Amines with additives

Rovis and Vora sought to expand the utility in alpha redox reactions to include the formation of amides [116]. While aniline was previously demonstrated as an efficient nucleophile in this reaction (Scheme 29), attempts to develop the scope to include non-aryl amines as various primary and secondary amines resulted in low yields. The discovery of a co-catalyst was the key to effecting amide formation (Table 15). Various co-catalysts, including HOBt, HOAt, DMAP, imidazole, and pentafluorophenol, are efficient and result in high yields of a variety of amides including those involving primary and secondary amines with additional functionality. 

There also exists an acidregioselective condensation of the aldol type, namely the Mannich reaction (B. Reichert, 1959 H. Hellmann, 1960 see also p. 291f.). The condensation of secondary amines with aldehydes yields Immonium salts, which react with ketones to give 3-amino ketones (=Mannich bases). Ketones with two enolizable CHj-groupings may form 1,5-diamino-3-pentanones, but monosubstitution products can always be obtained in high yield. Unsymmetrical ketones react preferentially at the most highly substituted carbon atom. Sterical hindrance can reverse this regioselectivity. Thermal elimination of amines leads to the a,)3-unsaturated ketone. Another efficient pathway to vinyl ketones starts with the addition of terminal alkynes to immonium salts. On mercury(ll) catalyzed hydration the product is converted to the Mannich base (H. Smith, 1964). 

The reaction of amines with the 4-phenylazo derivative (228) results in their rearrangement into triazolines. Depending on the basicity of the amines and the size of the alkoxy group, three different triazolines (229. 230, and 231) are obtained (Scheme 117) (454. 459, 472). In all cases, the first step involves nucleophilic addition of the amine to the carbonyl group followed by ring opening and further ring closure. 

A number of compounds of the general type H2NZ react with aldehydes and ketones m a manner analogous to that of primary amines The carbonyl group (C=0) IS converted to C=NZ and a molecule of water is formed Table 17 4 presents exam pies of some of these reactions The mechanism by which each proceeds is similar to the nucleophilic addition-elimination mechanism described for the reaction of primary amines with aldehydes and ketones... 

Analogously, aldehydes react with ammonia [7664-41-7] or primary amines to form Schiff bases. Subsequent reduction produces a new amine. The addition of hydrogen cyanide [74-90-8] sodium bisulfite [7631-90-5] amines, alcohols, or thiols to the carbonyl group usually requires the presence of a catalyst to assist in reaching the desired equilibrium product. 

Aromatic amines form addition compounds and complexes with many inorganic substances, such as ziac chloride, copper chloride, uranium tetrachloride, or boron trifluoride. Various metals react with the amino group to form metal anilides and hydrochloric, sulfuric, or phosphoric acid salts of aniline are important intermediates in the dye industry. 

The second major route to diarylamiaes is the condensation of an aromatic amine with a phenol. Aniline [62-53-3] phenol [108-95-2] and 3.5% phosphoric acid at 325°C gives a 50% yield of DPA (23). Apparently, this reaction iavolves the addition of aniline to the keto form of the phenol. Thus, naphthols and hydroquiaone are more reactive and give higher yields of product. This is the preferred route to A/-phenyi-2-naphthyiamiQe, 4-hydroxydiphenyiamiQe, and diphenyl- -phenylenediamine (24). 

The bismaleimide can then be polymerized by reaction with additional amine to form polyaininobismaleknide or by radiation-induced homopolymerization to form polybismaleimide (4). 

AH of the amine hydrogens are replaced when MDA or PMDA reacts with epoxides to form amine based polyols. These polyols can be used in reactions with isocyanates to form urethanes or with additional epoxide to form cross-linked thermo set resins. 

The thiophthalimide (CTP) and sulfenamide classes of retarders differ from the organic acid types by thek abiUty to retard scorch (onset of vulcanization) without significantly affecting cure rate or performance properties. Much has been pubUshed on the mechanism of CTP retardation. It functions particularly well with sulfenamide-accelerated diene polymers, typically those used in the the industry. During the initial stages of vulcanization, sulfenamides decompose to form mercaptobenzothiazole (MBT) and an amine. The MBT formed reacts with additional sulfenamide to complete the vulcanization process. If the MBT initially formed is removed as soon as it forms, vulcanization does not occur. It is the role of CTP to remove MBT as it forms. The retardation effect is linear with CTP concentration and allows for excellent control of scorch behavior. 

High molecular weight primary, secondary, and tertiary amines can be employed as extractants for zirconium and hafnium in hydrochloric acid (49—51). With similar aqueous-phase conditions, the selectivity is in the order tertiary > secondary > primary amines. The addition of small amounts of nitric acid increases the separation of zirconium and hafnium but decreases the zirconium yield. Good extraction of zirconium and hafnium from ca 1 Af sulfuric acid has been effected with tertiary amines (52—54), with separation factors of 10 or more. A system of this type, using trioctylarnine in kerosene as the organic solvent, is used by Nippon Mining of Japan in the production of zirconium (55). 

Reaction of primary amines with aldehydes and ketones (Section 17.10) Imines are formed by nucleophilic addition of a primary amine to the carbonyl group of an aldehyde or a ketone. The key step is formation of a carbinolamine intermediate, which then dehydrates to the imine. 

Shortly thereafter, Knorr reported that combining ammonia or primary amines with 1,4-dicarbonyls furnished substituted pyrroles (see Section 2.2), and Paal produced thiophenes by addition of hydrogen sulfide with 1,4-dicarbonyls. ... 

None of the 3-halogenopyridines yield 2-piperidinopyridine. This substance was obtained as the only product from the reaction of 2-fluoropyridine (24, X = F) with lithium piperidide under the same conditions in 97% yield. Finally, it was found that 4-chloropyridine (32, X = Cl) was converted in 95% total yield into a mixture of 0.4% of 3-piperidino- (29, Y = NC5H10) and 99.6% of 4-piperidino-pyridine (34, Y = NCsHio)- Thus, in contrast to the amination with potassium amide, 4-chloropyridine reacts with lithium piperidide almost exclusively via the addition product 33 (X = Cl, Y = NC5H10). 

Another approach involves utilization of the amines for addition of a fused pyridine ring to the benzothiadiazole skeleton. The Gould-Jacobs reaction of 4-amino-2,l,3-benzothiadiazole 60 with diethyl ethoxymethylenemalonate gave the substitution product, and, after thermal cyclization in diphenyl ether, afforded the... 

The same method was employed for the synthesis of benzo[<2]phenotellurazine 42 and proven to be more efficient. The heterocycle 42 was obtained in 55% yield (89H1007). A possible explanation for the higher yield of 42 is that the transmetallation reaction in this particular case dominates the side formation of nonreactive complex of the amine with tellurium tetrachloride. There is no need for an additional step of the isomerization of the formed aryltellurim trichloride. 

The usual procedure is to simply heat a mixture of the starting materials. A common side-reaction is the polyalkylation it can be suppressed by employing an excess of amine. In addition carbonyl substrates with a-hydrogens may undergo competitive aldol reactions the corresponding reaction products may then undergo a subsequent Leuckart-Wallach reaction. 

The Schiemann reaction seems to be the best method for the selective introduction of a fluorine substituent onto an aromatic ring. The reaction works with many aromatic amines, including condensed aromatic amines. It is however of limited synthetic importance, since the yield usually decreases with additional substituents present at the aromatic ring. 

N— compounds used as acid inhibitors include heterocyclic bases, such as pyridine, quinoline and various amines. Carassiti describes the inhibitive action of decylamine and quinoline, as well as phenylthiourea and dibenzyl-sulphoxides for the protection of stainless steels in hydrochloric acid pickling. Hudson e/a/. refer to coal tar base fractions for inhibition in sulphuric and hydrochloric acid solutions. Good results are reported with 0-25 vol. Vo of distilled quinoline bases with addition of 0 05m sodium chloride in 4n sulphuric acid at 93°C. The sodium chloride is acting synergistically, e.g. 0-05m NaCl raises the percentage inhibition given by 0-1% quinoline in 2n H2SO4 from 43 to 79%. Similarly, potassium iodide improves the action of phenylthiourea . 

The addition of (E)- and (Z)-crotylboronates 7 to aldoximes 6 has been realized in good yield by performing the reaction under 3-6 x 10° Torr pressure10. The resulting hydroxylamines 8 can easily be reduced to yield the primary amines. The addition of E-l leads preferentially to the anh-diastereomcr 8, while (Z)-crotylboronate 7 shows a modest selectivity towards formation of the vyy -diastereomer 8 (same sense as in the reaction with aldehydes). Some effort has been made to elucidate the mechanism, but this is not yet well understood. 

Unusual orientation has been reported for amination with halomines and with NCI3 in the presence of AICI3. For example, toluene gave predominately meta amination. It has been suggested that initial attack in this case is by Cl and that a nitrogen nucleophile (whose structure is not known but is represented here as NHJ for simplicity) adds to the resulting arenium ion, so that the initial reaction is addition to a carbon-carbon double bond followed by elimination of HCl ... 

Some advances have been made in the Paal-Knorr synthesis of pyrroles by the condensation of primary amines with 1,4-dicarbonyl species. For instance, a new synthetic route to monosubstituted succinaldehydes allows for the facile preparation of 3-substituted pyrroles <96TL4099>. Additionally, a general method for the synthesis of 1-aminopyiroles has been devised by the condensation of commercially available 2,2,2-trichloroethyl- or 2-(tri-methylsilyl)ethylhydrazine with 1,4-dicarbonyl compounds <96JOCl 180>. A related route to such compounds involves the reaction of a-halohydrazones with p-dicarbonyl compounds <96H(43)1447>. Finally, hexamethyldisilazane (HMDS) can be utilized as the amine component in the Paal-Knorr synthesis in the presence of alumina, and this modification has been employed in the synthesis of tm azaprostacyclin analog <96S1336>. 

Recent efforts in the development of efficient routes to highly substituted yS-ami-no acids based on asymmetric Mannich reactions with enantiopure sulfmyl imine are worthy of mention. Following the pioneering work of Davis on p-tolu-enesulfmyl imines [116], Ellman and coworkers have recently developed a new and efficient approach to enantiomerically pure N-tert-butanesulfmyl imines and have reported their use as versatile intermediates for the asymmetric synthesis of amines [91]. Addition of titanium enolates to tert-butane sulfmyl aldimines and ketimines 31 proceeds in high yields and diastereoselectivities, thus providing general access to yS -amino acids 32 (Scheme 2.5)... 

Not only N-H bonds from amines can participate in the aminolysis reaction, but also less nucleophilic urea, thiourea and biuret NH units can react with halophosphanes in an effective manner, forming the corresponding phosphinous amides with additional functionalities at the nitrogen atom [39-44]. 

On the theoretical side, study of the dissociation of addition compounds of amines with trimethylborane, boron trifluoride, and borane provide a new quantitative approach to steric strains. These studies quickly removed doubts as to the importance of steric effects in chemical behavior. 

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