Direct Alkene Amination

The synthetic methods for the preparation of allyl amines can be divided into several types of reactions [1]. In the present chaptgr, the focus will be on the formation of allyl amines by reaction of substrates having an allylic bond which can be broken. Two approaches will be covered and these are outlined in Scheme 1 the first method (a) is the synthesis of allyl amines by nucleophilic allylic substitution of compounds having an allyl functionality the second method (b) is the direct allylic amination of simple alkenes. 

The reaction type (a) in Scheme 1 for the allylic amination reaction uses substrates which have an allylic C-X (X = heteroatom, halide) bond and is mainly nucleophilic amination of functionalized alkenes, whereas reaction type (b) is a direct allylic amination of an alkene, based on electrophilic amination of nonfunctionalized alkenes and involves a cleavage of a C-H bond. 

An attractive procedure for allylic amination is the direct electrophilic amination of alkenes. The single-step procedure allows a convenient allylic functionalization, which is an important part of this amination chemistry. However, compared to the nucleophilic amination of functionalized alkenes, the electrophilic amination of nonfunctionalized alkenes is much more complex, both from a synthetic and mechanistic point of view. 

Sharpless et al. and Muccigrosso et al. were probably the first to perform the direct allylic amination of nonfunctionalized alkenes in the presence of a metal complex [60]. The complex used for the allylic amination was the molibdooscaziridine 109 prepared by reaction of the molybdenum dioxo complex 107 and phenyl hydroxy-lamine 108 (Eq. (25)). 

Another often used chiral ligand is l,F-binaphthyl-2,2 -diyl-bis(phosphine), or binap.It can be built into ruthenium catalysts, which display high activities and enantio-selectivities for the hydrogenation of alkenes, amines, allylalcohols, and unsaturated carbonyls. A directing effect is observed for an a-hydroxy group in these cases. 

Phosphorinanones have been utilized as substrates for the preparation of alkenes/ amines,indoles, - and in the synthesis of a series of secondary and tertiary alcohols via reduction,and by reaction with Grignard and Refor-matsky - reagents. Phosphorinanones have also been used as precursors to a series of 1,4-disubstituted phosphor ins. The use of 4-amino-l,2,5,6-tetrahydro-l-phenylphosphorin-3-carbonitrile for the direct formation of phosphorino-[4,3-< ] pyrimidines has been reported. ... 

Generated in situ amidoiodanes 458 and 459 are usehil reagents for metal-free direct allylic amination or diamination of alkenes [616,617]. 

The dream of every X chemist is to get that amine function directly on the safrole molecule without having to go thru any intermediate such as the ketone of MD-P2P or the bromine of bromosafrole. But Strike can tell you right now that that is very, very tough (that is why there ain t no methods for it). About the only article Strike has ever found for the actual placement of an amine directly on a terminal alkene (a.k.a. safrole) is the following [79] ... 

The next method Strike has for semi-direct amination is really weird, Strike is really exposing Strike s ignorance of chemistry with this dog. But if one looks hard at the articles cited, the potential is there. The authors came up with this little procedure that produced vicinal diamines out of alkenes [83]. Later they found that if they did a couple of things different, they would end up with a monoamine with the majority product being at the beta carbon. The following is a conjoining of the two paper s experimentals ... 

In 1974, Hegedus and coworkers reported the pa]ladium(II)-promoted addition of secondary amines to a-olefins by analogy to the Wacker oxidation of terminal olefins and the platinum(II) promoted variant described earlier. This transformation provided an early example of (formally) alkene hydroamination and a remarkably direct route to tertiary amines without the usual problems associated with the use of alkyl halide electrophiles. 

The groups R2N and Cl can be added directly to alkenes, allenes, conjugated dienes, and alkynes, by treatment with dialkyl-V-chloroamines and acids. " These are free-radical additions, with initial attack by the R2NH- radical ion. " N-Halo amides (RCONHX) add RCONH and X to double bonds under the influence of UV light or chromous chloride. " Amines add to allenes in the presence of a palladium catalyst. ... 

DL-Valiolamine (205) was synthesized from the exo-alkene (247) derived from 51 with silver fluoride in pyridine. Compound 247 was treated with a peroxy acid, to give a single spiro epoxide (248, 89%) which was cleaved by way of anchimeric reaction in the presence of acetate ion to give, after acetylation, the tetraacetate 249. The bromo group was directly displaced with azide ion, the product was hydrogenated, and the amine acety-lated, to give the penta-A, 0-acetyl derivative (250,50%). On the other hand. 

It is thus obvious that the direct transformation of a simple alkene into an amine would be a more economic process, since it would suppress at least one step without formahon of co-products (atom efficiency) [Scheme 4-1, paths (c) and (d)]. 

Hydroaminomethylahon of alkenes [path (c)j wiU not be considered [12]. This review deals exclusively with the hydroaminahon reaction [path (d)], i.e. the direct addition of the N-H bond of NH3 or amines across unsaturated carbon-carbon bonds. It is devoted to the state of the art for the catalytic hydroamination of alkenes and styrenes but also of alkynes, 1,3-dienes and allenes, with no mention of activated substrates (such as Michael acceptors) for which the hydroamination occurs without catalysts. Similarly, the reachon of the N-H bond of amine derivatives such as carboxamides, tosylamides, ureas, etc. will not be considered. 

Entries 5 to 7 are examples of oxidation of boranes to the carbonyl level. In Entry 5, chromic acid was used to obtain a ketone. Entry 6 shows 5 mol % tetrapropylam-monium perruthenate with Af-methylmorpholine-lV-oxide as the stoichiometric oxidant converting the borane directly to a ketone. Aldehydes were obtained from terminal alkenes using this reagent combination. Pyridinium chlorochromate (Entry 7) can also be used to obtain aldehydes. Entries 8 and 9 illustrate methods for amination of alkenes via boranes. Entries 10 and 11 illustrate the preparation of halides. 

These cinchona esters also effect asymmetric dihydroxylation of alkenes in reactions with an amine N-oxide as the stoichiometric oxidant and 0s04 as the catalyst. Reactions catalyzed by 1 direct attack to the re-face and those catalyzed by 2 direct attack with almost equal preference for the 5i-face. 

The primary products obtained from 2-butanol are of mechanistic. significance and may be compared with other eliminations in the sec-butyl system 87). The direction of elimination does not follow the Hofmann rule 88) nor is it governed by statistical factors. The latter would predict 60% 1-butene and 40% 2-butene. The greater amount of 2-alkene and especially the unusual predominance of the cis-olefin over the trans isomer rules out a concerted cis elimination, in which steric factors invariably hinder the formation of cis-olefin. For example, the following ratios oicisjtrans 2-butene are obtained on pyrolysis of 2-butyl compounds acetate, 0.53 89, 90) xanthate, 0.45 (S7) and amine oxide, 0.57 86) whereas dehydration of 2-butanol over the alkali-free alumina (P) gave a cisjtrans ratio of 4.3 (Fig. 3). 

Nitroso compounds are formed during the addition of nitrous oxide," " dinitrogen trioxide, and nitrosyl halides to alkenes, and in some cases, from incomplete oxidation of amines with peroxyacids like peroxyacetic acid. Quenching of carbanions with nitrosyl halides is also a route to nitroso compounds. A full discussion on this subject is beyond the scope of this work and so the readers are directed to the work of Boyer. ... 

Sulfonylhydroxylamines and hydroxylamine O-sulfonic acid have found wide apph-cation in synthesis of amines from achiral or chiral organoboranes and boronate esters and the hydroboration-amination methodology is successfully used for direct amination of alkenes. 0-Sulfonyloximes were also found to be good reagents for synthesis of amines from organomagnesium, -copper and -zinc reagents. 

The meso-ionic l,3>2-oxathiazol-5-ones (169) show an interesting range of reactions with nucleophiles including ammonia, primary amines, and aqueous alkali. They also react with l,3-dipolarophiles, including dimethyl acetylenedicarboxylate and methyl propiolate, yielding isothiazoles (171) and carbon dioxide. 1,3-Dipolar cycloaddition reactions with alkenes such as styrene, dimethyl maleate, and methyl cinnamate also lead to isothiazoles (171) directly. BicycUc intermediates (cf. 136) were not isolable these cycloaddition reactions with alkenes giving isothiazoles involve an additional dehydrogenation step. 

Considering the ample possibilities to generate new carbon-hereoatom bonds, particularly the wide range of oxygenation reactions, only limited attempts have been made to carry out direct amination of hydrocarbons. A few examples of animation of alkanes, alkenes, and aromatics are discussed briefly here. 

Olefins react directly at the electron-rich and rather electron-deficient oxygens. If the dimer is much more reactive toward olefins than the monomer, only a small fraction of the alkaloid-Os04 complex need be present as a dimer (94a). Houk developed a symmetrical five-membered transition-structure model on the basis of X-ray crystal structures of Os04-amine complexes and osmate ester products and ab initio transition structures of analogous reactions (Scheme 40). The MM2 calculations based on this [3 + 2] reaction model reproduce the stereoselectivities of the stoichiometric reactions observed with several chiral diamines (94b). The transition state may be stabilized by tt-tt interaction of the alkene substrate and the ligand aromatic ring (95). 

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