N- sulfonamides

Chiral methyltitanium reagents.1 The N-sulfonamides (1) formed from norephedrine have been used as chiral ligands for a methyltitanium reagent. Thus addition of 1 to TiCl4 and CH3Li (1 4) and then to isopropanol provides a reagent... 

Deamination of primary amines. The conversion of primary amines into N-sulfonamides under Schotten-Baumann conditions is the basis for the classical Hinsberg test. Baumgarten et aO have found that N-sulfonamides can be converted into N,N-disulfonimides, usually in high yield, by conversion into the sodium salt (NaH) and subsequent reaction with a sulfonyl chloride in DMF as solvent ... 

PhMe2SiLi cleaves silyl enol ethers to give the lithium eno-late more rapidly than does methyllithium, allowing f-butyldi-methylsilyl enol ethers to be purifed, and then converted into the lithium enolate at low temperature. It reacts with the N-sulfonamides of pyrroles, indoles, and secondary amines, but not primary amines, to remove the sulfonyl group (eq 25), but it opens A -sulfonylaziridines by attack on carbon. It adds to iron-coordinated cyclohexadiene (eq 26) and to chromium-coordinated benzene rings (eq 27). ... 

Corey examined and documented another class of amino-acid-derived N-sulfonamide oxazaborolidines, characterized by their convenient synthesis, for the catalytic asymmetric Mukaiyama aldol reaction. Oxazaborolidine 256, for example, can be assembled from the condensation of L-N-tosyl-tryp-tophan and n-butylboronic acid. It was shown to be an effective catalyst for the Mukaiyama addition of enoxysilanes with a variety of aldehydes (Equation 25) [127]. 

Sulfonamides derived from sulfanilamide (p-arninoben2enesulfonainide) are commonly referred to as sulfa dmgs. Although several dmg classes are characterized by the presence of a sulfonamide function, eg, hypoglycemics, carbonic anhydrase inhibitors, saluretics, and tubular transport inhibitors, the antibacterial sulfonamides have become classified as the sulfa dmgs. Therapeutically active derivatives are usually substituted on the N nitrogen the position is generally unsubstituted. These features are illustrated by the stmctures of sulfanilamide (1) and sulfadiazine (2)... 

Dialkylation of an amine or sulfonamide with a 1,3-dihalide provides a further route to azetidines <79CRV33l, 64HC( 19-2)88 5). Examples of this approach are the formation of N-tosylazetidine from tosylamide and l-bromo-3-chloropropane and the formation of N-alkylazetidinyl esters (36). The latter reaction works well except for R=Me the former provides a useful route to azetidine since the tosyl group can be removed by reductive methods. 

Six categories of 7V-hetero atom derivatives are considered N-M (M = boron, copper), N-N (e.g., N-nitro, A-nitroso), N-oxides (used to protect teriary amines), N-P (e.g., phosphinamides, phosphonamides), N-SiR3 (R = CH3), and N-S (e.g., sulfonamides, sulfenamides). 

Aryl bromides were also perfluoroethylated under these conditions [205] The key to improved yields was the azeotropic removal of water from the sodium perfluoroalkylcarboxylate [205] Partial success was achieved with sodium hepta-fluorobutyrate [204] Related work with halonaphthalene and anthracenes has been reported [206 207] The main limitation of this sodium perfluoroalkylcarboxylate methodology is the need for 2 to 4 equivalents of the salt to achieve reasonable yields A trifluoromethylcopper solution can be prepared by the reaction of bis(tri-fluoromethyl)mercury with copper powder in /V-methylpyrrolidone (NMP) at 140 °C [208] (equation 138) or by the reaction of N-trifluoromethyl-A-nitro-sotnfluoromethane sulfonamide with activated copper in dipolar aprotic solvents [209] This trifluoromethylcopper solution can be used to trifluoromethylate aro matic [209], benzylic [209], and heterocyclic halides [209]... 

Replacement of a benzene ring by its isostere, thiophene, is one of the more venerable practices in medicinal chemistry. Application of this stratagem to the NSAID piroxicam, gives tenoxicam, 136, a drug with substantially the same activity, nie synthesis of this compound starts by a multi-step conversion of hydroxy thiophene carboxylic ester 130, to the sulfonyl chloride 133. Reaction of that with N-methylglycinc ethyl ester, gives the sulfonamide 134. Base-catalyzed Claisen type condensation serves to cyclize that intermediate to the p-keto ester 135 (shown as the enol tautomer). The final product tenoxicam (136) is obtained by heating the ester with 2-aminopyridine [22]. 

Chemical Name 10-[2-(dlmethylamino)propyl] -N,N-dimethylphenothiazine-2-sulfonamide methane sulfonate... 

Methyl-isoxazole-(3)-carboxylic acid chloride 4-(/3-Aminoethyl)benzene sulfonamide hydrochloride Chloroformic acid methyl ester N-Amlno-hexamethylene imine... 

There is obtained from 4-[)3-[5-methyl-isoxazolyl-(3)-carboxamido]-ethyl]-benzene-sulfonamide (prepared from 5-methyl-isoxazole-(3)-carboxylic acid chloride and 4-()3-aminoethyl)-benzene-sulfonamide hydrochloride, MP 213° to 214°C in pyridine) and chloroformic acid methyl ester, in a yield of 69%, the compound N-[ [-4-[)3-[5-methyl-isoxazolyl-(3)-carbox-amido] -ethyl] ] -benzene-sulfonyl] ] -methyl-urethane in the form of colorless crystals of MP 173°C. 

By heating the diacetyl compound with sodium hydroxide solution partial saponification of the acetyl groups takes place. 25.6 grams of diacetyl compound are heated to boiling for some hours with 100 cc of 2 N sodium hydroxide solution. The precipitate produced by acidification of the solution with acetic acid is filtered off and treated with dilute sodium carbonate solution. The 4-aminobenzene-sulfonacetylamide passes into solution while the simultaneously formed 4-acetylaminobenzene-sulfonamide remains undissolved. It is filtered with suction and the filtrate again acidified with acetic acid. The 4-aminobenzene-sulfon-acetamide separates out and is recrystallized from water. It forms colorless lustrous rhombic crystals Of MP 1B1°C. 

Chemical Name N,N-Dimethyl-10-[3-(4-methyl-1-piperazinyl)propyl] -phenothiazine-2-sulfonamide... 

The method illustrates the ability of the sodium hydride-dimethylformamide system to effect the alkylation of aromatic sulfonamides under mild conditions and in good yield. The method appears to be fairly general. The submitters have prepared N,N-diethyl- and N,N-di- -butyl- >-toluenesulfonamide as well as 2-(/ -tolyIsuIfonyl)benz[/]isoindoline from 2,3-bis-(bromomethyl)naphthalene, and 1 %-tolylsulfony])pyrrolidine from 1,4-dichIorobutane the yield of purified product exceeded 75% in each case. 

Two recent reports described addition of nitrogen-centered nucleophiles in usefully protected fonn. Jacobsen reported that N-Boc-protected sulfonamides undergo poorly selective (salen) Co-catalyzed addition to racemic epoxides. However, by performing a one-pot, indirect kinetic resolution with water first (HKR, vide infra, Table 7.1) and then sulfonamide, it was possible to obtain highly enantiomer-ically enriched addition products (Scheme 7.39) [71]. These products were transformed into enantioenriched terminal aziridines in straightforward manner. 

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