either by acid hydrolysis of the acetamido derivatives or by catalytic reduction of the nitro derivatives and were usually condensed without isolation. The products are isolated either as the free bases or HCl salts. All the quinine equivalents (Q) reported here are based on the B4 test using P. gallinaceum in the chick. Nearly all the HCl salts m. with decomposition and are colored yellow to orange. 4-(4-Quinolylamino)-α-diethylamino-ο-cresol (II) di-HCl, SN 12,452, m. above 300°, was obtained in 48% yield and had a quinine equivalent of 3 (designated hereafter in the form Q 3). Analogs of II, substituted on the quinoline nucleus: 2-Cl (2HCl, SN 11,986, m. 248°, 30%, Q <0.07); 3-Ph, SN 11,631, m. 155°, 31%, Q 0.4; 6-MeO (2HCl, SN 10,274, m. 270°, 75%, Q 8); 6-Cl (HCl.0.5H2O, SN 11,597, m. 220°, 60%, Q 3.0); 6-Me, SN 11,559, m. 172° (2HCl, m. 238°, 56%, Q 4); 6-anilino (2HCl.H2O, SN 12,361, m. 196°, 63%, Q 0.2); 6-dimethylamino (3HCl.0.5H2O, SN 11,984, m. 235°, 73%, Q 2.5); 6-nitro (2HCl.1.5H2O, m. 210°, 63%, Q 0.8); 7-MeO (2HCl.0.5H2O, SN 11,554, m. 210°, 43%, Q 7); 7-EtO (2HCl.2H2O, SN 11,281, m. 136°, 44%, Q 7); (7-hexyloxy, SN 11,634, m. 153°, 35%, Q 0.5; Q 7); 7-Me (2HCl, SN 12,699, m. 245°, 93%, Q 9); 7-Cl (camoquin) SN 10,751, m. 208°, 86%, Q 25 (2HCl.0.5H2O, m. 243°); 2HCl.H2O, m. 183°; (2HCl.2H2O, m. 160°, 90%); 8-Cl, SN 11,551, m. 212° (2HCl.0.5H2O, m. 253°, 79%, Q 0.5); 8-MeO (2HCl.1.5H2O, SN 11,594, m. 241°, 50%, Q 0.8); 8-Me (2HCl.H2O, SN 11,601, m. 253°, 66%, Q 0.7); 5-chloro-3-Me (2HCl, SN 11,985, m. 258°, 48%, Q 0.3); 5,7-di-Cl (2HCl, SN 12,700, m. 200°, 65%, Q 3); 5,7-di-Me (2HCl, SN 11,561, m. 242°, 67%, Q 10); 5,8-di-Cl (2HCl.H2O, SN 11,596, m. 235°, 60%, Q 0.25); 5,8-di-Me (2HCl, SN 11,560, m. 249°, 80%, Q 0.6); 5-chloro-8-methoxy [2HCl, SN 12,162,(incorrectly given as 12,161 in original), m. 231°, 80%, Q 0.4]; 6-methoxy-2-Me (2HCl, SN 9223, m. 278°, 45%, Q 1.2); 6-methoxy-2-Ph (2HCl.1.75H2O, SN 11,592, m. 198°, 61%, Q 0.25); 6,7-di-Cl (2HCl, SN 12,161, m. 257°, 71.5%, Q 5); 6,7-di-MeO (2HCl, SN 13,395, m. 258°, 68%, Q 2.5); 6,7-di-Me, SN 11,990, m. 215°, 49%, Q 6; 6,8-di-Me (2HCl.H2O, SN 11,558, m. 264°, 54%, Q 0.6); 7-chloro-2-Ph (2HCl, SN 11,232, m. 260°, 41%, Q 0.3); 7-chloro-3-Ph, SN 12,228, m. 165°, Q 1; 7-chloro-3-Me (2HCl, SN 10,492, m. 260°, 64%, Q 6); 8-methoxy-5-Me (2HCl, SN 11,632, m. 210°, 90%, Q 0.6); 6,7,8-tri-Cl (2HCl, SN 11,633, m. 277°, 40%, Q <0.3); and 6-HO (2HCl, SN 11,563, m. 262°, 64%, Q 0.2) (prepared by HBr demethylation of the 6-MeO derivative). 4-(6-Methoxy-4-quinolylamino)-α-dibutylamino-ο-cresol (III) (2HCl.1.25H2O, m. 193°, 10%, Q 9); the (7-chloro-3-methyl-4-quinolylamino) analog of III (2HCl.1.5H2O, m. 177°, 43%, Q 10). 4-(6-Methoxy-4-quinolylamino)-α-1-piperidyl-ο-cresol (IV) (2HCl.0.5H2O, SN 12,038, m. 270°, 80%, Q 8); analogs of IV: (6,7-dimethoxy-4-quinolylamino) (2HCl, SN 13,413, m. 230°, 40%, Q 4); (7-chloro-3-methyl-4-quinolylamino) (2HCl, SN 12,360, m. 270°, 47%, Q 2); (6-methyl-4-quinolylamino) (2HCl, SN 12,456, m. 240°, 41%, Q 2.5). 4-(6-Methoxy-4-quinolylamino)-α-4-morpholinyl-ο-cresol (V) (2HCl, SN 11,989, m. 265°, 57%, Q 1); analogs of V: (7-chloro-3-methyl-4-quinolylamino) (2HCl, SN 12,362, m. 242°, 33%, Q 0.15); (6-methyl-4-quinolylamino), SN 12,457, m. 239°, 50%, Q 0.8. 5-(7-Chloro-4-quinolylamino)-α-diethylamino-ο-cresol, SN 13,730, m. 173°, Q 9; 6-(7-chloro-4-quinolylamino)-α-diethylamino-4-(diethylaminomethyl)-ο-cresol-1.5H2O, m. 145°, Q 5; 4-chloro-α-diethylamino-6-(6-methoxy-4-quinolylamino)-ο-cresol (2HCl, SN 12,885, m 205°, 50%, Q 0.5). 6-Chloro-4-(7-chloro-4-quinolylamino)-α-diethylamino-ο-cresol (VI), SN 13,729, m. 225°, Q 12; analogs of VI: 6-Ph (0.5H2O, m. 235°, 25%); 6-allyl, SN 11,991, m. 148°, 44%, Q 10; 6-allyl-α-1-piperidyl, SN 12,697, m. 190°, 32%, Q 4; 6-allyl-α-diallylamino, SN 13,394, m. 131°, 25%, Q 0.7. 6-Allyl-α-diethylamino-4-(6-methoxy-4-quinolylamino)-ο-cresol, SN 12,039, m. 161°, 33%, Q 7. Variations of the alkylamino group on the cresol portion of camoquin were studied: α-amino-4-(7-chloro-4-quinolylamino)-ο-cresol (VII) (2HCl.0.5H2O, SN 1603, m. 325°, 80%, Q 6); analogs of VII (substituents on the α-amino group): benzoyl (HCl, SN. 11,557, m. 289°, 80%, Q 0.15); Et (2HCl, m. 280°, Q 40, 4% conversion, prepared by the Mannich reaction of EtNH2, (HCHO)x, and 7-chloro-4-(4-hydroxyanilino)quinoline (HCl, m. above 320°, 94%)); Pr(2HCl.0.5H2O, m. 244°, 24%, Q 30); iso-Pr (2HCl, m. 287° 50%, Q 40); Bu (2HCl, m. 254°, 6%, Q 30); sec-Bu (2HCl.H2O, m. 252°, 3%, Q 50); iso-Bu (2HCl, m. 256°, 65%, Q 75); tert-Bu (2HCl, m. 285°, 36%, Q 40); Am (2HCl, m. 266°, 15%, Q 50); (1-methylbutyl 2HCl, m. 231°, 22%, Q 40); iso-Am (2HCl, m. 279°, 20%, Q 50); hexyl (2HCl, m. 280°, 56%, Q 25); (2-ethylbutyl (2HCl, m. 263°, 15%, Q 50)); heptyl (2HCl, m. 278°, 29%, Q 15); octyl, m. 150°, 15%, Q 2.5; allyl (2HCl, m. 257°, 3%, Q 20); 1-methylallyl (2HCl.1.75H2O, m. 95°); cyclohexyl (2HCl.0.25H2O, m. 252°, 30%, Q 30); 2-hydroxyethyl (2HCl.H2O, m. 182°, 15%, Q 3); 2-methoxyethyl (2HCl, m. 271°, Q 25); benzyl (2HCl, m. 270°, Q 16); (α-methylphenethyl) (2HCl.0.25H2O, m. 243°, 31%, Q 25); di-Me (2HCl, m. 290°, 85%, Q 6); N-ethyl-N-butyl(2HCl, m. 240°, 65%, Q 30); di-Pr, SN 13,835, m. 181°, 11%, Q 25; di-Bu, SN 14,105, m. 164°, 20%, Q 35; diiso-Bu (0.5H2O, m. 166°, 38%); diiso-Am (0.5H2O, m. 135°); dihexyl (2HCl, m. 220°, 40%, Q 0.5); diheptyl (2HCl, m. 203°, 52%, Q 1); dioctyl (2HCl, m. 192°, 46%, Q 0.2); bis(2-ethylhexyl) (2HCl.H2O, m. 154°, 1%, Q 3); methyl(2-hydroxyethyl) (2HCl, SN 12,363, m. 250°, 63%, Q 3); butyl(2-hydroxyethyl), SN 14,824, m. 149°, 22%, Q 12; bis(2-hydroxyethyl), m. 193°, 25%, Q 0.6; dibenzyl (2HCl, m. 235°, 74%, Q 2.5); N-methyl-N-Ph (H2O, m. 140°, 39%, Q 0.07); N-ethyl-N-Ph, m. 131°, 54%, Q <0.05. Further analogs of VII: α-1-piperidyl (2HCl.2.5H2O, SN 11,636, m. 302°, 77.5%, Q 25); α-(2-methyl-1-piperidyl) (2HCl, SN 12,357, m. 288°, 66%, Q 20); α-4-morpholinyl (2HCl, SN 11,987, m. 292°, 60-5%, Q 4). Compounds containing heterocyclic nuclei other than the 4-quinolyl include the following 4-(heterocyclic amino)-α-diethylamino-ο-cresols: 9-acridyl (2HCl, SN 12,356, m. 265°, 45%, Q 1.5); (3-chloro-9-acridyl) (2HCl, SN 12,355, m. 267°, 52%, Q 3); (4-methoxy-9-acridyl) (2HCl, SN 12,164, m. 245°, 50%, Q 0.15); (3-chloro-5-methyl-9-acridyl) (2HCl, SN 11,988, m. 275°, 40%, Q 0.25); 2-quinolyl (2HCl, SN 9559, m. 230°, 48%, Q 0.12); (6-methoxy-2-quinolyl) (2HCl, SN 11,537, m. 237°, 20.5%, Q 0.7); (5-nitro-2-quinolyl) (2HCl, SN 9307, m. 245°, 33%, Q <0.07); (2-amino-4-pyrimidyl) (2HCl, SN 9591, m. 258°, 41%, Q 1.1); [2-(1-piperidyl)-4-pyrimidyl], SN 10,177, m. 156°, 31%, Q 0.4; (2-amino-6-methyl-4-pyrimidyl) (2HCl, m. 245°, 55%); (4-methoxy-2-benzothiazolyl) (2HCl, SN 11,189, m. 163°, 47%, Q <0.07); (6-chloro-2-methoxy-9-acridyl) (VIII), SN 8617, m. 175°, 50% (H2O, m. 117°; 2HCl, m. 280°, 76%, Q 4; 2HCl.2H2O, m. 180°); analogs of VIII: α-(ethylbutylamino) (2HCl, m. 252°, 36%, Q 5); α-dibutylamino (2HCl, SN 11,599, m. 246°, 69%, Q 2.5); α-diallylamino, SN 13,163, m. 158°, 16%, Q 0.5; α-dihexylamino (2HCl, m. 254°, 23%, Q 0.4); α-dioctylamino (2HCl, m. 285°, 20%, Q <0.06); α-1-piperidylamino (2HCl, SN 11,536, m. 287°, Q 0.6); α-hexylamino (2HCl.H2O, m. 226°, 7%, Q 1); α-(2-hydroxyethylamino) (2HCl.H2O, SN 11,233, m. 284°, 90%, Q 0.2); α-benzamido (HCl.0.5H2O, SN 11,589, m. 294°, 95%, Q <0.04). 5-(6-Chloro-2-methoxy-9-acridylamino)-α-diethylamino-ο-cresol (2HCl.0.5H2O, SN 9614, m. 237°, 50%, Q 1); 4-tert-butyl-6-(6-chloro-2-methoxy-9-acridylamino)-α-diethylamino-ο-cresol (IX) (2HCl, SN 11,544, m. 271°, 98%, Q 0.6); 4-Ph analog of IX (2HCl, SN 11,553, m. 274°, 84%, Q 0.5); 4-diethylaminomethyl analog of IX (3HCl.H2O, SN 11,550, m. 257°, 73%, Q 2); 6-allyl-4-(6-chloro-2-methoxy-9-acridylamino)-α-diethylaminο-ο-cresol (X) (2HCl, SN 11,234, m. 233°, 65%, Q 3); α-diallylamino analog of X (2HCl.H2O, SN 13,399, m. 188°, 12%, Q 0.3); and α-1-piperidyl analog of X, SN 12,701, m. 164°, 44%, Q 2. A series of nitrobenzylamines was prepared by condensation of the nitrobenzyl chloride with the amine in absolute EtOH. During the course of this work, 2-(chloromethyl)-4-nitrophenetole,m. 72-5°, was obtained in 75% yield from the chloromethylation of 4-nitrophenetole. The nitrobenzylamines were reduced catalytically in absolute EtOH and the resulting aminobenzylamines without isolation were condensed with the chloroheterocycle. Thus were obtained: N,N-diethyl-3-nitrobenzylamine, b6 145-8°, 60%; 4-nitro isomer (XI) (HCl, m. 162°, 45%); analogs of XI: N,N-di-Pr (HCl, m. 138°, 68%); N-monoisopropyl (HCl, m. 232°, 82%); N-monoisobutyl (HCl, m. 214°, 64%). N,N-Diethyl-5-nitro-2-methoxybenzylamine (XII) (HCl, m. 178°, 72%); analogs of XII: N-monoisobutyl (HCl, m. 176°, 63%); N-monoamyl (HCl salt could not be separated from an impurity of AmNH2.HCl). N,N-Diethyl-5-nitro-2-ethoxybenzylamine (HCl, m. 182°, 56%). 3-(7-Chloro-4-quinolylamino)-N,N-diethylbenzylamine (2HCl.2H2O, SN 11,590, m. 128° (all these HCl salts m. with decomposition), 85%, Q 1); 4-(7-chloro-4-quinolylamino)-N,N-diethylbenzylamine (XIII) (2HCl, SN 12,455, m. 261°, Q 4); N,N-di-Pr analog of XIII (2HCl, m. 255°, 60%, Q 4); the N-monoisopropyl analog of XIII (2HCl salt, m. 303°, 23%, Q 10); N-monoisobutyl analog of XIII (2HCl.H2O, m. 288°, 76%); 5-(7-chloro-4-quinolylamino)-N,N-diethyl-2-methoxybenzylamine (XIV), m. 203°, 64%, Q 25; N-monoisobutyl analog of XIV (2HCl.0.25H2O, m. 194°, 76%, Q 17); N-monoamyl analog of XIV (2HCl, m. 288°, 42%, Q 15); 2-ethoxy analog of XIV (2HCl.2H2O, m. 247°, 73%, Q 8); 3-(6-chloro-2-methoxy-9-acridylamino)-N,N-diethylbenzylamine (XV) (2HCl.0.75H2O, SN 10,984, m. 278°, 55%, Q 0.5); the 4-substituted benzyl isomer of XV (2HCl.0.5H2O, SN 10,028, m. 260°, 92%, Q 0.4); and 5-(6-chloro-2-methoxy-9-acridylamino)-2-methoxy-N,N-diethylbenzylamine (2HCl.0.5H2O, m. 212°, 67%, Q 3). 6-Chloro-9-(4-hydroxyanilino)-2-methoxyacridine, m. 266° (decomposition) (HCl, orange, m. above 300°, prepared in 98% yield from p-NH2C6H4OH and 6,9-dichloro-2-methoxyacridine on the steam bath), failed to undergo the usual Mannich reaction. Failure of this reaction led to the development of the method of synthesis used for all of the heterocyclic derivatives reported in this paper. In some applications, this compound(18436-73-2)Recommanded Product: 4-Chloro-8-methylquinoline is unique.If you want to know more details about this compound, you can contact with the author or consult more relevant literature.

Reference:
Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

Electric Literature of C5H11NO. The mechanism of aromatic electrophilic substitution of aromatic heterocycles is consistent with that of benzene. Compound: (S)-3-Methoxypyrrolidine, is researched, Molecular C5H11NO, CAS is 120099-61-8, about Novel 7-formyl-naphthyridyl-ureas derivatives as potential selective FGFR4 inhibitors: Design, synthesis, and biological activity studies. Author is Sun, Chang’an; Fang, Lei; Zhang, Xiaobing; Gao, Peng; Gou, Shaohua.

Total twenty-five 7-formyl-naphthyridyl-urea derivatives were designed, synthesized and evaluated for their inhibition of FGFR4 kinase and antitumor activity. The pharmacol. data indicated that most of the tested compounds showed high selectivity towards FGFR4 kinase and could significantly inhibit FGFR4 and the tumor cells lines with the high expression of FGFR4. In particular, compounds 6f, 6g, 6h, 6l, 6m and 6s showed a good performance in pharmacokinetic tests. When tested in mice, the representative compound 6f was found to have good pharmacokinetic parameters, low toxicity, and better tumor inhibiting activity in vivo.

In some applications, this compound(120099-61-8)Electric Literature of C5H11NO is unique.If you want to know more details about this compound, you can contact with the author or consult more relevant literature.

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Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

Reference of 4-Chloro-8-methylquinoline. 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: 4-Chloro-8-methylquinoline, is researched, Molecular C10H8ClN, CAS is 18436-73-2, about Hypoxia-selective antitumor agents. 6. 4-(Alkylamino)nitroquinolines: a new class of hypoxia-selective cytotoxins.

A series of isomeric 4-[[3-(dimethylamino)propyl]amino]nitroquinolines, e.g., I [Rn = H, 3-, 5-, 6-, 7-, 8-NO2, 2,5-Me(O2N), 3,5-Me(O2N), 6,5-Me(O2N), 8,5-Me(O2N), 7,8-Me(O2N), 7,6-Me(O2N), 2,3-Me(O2N)], has been synthesized and evaluated as hypoxia-selective cytotoxins and as radiosensitizers of hypoxic cells. The compounds showed widely-differing hypersensitivity factors (ratios of cytotoxicity against wild-type and repair-deficient mammalian cells). Many compounds showed oxygen-sensitive bioreduction resulting in DNA alkylation, while others show oxygen-insensitive modes of action. Of the nitro isomers studied, the 5-nitro showed the greatest hypoxic selectivity. A series of ring-substituted analogs were then prepared, in an effort to lower its reduction potential of -286 mV. Structure-activity studies showed that the effects of substitution on reduction potential were complex, being mediated by electronic and steric effects on the nitro group, as well as by effects on quinoline pKa. Two compounds of lower reduction potential, the 3- and 8-Me analogs, showed improved selectivity (47- and 60-fold in a clonogenic assay). These two compounds also showed the highest in vitro therapeutic indexes of the series as hypoxic cell radiosensitizers. Despite these favorable in vitro properties, neither compound had activity against hypoxic cells in SCCVII tumors when administered at 60% of the maximum tolerated dose.

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Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

The preparation of ester heterocycles mostly uses heteroatoms as nucleophilic sites, which are achieved by intramolecular substitution or addition reactions. Compound: 5-Methylfuran-2(3H)-one( cas:591-12-8 ) is researched.Recommanded Product: 591-12-8.Mafokoane, M.; Seguel, J.; Garcia, R.; Diaz de Leon, J. N.; Sepulveda, C.; Escalona, N. published the article 《Conversion of levulinic acid using CuO/WO3(x)-Al2O3 catalysts》 about this compound( cas:591-12-8 ) in Catalysis Today. Keywords: tungsten oxide alumina supported copper monoxide catalyst; levulinic acid conversion. Let’s learn more about this compound (cas:591-12-8).

The CuO/WO3(x)-Al2O3 catalysts were tested for the conversion of levulinic acid into chems. of high added-value compounds The WO3(x)-Al2O3 modified supports with 5 different WO3 contents (2, 4, 6, 8, and 10 wt%) were prepared by the wet impregnation method, consequently 5 wt% CuO was impregnated on the modified supports. The optimum catalytic activity was obtained with CuO/WO3(6%)-Al2O3 catalyst, which was directly related to the highest acidity of the catalyst showed by NH3-TPD and acid strength by titration anal. The distribution of products observed on CuO/WO3(x)-Al2O3, was correlated with a change in acid site type and acid strength. The changes in the acidity by the addition of CuO over modified support was attributed to structural changes (distortions) stabilizing the active phase. This distortion is increasing the acidity strength, and favoring a higher catalytic activity with changes in the selectivity in function of CuO content over WO3(x)-Al2O3 modified support, obtaining the maximum formation of 2-MTHF and possibly other higher value-added chems. from GVL such as: 1,4-pentanediol, pentenoic acid, pentanoic acid, 2-pentanol, and gaseous products were on CuO/WO3(6%)-Al2O3 catalyst.

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Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Effect of pyridoxal phosphate on toxicity and antitumor activity of mitomycin C and 4-deoxypyridoxine hydrochloride in rats. Preliminary observations》. Authors are Fujimoto, Shigeru.The article about the compound:5-(hydroxymethyl)-2,4-dimethylpyridin-3-ol hydrochloridecas:148-51-6,SMILESS:OC1=C(C)C(CO)=CN=C1C.[H]Cl).Name: 5-(hydroxymethyl)-2,4-dimethylpyridin-3-ol hydrochloride. Through the article, more information about this compound (cas:148-51-6) is conveyed.

In rats bearing ascites hepatoma, combined therapy with mitomycin C and vitamin B6 arrested leukopenia, but failed to alleviate liver dysfunction and anemia. The growth of subcutaneous tumors was not stimulated by vitamin B6. Tumor growth was inhibited for 2 weeks after administration of 4-deoxypyridoxine-HCl, an antagonist of vitamin B6, to rats fed a diet free of vitamin B6. The administration of vitamin B6 did not lessen the effect of mitomycin C on subcutaneous tumors in rats. Vitamin B6 might counteract leukopenia, a side effect of antitumor agents, by an improvement in metabolism of proteins.

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Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

The three-dimensional configuration of the ester heterocycle is basically the same as that of the carbocycle. Compound: 5-Methylfuran-2(3H)-one(SMILESS: O=C1OC(C)=CC1,cas:591-12-8) is researched.Quality Control of Mesitylcopper(I). The article 《Rapid microwave-assisted polyol synthesis of TiO2-supported ruthenium catalysts for levulinic acid hydrogenation》 in relation to this compound, is published in Catalysts. Let’s take a look at the latest research on this compound (cas:591-12-8).

One wt% Ru/TiO2 catalysts prepared by a one-pot microwave-assisted polyol method have been shown to be highly active for Levulinic acid hydrogenation to γ-Valerolactone. Preparation temperature, microwave irradiation time and choice of Ru precursor were found to have a significant effect on catalyst activity. In the case of Ru(acac)3-derived catalysts, increasing temperature and longer irradiation times increased catalyst activity to a maximum LA conversion of 69%. Conversely, for catalysts prepared using RuCl3, shorter preparation times and lower temperatures yielded more active catalysts, with a maximum LA conversion of 67%. Catalysts prepared using either precursor were found to contain highly dispersed nanoparticles <3 nm in diameter XPS anal. of the most and least active catalysts shows that the catalyst surface is covered in a layer of insoluble carbon with surface concentrations exceeding 40% in some cases. This can be attributed to the formation of large condensation oligomers from the reaction between the solvent, ethylene glycol and its oxidation products, as evidenced by the presence of C-O and C = O functionality on the catalyst surface. In some applications, this compound(591-12-8)Category: pyrimidines is unique.If you want to know more details about this compound, you can contact with the author or consult more relevant literature.

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Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Biological radiation protection. LIX. The meaning of radiation-caused changes in the content of metabolites to the survival rate of mice》. Authors are Melching, Hans Joachim; Abe, Mitsuyuki; Streffer, Christian.The article about the compound:5-(hydroxymethyl)-2,4-dimethylpyridin-3-ol hydrochloridecas:148-51-6,SMILESS:OC1=C(C)C(CO)=CN=C1C.[H]Cl).Category: pyrimidines. Through the article, more information about this compound (cas:148-51-6) is conveyed.

After radiation, changes occur in albumin metabolism, especially in the case of tryptophan and cysteine. The changes reflect a curbing of the activity of amino acid decarboxylase with pyridoxal 5-phosphate as coenzyme. The following compounds increased the mortality rate when given with an x-ray dose of 505 r. (L.D.16/30): 4-deoxypyridoxine-HCl, isonicotinic acid hydrazide,DL-tryptophan, DL-kynurenine, and L-kynurenine. Taurine, given with 590 r. (L.D.64/30), increased the survival rate.

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Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia

The chemical properties of alicyclic heterocycles are similar to those of the corresponding chain compounds. Compound: 5-(hydroxymethyl)-2,4-dimethylpyridin-3-ol hydrochloride, is researched, Molecular C8H12ClNO2, CAS is 148-51-6, about Investigation of related impurities in metadoxine by a reversed phase high performance liquid chromatography technique, the main research direction is metadoxine investigation impurity reversed phase high performance liquid chromatog; Metadoxine; bulk drug; liquid chromatography; mass spectroscopy; related substances.Reference of 5-(hydroxymethyl)-2,4-dimethylpyridin-3-ol hydrochloride.

A new reversed-phase high-performance liquid chromatog. (RP-HPLC) method has been developed for the separation and identification of impurities present in metadoxine. Herein, we report that one of the impurities eluted from the metadoxine sample is 4-deoxypyridoxine hydrochloride (4-DPH). In HPLC anal., the retention time (RT) of 4-DPH was observed to be at 13.5 min in both the reference and metadoxine samples and the relative retention time (RRT) was 1.71. The presence of 4-DPH in a metadoxine sample was also confirmed by a chromatogram obtained by spiking the 4-DPH standard into the sample. Furthermore, the elution and mass of impurity 4-DPH in metadoxine was proven by LC-mass spectroscopy studies. This method highlights the presence of another unknown impurity that has so far not been observed in earlier methods of metadoxine evaluation. Hence, the developed method achieved superior resolution between metadoxine and impurities and thereby facilitates the production of a purer metadoxine drug.

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Pyrimidine | C4H4N2 – PubChem,
Pyrimidine – Wikipedia