Amido

Potassium and sodium borohydride show greater selectivity in action than lithium aluminium hydride thus ketones or aldehydes may be reduced to alcohols whilst the cyano, nitro, amido and carbalkoxy groups remain unaffected. Furthermore, the reagent may be used in aqueous or aqueous-alcoholic solution. One simple application of its use will be described, viz., the reduction of m-nitrobenzaldehyde to m-nitrobenzyl alcohol ... 

During the course of biochemical studies (138). the mass spectrum of 2-acetamidothiazole was recorded its main peaks are the molecular ion (m/e= 142, relative intensity = 26%) and fragments 100 (100), 58 (2. 5), and 43 (39). For 2-acetamido-5-bromothiazole the main peak results again from the loss of C2H2O by the molecular ion. 2-AcetyIacet-amido-4-methylthiazole (2S) exhibits significant loss of from the... 

Treatment of 2-imino-3-phenyl-4-amino-(5-amido)-4-thiazoline with isocyanates or isothiocyanates yields the expected product (139) resulting from attack of the exocyclic nitrogen on the electrophilic center (276). Since 139 may be acetylated to thiazolo[4,5-d]pyrimidine-7-ones or 7-thiones (140). this reaction provides a route to condensed he erocycles (Scheme 92). 

FROM 2-(p-R-ARYLSULFEN.AMIDO)THIAZOLES TO 2 AMIN0-5-(P-R-ARYLTHI0)THIAZ0LES... 

Similarly, 2-methyl-5-acetamidothiazoles were obtained from the corresponding nitriles, NCCH(R2)NHCOMe, in which Rj = hydrogen, or amido, methylamido, and dimethylamido groups (551, 571) (Table 11-33). 5-Aminothiazole derivatives (209), Rj = Me or Ph and Rj H,... 

Ami dinoaziri dines 2-Amido Amido black Amidochlor... 

The P-halo ketone intermediates formed in the foregoing reactions arise from the capture of carbocationic intermediates by halide of the gegenions. In some cases, solvents such as acetonitrile can act as the competing nucleophilic species. For example, P-amido ketones could be obtained by the acylation of alkenes in acetonitrile (172). 

An exception exists to the monobasic nature of sulfamic acid when it dissolves ia Hquid ammonia. Sodium, potassium, etc. add both to the amido and sulfonic portions of the molecule to give salts, such as NaSO NHNa. 

In sulfamation, also termed A/-sulfonation, compounds of the general stmcture R2NSO2H are formed as well as their corresponding salts, acid hahdes, and esters. The reagents are sulfamic acid (amido—sulfuric acid), SO —pyridine complex, SO —tertiary amine complexes, ahphatic amine—SO. adducts, and chlorine isocyanate—SO complexes (3). 

Garboxylates. Soaps represent most of the commercial carboxylates. The general stmcture of soap is RCOO M", where R is a straight hydrocarbon chain in the C —C2 range and M+ is a metal or ammonium ion. Intermption of the chain by amino or amido linkages leads to other stmctures which account for the small volumes of the remaining commercial carboxylates. 

A Acylsarcosinates. Sodium A/-lautoylsarcosinate [7631-98-3] is a good soap-like surfactant. Table 4 gives trade names and properties. The amido group in the hydrophobe chain lessens the interaction with hardness ions. A/-Acylosarcosinates have been used in dentifrices (qv) where they ate claimed to inactivate enzymes that convert glucose to lactic acid in the mouth (57). They ate prepared from a fatty acid chloride and satcosine ... 

The phosphido complex, Th(PPP)4 [143329-04-0], where PPP = P(CH2CH2P(CH2)2)2) has been prepared and fully characterized (35) and represents the first actinide complex containing exclusively metal—phosphoms bonds. The x-ray stmctural analysis indicated 3-3-electron donor phosphides and 1-1-electron phosphide, suggesting that the complex is formally 22-electron. Similar to the amido system, this phosphido compound is also reactive toward insertion reactions, especially with CO, which undergoes a double insertion (35,36). 

In the search for improved antibacterials not only has the effect produced by the variation of the C-7 amido side chain and the 3 substituent been studied, but so also has the more synthetically challenging question of the effect of changes in the cephem nucleus (194,197,198). Nuclear analogues have been studied since the early 1970s but only the oxacephem class has reached the marketplace. 

Amido black is a commonly used stain, but it is not very sensitive. It is often used to visualize concentrated proteins or components that are readily accessible to dyes such as proteins that have been transferred from a gel to nitrocellulose paper. Two of the more sensitive and more frequently used stains are Coomassie Brilliant Blue (R250 and G250) and silver stains. Because these stains interact differently with a variety of protein molecules, optimization of the fixative and staining solutions is necessary. The Coomassie stains are approximately five times more sensitive than amido black and are appropriate for both agarose and polyacrylamide gels. The silver stain is approximately 100 times more sensitive than Coomassie and is typically used for polyacrylamide gels. 

To quantitate proteins from staining, a densitometer aided by computer software is used to evaluate band areas of samples compared to band areas of a standard curve. Amido black, Coomassie Brilliant Blue, and silver stains are all appHcable for use in quantification of proteins. 

Numerous variations of this reaction have been studied, principally those involving a prior inclusion of the nuclear sulfur atom in a thioacylamino compound. Thus, thiobenz-amido acetaldehyde diethyl acetal (8) underwent ring closure to 2-phenylthiazole (9) on gentle heating (57JCS1556). Similarly, iV-thioacyl a-amino acids also undergo ready ring closure to thiazoles. 

As many natural and synthetic /3-lactams bear 3-acylamino substituents, the corresponding free amines or protected forms thereof are versatile synthetic intermediates. They may be prepared in several ways, for example by deacylation of the 7-amido group in naturally occurring penicillins by enzymic or chemical means. Chemical degradation usually involves conversion of the amide to a chloroimidate followed by cleavage with aqueous alcohols (75S547 p. 560, 78T1731 p. 1753). 

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