Amide cationic

The addition of alkenes to A -methylenium amide cations is stereo-specific in the sense that it obeys the cis principle of Alder and Stein, cis-2-butene giving a cis product (105, R = R = Me) and the trans isomer giving trans product (105, R = R = Me). The cycloaddition of unsymmetrical alkenes is highly regiospecific. Knowing how the alkene will react with a large cation allows prediction of the product (105). Thus styrene, butadiene, and vinyl acetate all react so that its substituent appears at position 6 of the dihydrooxazinium salt (105, R = Ph, vinyl, or OAc). 

Bis(trimethylsilyl)-amide Cation Reaction Solvent Product Yield (%) Methylene Cyclopropane Composition (%) 1-Methyl-cyclopropane Composition (%)... 

For H+ addition, the amide group is a very weak base, and there once was considerable debate over whether the amide oxygen or the amide nitrogen was the most favorable protonation site. However, NMR experiments have decisively established that the oxygen atom serves as the main protonation site over the entire range of acidic solutions. Several groups have estimated the ratio of the O- to N-protonated amide cations to be 10. ... 

Sn(CH3)3l dissolved in nitrobenzene as a function of concentration of various EPD solvents added (35). In noncoordinating or weakly coordinating solvents, such as hexane, earbon tetrachloride, 1,2-dichloroethane, nitrobenzene, or nitromethane, Sn(CH3)3l is present in an unionized state (tetrahedral molecules). Addition of a stronger EPD solvent to this solution provokes ionization, presumably with formation of trigonal bipju amidal cations [Sn(CH3)3 (EPD)2J. Table II reveals that the molar conductivities at a given mole ratio EPD Sn(CH3)3l are (with the exception of pyridine) in accordance with the relative solvent donicities. No relationship appears to exist between conductivities and the dipole moments or the dielectric constants of the solvents. 

In order to explain the termination reaction, leading to the cyclic amidate cation through removal of the water molecule, Bertalan proposed the antiperiplanar participation (structure 188b) ... 

CokoL [ er] Fatty amide cationic cotton and wool softener and lubricant for textile industry finishing agent... 

Two cationic heteroazadiene systems that participate in well-defined [4+ + 2] cydoadditions have been investigated extensively. The N-methyl-A -methylenium amide or carbamate" cations as well as simple N-methylenium amides - nd vinyinitrosonium cations " have been shown to participate as effective cationic azadienes in [4+ + 2] cydoadditions. iV-Methyl-A -methylenium amide cations, e.g., 22, participate in [4 + 2] cydoadditions with neutral or conjugated dienophiles [Eq. (78)], ... 

The measured values for uracil [21] are -7.32 and -2.98 since the dication of 32 deprotonates to give an identical pK while that of 33 is much higher, the major deprotonation pathway of 31 must be 31d - 31b - 31a. No correction of OMe - OH for either 32 or 33 is needed since, in both cases, OMe is remote from the site of protonation. Hence, pK -5.84 is also expected for 31d->31c and pK 4.46 for 31c 31a follows by difference. The monocations 32b and 33b deprotonate to give identical piC values, which however require slightly different correction factors [3] to yield those of the OH tautomers 31b and 31c, since while the first is an amide cation the second is that of a urea this however is beyond the scope of this discussion. 

By analogy, ammonium salts should behave as acids in liquid ammonia, since they produce the cation NH4 (the solvo-cation ), and soluble inorganic amides (for example KNHj, ionic) should act as bases. This idea is borne out by experiment ammonium salts in liquid ammonia react with certain metals and hydrogen is given off. The neutralisation of an ionic amide solution by a solution of an ammonium salt in liquid ammonia can be carried out and followed by an indicator or by the change in the potential of an electrode, just like the reaction of sodium hydroxide with hydrochloric acid in water. The only notable difference is that the salt formed in liquid ammonia is usually insoluble and therefore precipitates. 

The amide is activated toward nucleophilic attack by protonation of its carbonyl oxygen The cation produced m this step is stabilized by resonance involving the nitro gen lone pair and is more stable than the intermediate m which the amide nitrogen is protonated... 

Deamidation of soy and other seed meal proteins by hydrolysis of the amide bond, and minimization of the hydrolysis of peptide bonds, improves functional properties of these products. For example, treatment of soy protein with dilute (0.05 A/) HCl, with or without a cation-exchange resin (Dowex 50) as a catalyst (133), with anions such as bicarbonate, phosphate, or chloride at pH 8.0 (134), or with peptide glutaminase at pH 7.0 (135), improved solubiHty, whipabiHty, water binding, and emulsifying properties. 

The biochemical basis for the toxicity of mercury and mercury compounds results from its ability to form covalent bonds readily with sulfur. Prior to reaction with sulfur, however, the mercury must be metabolized to the divalent cation. When the sulfur is in the form of a sulfhydryl (— SH) group, divalent mercury replaces the hydrogen atom to form mercaptides, X—Hg— SR and Hg(SR)2, where X is an electronegative radical and R is protein (36). Sulfhydryl compounds are called mercaptans because of their ability to capture mercury. Even in low concentrations divalent mercury is capable of inactivating sulfhydryl enzymes and thus causes interference with cellular metaboHsm and function (31—34). Mercury also combines with other ligands of physiological importance such as phosphoryl, carboxyl, amide, and amine groups. It is unclear whether these latter interactions contribute to its toxicity (31,36). 

Dialkyl and diarylthaHium(III) derivatives are stable, crystalline soHds that melt at 180—300°C. The dimethylthaHium derivatives of CN , CIO, BF, and NO 2 contain linear (CH2)2T1 cations and the free anions (19). In aqueous solutions, they ionize to the (CH2)2T1(H20) ions, except those derivatives containing alkoxide, mercaptide, or amide anions, which yield dimeric stmctures (20,21). 

In contrast to the above additions A-allyl- and substituted A-allyl-amides, -urethanes, -ureas and -thioureas undergo intramolecular cyclization only in 6(3-96% sulfuric acid to give the corresponding oxazolinium and thiazolinium salts. Treatment of these cations with base yields 2-oxazolines and 2-thiazolines in moderate to good yields. The reaction is illustrated by the conversion of A-2-phenylallylacetamide (342) into 2,5-dimethyl-5-phenyl-2-oxazoline (343) in 70% yield 70JOC3768) (see also Chapter 4.19). 

Aromatic ethers and furans undergo alkoxylation by addition upon electrolysis in an alcohol containing a suitable electrolyte.Other compounds such as aromatic hydrocarbons, alkenes, A -alkyl amides, and ethers lead to alkoxylated products by substitution. Two mechanisms for these electrochemical alkoxylations are currently discussed. The first one consists of direct oxidation of the substrate to give the radical cation which reacts with the alcohol, followed by reoxidation of the intermediate radical and either alcoholysis or elimination of a proton to the final product. In the second mechanism the primary step is the oxidation of the alcoholate to give an alkoxyl radical which then reacts with the substrate, the consequent steps then being the same as above. The formation of quinone acetals in particular seems to proceed via the second mechanism. ... 

MonofluoToalkanes and vicinal difluoroalkanes are dehydrofluonnated if strong enough bases are applied [10 12] In 5-fluorononane and fluorocyclodo-decane, elimination by means of sodium methoxide in methanol gives cis- and trans allcenes in respective yields of 8 and 21% and in ratios of 1 2 2 2 4, however, the bulky lithium diisopropyl amide m tetrahydrofuran produces trdns-isomers almost exclusively The strength of the base does not have much effect on the rate of elimination, but the lithium cation causes considerable acceleration [10] (equation 10)... 

Alkylation of enamines with epoxides or acetoxybromoalkanes provided intermediates for cyclic enol ethers (668) and branched chain sugars were obtained by enamine alkylation (669). Sodium enolates of vinylogous amides underwent carbon and nitrogen methylation (570), while vicinal endiamines formed bis-quaternary amonium salts (647). Reactions of enamines with a cyclopropenyl cation gave alkylated imonium products (57/), and 2-benzylidene-3-methylbenzothiazoline was shown to undergo enamine alkylation and acylation (572). A cyclic enamine was alkylated with methylbromoacetate and the product reduced with sodium borohydride to the key intermediate in a synthesis of the quebrachamine skeleton (57i). 

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