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Group 14 amides reactions

The preparation of polyacrylamides and postpolymeri2ation reactions on polyacrylamides are usually conducted ia water. Reactions on the amide groups of polyacrylamides are often more compHcated than reactions of simple amides because of neighboring group effects. Reaction rates, for example, can differ considerably. [Pg.140]

Diuretic activity can be retained in the face of replacement of one of the sulfonamide groups by a carboxylic acid or amide. Reaction of the dichlorobenzoic acid, 174, with chlorsulfonic acid gives the sulfonyl chloride, 175 this is then converted to the amide (176). Reaction of that compound with furfuryl ine leads to nucleophilic aromatic displacement of the highly activated chlorine at the 2 position. There is thus obtained the very potent diuretic furosemide (177). ... [Pg.134]

Another topical anesthetic, similar to benzocaine, is lidocaine, which is used to relieve the pain of shingles (herpes zoster) infections. Lidocaine is called an amide anesthetic, because it is not an ester (the alcohol is replaced by an amide, the nitrogen group). Amide anesthetics are metabolized by the liver, and are less prone to cause allergic reactions. If an anesthetic has the letter i in the prefix (lidocaine, prilocaine, bupivacaine), it is an amide anesthetic. [Pg.173]

R= H, alkyl or aryl group Figure 3.13 Amidation reaction scheme.10... [Pg.151]

Each functional group of an amino acid exhibits all of its characteristic chemical reactions. For carboxylic acid groups, these reactions include the formation of esters, amides, and acid anhydrides for amino groups, acylation, amidation, and esterification and for —OH and —SH groups, oxidation and esterification. The most important reaction of amino acids is the formation of a peptide bond (shaded blue). [Pg.18]

Note also the stereochemistry. In some cases, two new stereogenic centers are formed. The hydroxyl group and any C(2) substituent on the enolate can be in a syn or anti relationship. For many aldol addition reactions, the stereochemical outcome of the reaction can be predicted and analyzed on the basis of the detailed mechanism of the reaction. Entry 1 is a mixed ketone-aldehyde aldol addition carried out by kinetic formation of the less-substituted ketone enolate. Entries 2 to 4 are similar reactions but with more highly substituted reactants. Entries 5 and 6 involve boron enolates, which are discussed in Section 2.1.2.2. Entry 7 shows the formation of a boron enolate of an amide reactions of this type are considered in Section 2.1.3. Entries 8 to 10 show titanium, tin, and zirconium enolates and are discussed in Section 2.1.2.3. [Pg.67]

An expeditious route to the cyclic sulfamide HIV-1 protease inhibitors of type 145 and 146 (tetrahydro-l,2,7-thiadiazepine 1,1-dioxide derivatives) from 141 and 142 hinges on palladium-catalysed amidation reactions. These reactions of 144 and 143 were microwave promoted and provided, after removal of the cyclic ketal protecting group, moderate to good yields of (145, 57%) and (146, 66%) for example with R = NHCOCH2-2-naphthyl <06T4671>. [Pg.458]

The family of complexes which contain amide/alkoxide functionalities constitute the largest group. The reaction of lithium anilide with TuONa, cBuOK, and TMEDA in a 2 1 1 2 ratio produced the remarkable trimetallic complex... [Pg.47]

Figure 17.6 The reaction of SANH with amine-containing proteins or other molecules results in amide bond modifications containing terminal hydrazine groups. The reaction of SFB with amine-containing proteins or other molecules results in amide bond modifications containing terminal aldehyde groups. Subsequently, the two modified molecules can be reacted together to create a conjugate via hydrazone bond formation. Figure 17.6 The reaction of SANH with amine-containing proteins or other molecules results in amide bond modifications containing terminal hydrazine groups. The reaction of SFB with amine-containing proteins or other molecules results in amide bond modifications containing terminal aldehyde groups. Subsequently, the two modified molecules can be reacted together to create a conjugate via hydrazone bond formation.
Figure 28.12 Sulfo-SBED first is used to label a bait protein through reaction of the sulfo-NHS ester with available amine groups on the protein, yielding an amide bond linkage. This labeled bait protein then is added to a sample containing proteins that potentially could interact with the bait. After an incubation period, the sample is exposed to UV light to photoactivate the phenyl azide group. This reaction causes any interacting prey proteins to be crosslinked with the bait protein, forming a complex containing a biotin affinity tag. Figure 28.12 Sulfo-SBED first is used to label a bait protein through reaction of the sulfo-NHS ester with available amine groups on the protein, yielding an amide bond linkage. This labeled bait protein then is added to a sample containing proteins that potentially could interact with the bait. After an incubation period, the sample is exposed to UV light to photoactivate the phenyl azide group. This reaction causes any interacting prey proteins to be crosslinked with the bait protein, forming a complex containing a biotin affinity tag.
The palladium(0)-catalyzed cyclization of amide-allenes via a carbopalladation has been developed by several groups. The reaction proceeds through the carbopalladation of the allene moiety with an organopalladium species (R-Pd-X), generated by oxidative addition of R-X to palladium(O), and subsequent reductive elimination of the resultant 7r-allylpalladium intermediate.47,47a 47f... [Pg.718]

Histone acetylation is a reversible amidation reaction involving defined e-amino groups of lysine residues (see Fig. 6) at the N-terminal tails of core histones. The highly dynamic equilibrium between the acetylated and non-acetylated states of lysine is maintained by two enzymatic groups, referred to as histone acetyltransferases (HATs) and histone deacetylases (HDACs). [Pg.252]

N-Alkyl isoindolo[2,l-fc][2,4]benzodiazepines 190 (R = alkyl. Scheme 38, Section 3.1.1.2) are synthesized by an intramolecular N-acyliminium ion-amide reaction (1997TL2985, 1998T1497). Isothiocyanates 23 undergo under basic conditions in DMF ring closure by an intramolecular substitution between N1 of the pyrrole ring and isothiocyanate group to afford benzo[/]pyrrolo[l,2-c] [l,3]diazepine-5-thiones 25 (Scheme 2, Section 2.1.1.1 (2005BMCL3220)). [Pg.38]

Trimethylsilyldiazomethane, as a stable and safe substitute for hazardous diazomethane, is useful both as a reagent for introducing a Cj-unit and as a C-N-N synthon for the preparation of azoles. Many methods are described in the literature for the preparation of trimethylsilyldiazomethane, including the trimethylsilylation of diazomethane (7-74S), the alkaline decomposition of N-nitroso-N-(trimethylsilylmethyl)amides (25-61%) and the diazo group transfer reaction of trimethylsilylmethyllithium with p-toluenesulfonyl azide (38%). The present modified diazo group transfer method appears to be the most practical, high-yield, and large scale procedure for the preparation of... [Pg.131]

In a typical example of the s)mthesis of one of these broad-spectrum agents, the cefamandole intermediate (20-2) is first acylated with the protected thiazole acid chloride (21-5) to give the amide (22-1). Removal of the protecting group by reaction of that intermediate with thiourea can be envisaged as involving an initial displacement of chlorine on the side chain by sulfur to form an intermediate such... [Pg.560]


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Amidating reaction

Amidation reactions

Amide Reaction

Amide groups

Leaving group amide hydrolysis reactions

Reactions of the amide group in acylamino acids and peptides

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