Subject amine salts

The aminometallation reaction is of special relevance to the key step involved in metal-catalyzed amination of alkenes and alkynes [4b,d,41]. The reversible attack of aliphatic amines at the monoalkene ligand shown in Eq. 8.6 may proceed in stereospecific trans addition and elimination [42]. For example, diethylamine was reacted with 1-butene, which coordinated to Pt using only one enantioface of the olefin ((S)-l-butene-Pt bond) (Scheme 8.24) [42a]. Alkylplatinum complex thus formed was subjected to acidic work-up to give optically active amine salt having the S-configuration at the asymmetric carbon. This result unambiguously demon-... 

The Carra Letter addressed a particularly vexing example of a polymer salt in inks. Insoluble polymer acids are converted to soluble amine salts of the polymer by pH neutralization when certain inks are made. The salts are made during the formulation of the ink, and other ink formulation ingredients are present. EPA concluded that the polymer salts do not contribute a primary property of the commercial ink although they do impart physicochemical properties to the ink. They are not the product intended for distribution in commerce, and they have no commercial purpose outside of the ink formulation in which they are formed. As a result of these conclusions, these polymer salts are not required to be on the Inventory and entities that make or import them as part of an ink product are not subject to the PMN regulations. 

In general, the most common method of preparing diazonium salts involves the treatment of a soluble aromatic amine salt in aqueous mineral acid at low temperature with sodium nitrite. In this connection it should be kept in mind that many aromatic amines require considerable purification prior to use since they are subject to air oxidation. Frequently, purification of the amine in the presence of traces of sodium hydrosulfite in a recrystallizing solvent is helpful in overcoming discolorations due to oxidation. Also to be kept in mind in preparing diazonium salts is the fact that the hydrochloride salts of many aromatic amines are more soluble at low temperatures than at high temperatures. 

Addition of several organomercury compounds (methyl, aryl, and benzyl) to conjugated dienes in the presence of Pd(II) salts generates the ir-allylpalladium complex 422, which is subjected to further transformations. A secondary amine reacts to give the tertiary allylic amine 423 in a modest yield along with diene 424 and reduced product 425[382,383]. Even the unconjugated diene 426 is converted into the 7r-allyllic palladium complex 427 by the reaction of PhHgCI via the elimination and reverse readdition of H—Pd—Cl[383]. 

The viscous oil resin Is slurried twice with 250 cc portions of methanol to remove any unreacted primary amines. The oil residue after being washed with methanol is dissolved in ethyl alcohol and 75 cc of concentrated hydrochloric acid is added dropwise to the warm alcohol solution of the base. The dihydrochloride salts of the several hydroabietyl ethylenediamines precipitates immediately from solution. The salt is then separated by filtering and is washed twice with 100 cc portions of cooled ethyl alcohol. The dihydrochloride salts of the dehy-droabietyl, dihydroabietyl and tetrahydroabietyl ethylenediamine mixture have a melting point of about 292°C to 295°C. On subjecting the mixture to solubility analyses it Is found that the dehydroabietyl ethylenediamine is present in substantially the same proportion as is the dehydroabietylamine in the original "Rosin Amine D."... 

Benzylic quaternary ammonium salts, when treated with alkali metal amides, undergo a rearrangement called the Sommelet-Hauser rearrangementSince the product is a benzylic tertiary amine, it can be further alkylated and the product again subjected to the rearrangement. This process can be continued around the ring until an ortho position is blocked. ... 

The fourth chapter gives a comprehensive review about catalyzed hydroamina-tions of carbon carbon multiple bond systems from the beginning of this century to the state-of-the-art today. As was mentioned above, the direct - and whenever possible stereoselective - addition of amines to unsaturated hydrocarbons is one of the shortest routes to produce (chiral) amines. Provided that a catalyst of sufficient activity and stabihty can be found, this heterofunctionalization reaction could compete with classical substitution chemistry and is of high industrial interest. As the authors J. J. Bmnet and D. Neibecker show in their contribution, almost any transition metal salt has been subjected to this reaction and numerous reaction conditions were tested. However, although considerable progress has been made and enantios-electivites of 95% could be reached, all catalytic systems known to date suffer from low activity (TOP < 500 h ) or/and low stability. The most effective systems are represented by some iridium phosphine or cyclopentadienyl samarium complexes. 

Another situation is observed when salts or transition metal complexes are added to an alcohol (primary or secondary) or alkylamine subjected to oxidation in this case, a prolonged retardation of the initiated oxidation occurs, owing to repeated chain termination. This was discovered for the first time in the study of cyclohexanol oxidation in the presence of copper salt [49]. Copper and manganese ions also exert an inhibiting effect on the initiated oxidation of 1,2-cyclohexadiene [12], aliphatic amines [19], and 1,2-disubstituted ethenes [13]. This is accounted for, first, by the dual redox nature of the peroxyl radicals H02, >C(0H)02 and >C(NHR)02 , and, second, for the ability of ions and complexes of transition metals to accept and release an electron when they are in an higher- and lower-valence state. 

The starting benzothiazole carboxylic ester 387 was subjected to a Anamination by using mesityl hydroxylamine to give an A -amino salt 388, which was treated with a tertiary amine to give the deprotonated intermediate 389. This species when reacted with phenylisocyanate yielded the final product 390 in moderate yield <2001JOC8528>. 

The phosphonium and carbenium salts are efficient reagents for activating and coupling A-alkoxycarbonylamino acids as well as peptide acids. However, the requirement for tertiary amine to effect the reaction has several implications. The base renders hydroxyl groups subject to acylation. Hence, the side chains of serine and threonine and any hydroxymethyl groups of a resin that have not been derivatized... 

N-Boc-N-(but-2-enoyl)amine is an excellent pronucleophile for the Ir-catalyzed allylic amination under salt-free conditions (cf. Table 9.3, entries 15-18). The products were subjected to RCM with good results, even upon application of the Grubbs I catalyst (Scheme 9.29) [27bj. The resultant N-Boc protected a,P-unsaturated y-lactams are valuable chiral intermediates with appUcations in natural products synthesis and medicinal chemistry. 

The nitrogen atoms of heterocycles like imidazoles and triazoles have been converted into IV-nitroimide groups. The A -nitroimide (164) is synthesized from 1-amino-1,3,4-triazole (162) by IV-amination of the tertiary nitrogen with 0-picrylhydroxylamine, addition of nitric acid to give the nitrate salt (163), followed by IV-nitration with nitronium tetrafluoroborate in acetonitrile. The 1,2,3-triazole (165) and the imidazole (166) ° are synthesized in a similar way. The synthesis of IV-nitroimides has been the subject of an excellent review. ... 

When 2,2-dichloro-3-phenylpropanal 203 is subjected to standard reaction conditions with chiral triazolium salt 75c, the desired amide is produced in 80% ee and 62% yield Eq. 20. This experiment suggests that the catalyst is involved in an enantioselec-tive protonation event. With this evidence in hand, the proposed mechanism begins with carbene addition to the a-reducible aldehyde followed by formation of activated car-boxylate XLII (Scheme 32). Acyl transfer occurs with HOAt, presumably due to its higher kinetic nucleophilicity under these conditions, thus regenerating the carbene. In turn, intermediate XLin then undergoes nucleophilic attack by the amine and releases the co-catalyst back into the catalytic cycle. 

The Merck process group subsequently published a more detailed route amenable towards multikilogram scales (Blacklock et al., 1988). This synthesis begins with treatment of alanine with phosgene to produce A-carboxyanhydride (NCA) 16 (Scheme 10.3). Under basic aqueous conditions this anhydride is coupled with proline to produce, upon acidic work-up, the dipeptide alanyl-proline (14). Enalapril is then prepared in one synthetic step by a diastereoselective reductive amination between ethyl-2— oxo-4-phenylbutyrate (13) and 14. This reaction was the subject of extensive optimization, and it was found that the highest diastereoselectivity was obtained by hydrogenation over Raney nickel in the presence of acetic acid (25%), KF (4.0 equiv.), and 3 A molecular sieves (17 1 dr). Enalapril is then isolated in diastereomerically pure form as its maleate salt (Huffman and Reider, 1999 Huffman et al., 2000). 

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