Amination anti-Markovnikov

With thionyl chloride as catalyst, hydrogen peroxide adds to vinyl ethers in anti-Markovnikov fashion, as do monothioglycols with amine catalysts... 

Organoboranes react with a mixture of aqueous NH3 and NaOCl to produce primary amines. It is likely that the actual reagent is chloramine NH2CI. Chloramine itself,hydroxylamine-O-sulfonic acid in diglyme, and trimethyl-silyl azide " also give the reaction. Since the boranes can be prepared by the hydroboration of alkenes (15-16), this is an indirect method for the addition of NH3 to a double bond with anti-Markovnikov orientation. Secondary amines can be prepared by the treatment of alkyl- or aryldichloroboranes or dialkylchlorobor-anes with alkyl or aryl azides. 

Ammonia can be added to double bonds (even ordinary double bonds) in an indirect manner by the use of hydroboration (15-16) followed by treatment with NH2CI or NH2OSO2OH (12-29). This produces a primary amine with anti-Markovnikov orientation. An indirect way of adding a primary or secondary amine to a double bond consists of aminomercuration followed by reduction (see 15-3 for the analogous oxymercuration-demercuration procedure), for example. 

It was thought that propionitrile came from dehydrogenation of the anti-Markovnikov hydroamination product, w-PrNHj. Propionitrile can break down to ethylene and HCN, the former reacting with NH3 to generate acetonitrile via ethyl-amine, the latter adding to propene to form the butyronitriles [26, 37]. 

The stoichiometric hydroamination of unsymmetrically disubstituted alkynes is highly regioselective, generating the azametaUacycle with the larger alkyne substituent a to the metal center [294, 295]. In others words, the enamine or imine formed results from an anti-Markovnikov addition. Unfortunately, this reaction could not be applied to less stericaUy hindered amines. 

In 1993, ten challenges faced the catalysis research community. One of these was the anti-Markovnikov addition of water or ammonia to olefins to directly synthesize primary alcohols or amines [323]. Despite some progress, the direct addition of N-H bonds across unsaturated C-C bonds, an apparently simple reaction, stiU remains a challenging fundamental and economic task for the coming century. 

Chatani and coworkers published an efficient method for the Rh(I)-catalyzed anti-Markovnikov hydroamination of terminal alkynes using either primary or secondary amines [58]. This reactivity had been observed earlier in the course of their studies on hydrative alkyne dimerization (Equation 9.8). 

The first example of anti-Markovnikov addition of O-nudeophiles to terminal alkynes was the catalytic addition of ammonium carbamates, generated in situ from secondary amines and carbon dioxide, to terminal alkynes, which regioselectively produced vinylcarbamates (Scheme 10.1) [5]. It was also the first time that a metal vinylidene was suggested as an active intermediate in catalysis [5]. 

Success was obtained with Ru3(CO)i2 as catalyst precursor [6], but the most efficient catalysts were found in the RuCl2(arene)(phosphine) series. These complexes are known to produce ruthenium vinylidene spedes upon reaction with terminal alkynes under stoichiometric conditions, and thus are able to generate potential catalysts active for anti-Markovnikov addition [7]. Similar results were obtained by using Ru(r]" -cyclooctadiene)(ri -cyclooctatriene)/PR3 as catalyst precursor [8]. (Z)-Dienylcarba-mates were also regio- and stereo-selectively prepared from conjugated enynes and secondary aliphatic amines (diethylamine, piperidine, morpholine, pyrrolidine) but, in this case, RuCl2(arene) (phosphine) complexes were not very efficient and the best catalyst precursor was Ru(methallyl)2(diphenylphosphinoethane) [9] (Scheme 10.1). 

Hosokawa, Murahashi, and coworkers demonstrated the ability of Pd" to catalyze the oxidative conjugate addition of amide and carbamate nucleophiles to electron-deficient alkenes (Eq. 42) [177]. Approximately 10 years later, Stahl and coworkers discovered that Pd-catalyzed oxidative amination of styrene proceeds with either Markovnikov or anti-Markovnikov regioselectivity. The preferred isomer is dictated by the presence or absence of a Bronsted base (e.g., triethylamine or acetate), respectively (Scheme 12) [178,179]. Both of these reaction classes employ O2 as the stoichiometric oxidant, but optimal conditions include a copper cocatalyst. More recently, Stahl and coworkers found that the oxidative amination of unactivated alkyl olefins proceeds most effectively in the absence of a copper cocatalyst (Eq. 43) [180]. In the presence of 5mol% CUCI2, significant alkene amination is observed, but the product consists of a complicated isomeric mixture arising from migration of the double bond into thermodynamically more stable internal positions. 

The second approach is limited to the synthesis of 4,4-dihalogeno-3,5-bis(halogenomethyl) derivatives of 82. Compounds 85 are obtained by electrophilic addition of tellurium tetrahalogenides to diallyl oxide, sulfide, or amine under the conditions of the double phase tellurohalogenation reaction (78KGS1212 89KGS564). The reaction follows to an anti-Markovnikov stereochemical course. The yields of the mixture of cis- and trans- isomers of compounds 85 are in the range 27-79%. By fractional crystallization the isomers of 85 (M = O, X = Br) were separated. 

Since alcohols are less effective as hydrogen donors than amines, a PET photoaddition can occur only when the oxidized component of the reaction is the alkene. Furthermore, if the photosensitizer is chiral, the polar addition would occur in an enantiodifferentiating manner to some degree. Thus, the photoaddition of 2-propanol to 1,1-diphenylpropene, when sensitized by chiral naphthalene(di)carbox-ylates, formed the anti-Markovnikov photoadduct with enantiomeric excesses of up to 58% [53]. Unfortunately, the reaction is far from attracting synthetic interest as the yields are still too low. 

The addition of borane to alkenes was first reported by H. C. Brown et al. [3] in 1956. The anti-Markovnikov insertion of an unsaturated moiety into a B-H bond of the borane (R2BH, RBH2 and BH3) proved to be the initial step for introduction of a very wide variety of functional groups. Within the following decade, the same author described the replacement of a boron atom by an amino group, affording a synthetic route from alkenes to amines [4] (Scheme 1). 

Products of addition to styrene double bonds can arise as a result of light induced electron transfer reactions. Lewis has studied the intramolecular reaction of l-phenyl-w-amino alkenes (422) 289,290 products arise from electron transfer from the amine nitrogen to the excited state of the styryl group followed by intramolecular proton transfer in the radical ion pair produced. The resultant biradical then couples to yield the isolated products (423) and (424). Sensitisation of the intermolecular analogue of this reaction by 1,4-dicyanobenzene has been reported and is proposed to occur by electron transfer from the styrene to the excited state of the sensitiser followed by attack of an amine on the styrene radical cation. This ultimately leads to the product of anti-Markovnikov addition of the amine across the double bond of the styrene. This is similar to the sequence long since established by... 

Hydroamination. On exchanging two of the Et2N groups of the title reagent to A-(2,6-diisopropylphenyl)benzamido residues, a precatalyst for anti-Markovnikov hydro-amination of 1-alkynes to form aldimines is readily obtained. 

Under hydroformylation conditions, amines effect hydroaminomethylation to alkenes in an anti-Markovnikov sense. ... 

The ET-sensitized photoamination of 1,1-diarylethylenes with ammonia and most primary amines yields the anti-Markovnikov adducts. Photoamination of unsymmetrically substituted stil-benes yields mixtures of regioisomers 15 and 16. Modest re-gioselectivity is observed for p-methyl or p-chloro substituents however, highly selective formation of adduct 15 is observed for the p-methoxy substituent (Table 5). Selective formation of 15 was attributed to the effect of the methoxy substituent on the charge distribution in the stilbene cation radical. This re-gioselectivity has been exploited in the synthesis of intermediates in the preparation of isoquinolines and other alkaloids." Photoamination of 1-phenyl-3,4-dihydronaphthalene yields a mixture of syn and anti adducts 17 and 18 (Scheme 5)." Use of bulky primary amines favors formation of the syn adduct (Table 5), presumably as a consequence of selective anti protonation of the intermediate carbanion. 

The photoinduced anti-Markovnikov addition of methanol to 1,1-diphenylethene reported by Arnold and co-workers in 1973 provides the first example of the addition of a nucleophile to an arylalkene radical cation. There are now a number of studies that demonstrate the generality of nucleophilic addition of alcohols, amines, and anions such as cyanide to aryl- and diaryl-alkene radical cations. Product studies and mechanistic work have established that addition occurs at the 3-position of I-aryl or 1,1 -diarylalkene radical cations to give arylmethyl or diaryl-methyl radical-derived products as shown in Scheme I for the addition of methanol to 1,1-diphenylethene. For neutral nucleophiles, such as alcohols and amines, radical formation requires prior deprotonation of the 1,3-distonic radical cation formed in the initial addition reaction. The final product usually results from reduction of the radical by the sensitizer radical anion to give an anion that is then protonated, although other radical... 

Palladium Pd(II)-catalysed hydroalkylation of Al-protected allylic amines PG(R )N-CH(R )C=CH2 (PG = protecting group) by Bu"ZnBr and other alkylzinc reagents has been reported to afford anti-Markovnikov products PG(R )N-CH(R )CH2CH2-Bu". Mechanistic studies suggest that a reversible jS-hydride elimination/hydride insertion process furnishes the primary Pd-alkyl intermediate, which undergoes transmetallation followed by reductive elimination to form a new sp -sp carbon-carbon bond. ° DFT PBE/3z calculations have been employed to elucidate the solvent effect on hydroxymethoxycarbonylation of cyclohexene catalysed by (Ph3P)2Pd. ... 

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