Hydroamination intramolecular processes

Due to its marked atom economy, the intramolecular hydroamination of alkenes represents an attractive process for the catalytic synthesis of nitrogen-containing organic compounds. Moreover, the nitrogen heterocycles obtained by hydroamination/cyclisation processes are frequently found in numerous pharmacologically active products. The pioneering work in this area was reported by Marks et al. who have used lanthanocenes to perform hydroamination/cyclisation reactions in 1992. These reactions can be performed in an intermolecular fashion and transition metals are by far the more efficient catalysts for promotion of these transformations via activation of the... 

Trivinyl benzene may be utilized in a hydroamination/carbocyclization process that is initiated by an intramolecular anft -Markovnikov addition of n-propylamine followed by an intramolecular hydroamination and a highly diastereoselective car-bocyclization step (44) [100]. 

One of the best-characterized examples of intramolecular hydroamidation of an alkene with the tethered activated nitrogen of amide and carbamate groups is shown in Equations 16.66a and 16.66b. This reaction is catalyzed by a dicationic palladium complex ligated by a PNP pincer ligand. Like the rhodium-catalyzed hydroamination, this process occurs to form five- and six-membered rings with or without substituents to bias the system toward cyclization.. 

Multiple efficient catalysts were reported for the intramolecular process, while the intermolecular process has been studied predominantly for alkynes. The reactivity of the unsaturated fragment decreases in the order alkyne > allene diene > vinyl arene unactivated alkene with the intermolecular hydroamination of simple alkenes representing the most difficult transformation. The hydroamination of all types of carbon-carbon unsaturated fragments will be covered in this chapter. 

The intermolecular hydroamination is significantly less feasible than the intramolecular process as the C-C unsaturated moiety is not tethered in the vicinity of the catalytic center. The mechanism is believed to be analogous to the intramolecular case, with insertion being less favorable [20]. The insertion step was identified to be rate limiting in the intermolecular lithium-amide-catalyzed hydroamination of vinyl arenes by detailed DFT-analysis [40]. 

The mechanism does not proceed through a direct hydroamination of one of the diastereotopic alkenes, but involves a series of very selective processes including a deprotonation of (22), diastereoselective protonation of (26), intramolecular addition of lithium amide (27) to the 1,3-diene moiety, and final regioselective protonation of the allyl anion (28), all mediated by a substoichiometric amount of n-BuLi. 

Type 4 metallocene complexes catalyze the regioselective mtermolecular addition of primary amines to acetylenic, olefinic, and diene substrates at rates which are = 1/1000 those of the most rapid intramolecular analogues [165]. Variants such as the intramolecular hydroamination/cyclization of aminoallenes [166] and the intra- and intermolecular tandem C-N and C-C bond-forming processes of aminodialkenes, aminodialkynes, aminoallenynes, and aminoalkynes [167] were applied as new regio- and stereoselective approaches to naturally occurring alkaloids. For example, bicyclic pyrrolizidine intermediate E... 

The scope of the lanthanide-mediated, intramolecular amination/cyclization reaction has been determined for the formation of substituted quinolizidines, indolizidines, and pyrrolizidines,1046 as well as tricyclic and tetracyclic aromatic nitrogen heterocycles.1047 The amide derivative OT ro-[ethylene-bis(indenyl)]ytterbium(m) bis(trimethyl-silyl)amide catalyzes the hydroamination of primary olefins in excellent yields.701 A facile intramolecular hydroamination process catalyzed by [(C5H4SiMe3)2Nd(/r-Me)]2 has also been reported. The lanthanide-catalyzed hydroamination enables a rapid access to 10,1 l-dihydro-5//-dibenzo[tf,rf]cyclohepten-5,10-imines (Scheme 283).1048... 

Intermolecular hydroamination of alkynes, which is a process with a relatively low activation barrier, has not been used for the synthesis of chiral amines, since the achiral Schiff base is a major reaction product. However, protected aminoalkynes may undergo an interesting intramolecular allylic cyclization using a palladium catalyst with a chiral norbomene based diphosphine ligand (Eq. 11.9) [115]. Unfor tunately, significantly higher catalyst loadings were required to achieve better enantioselectivities of up to 91% ee. 

The insertion approach is very successful in the hydroamination of alkynes and alkenes catalyzed by lanthanide complexes developed by Marks et al. [220]. Thorough mechanistic studies have been undertaken for the intramolecular reaction (hydroamination-cyclization of aminoalkenes), although the intermolecular version of the process is also efficient [222]. The mechanism of the reaction can be represented in a simplified way by Scheme 6.68. The insertion step is almost thermoneutral, but the protonolysis of the M-aminoalkyl bond that follows is exothermic and provides the necessary driving force. The insertion of the alkene into the Ln-N bond is irreversible and rate determining and it goes through a... 

The first hydroaminations by this mechanism were reported by Bergman with zircono-cene complexes and by Livinghouse with monocyclopentadienyl titanium and zirconium complexes. Bergman reported the intermolecular addition of a hindered aniline to an alkyne. The hindrance of the aniline was important to prevent formation of stable dimeric complexes containing bridging imido groups. Livinghouse reported intramolecular reactions that occurred at lower temperatures over shorter times. The intramolecularity of this process allows the [2+2] cycloaddition of the imido complex with the alkyne to be faster than the dimerization. 

Lanthanide complexes also catalyze the hydroamination of 13-dienes. The lanthanide catalysts originally developed for the intramolecular hydroamination of aminoalkenes are particularly active for the intramolecular additions of alkyl amines to dienes. The scope of this process is broad an illustrative example showing the high diastereoselectiv-ity of the cyclization of a chiral amine is shown in Equation 16.82. These reactions occur by insertion of the diene into a lanthanide-amide intermediate to form an allyl-metal intermediate. 

Some of the most active catalysts for the hydroamination of alkynes are based on lanthanides and actinides. The turnover frequencies for the additions are higher than those for lanthanide-catalyzed additions to alkenes by one or two orders of magnitude. Thus, intermolecular addition occurs with acceptable rates. Examples of both intermolecular and intramolecular reactions have been reported (Equations 16.87 and 16.88). Tandem processes initiated by hydroamination have also been reported. As shown in Equation 16.89, intramolecular hydroamination of an alk5me, followed by cyclization with the remaining olefin, generates a pyrrolizidine skeleton. Hydroaminations of aminoalkynes have also been conducted with the metallocenes of the actinides uranium and thorium. - These hydroaminations catalyzed by lanthanide and actinide complexes occur by insertion of the alkyne into a metal-amido intermediate. 

Synthesis of 1,2-disubstituted indole frameworks 257 via a formal 4 - - 1 cydoaddition between a 4-carbon unit and a primary amine was recently developed by Ackermann (Scheme 9.90) [242]. Reactive intermediates, 2-(o-haloaryl)enam-ines 256 were generated via the Cu(I)-catalyzed hydroamination of the orfHo-halo-substituted phenylacetylenes 254 with primary amines 255. A subsequent Cu(I)-catalyzed intramolecular enamine arylation reaction gave the corresponding indoles 257 in good yields. The authors demonstrated that alkynyl chlorides 254 could also participate in this cascade double amination process, albeit with a substantially diminished efHdency. 

Organolanthanide complexes are known to be highly active catalysts for a variety of organic transformations, which can be either intramolecular or intermolecular in character. Successful intramolecular transformations include hydroelementation processes, which is the addition of a H-E (E = N, O, P, Si, S, H) bond across unsaturated C-C bonds, such as hydroamination, hydroalkoxylation, and hydrophosphination. Intermolecular transformations include a series of asymmetric syntheses, the amidation of aldehydes with amines, Tishchenko reaction, addition of amines to nitriles, aUcyne dimerization, and guanylation of terminal aUcynes, amines, and phosphines with carbodiimides. 

The development of catalytic methods for the hydroamination of nonactivated alkenes, allenes, and alkynes has received considerable attention in recent years [1]. These highly atom-economical processes allow direct access to industrially and biologically relevant classes of compounds such as amines, enamines, and imines from cheap and readily available starting materials. This has recently led to an ever-increasing range of molecular compounds that have been identified as catalysts for these transformations (Scheme 13.1). Whereas rare-earth catalysts have been found to be mainly active in intramolecular hydroamination, other catalysts - in particular those of the late transition metals - are frequently limited to the addition of weakly basic substrates (aniline, sulfonamides, carboxamides, etc.) to alkenes, alkynes, and allenes. 

A Pd(II)-catalysed aerobic oxidative approach to 2,3-dihydro-l//-pyrrolo[l,2-u]indoles from Ai-alkynyl anilines by tandem intramolecular hydroamination and aryl C-H activation process has been reported. Molecular oxygen was the oxidant to recycle the Pd catalysis (Scheme 142). ... 

Using a similar Pt-catalyzed intermolecular oxidative dehydrogenation hydroamination followed by intramolecular aryl C(sp )—H fuctionalization process, Poli and coworkers developed a simple protocol for the synthesis of quinaldine 78 from readily available aniline and ethylene (Scheme 12.36) [41]. It was found that the selectivity of the catalytic reaction between aniline and ethylene in the presence of the Brunet catalyst (PtBr2/Br ) shifts from the hydroamination product Af-ethylaniline to the heterocyclization product... 

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