Theoretical Studies of the Asymmetric Binary‐Acid‐Catalyzed <i>tert</i>‐Aminocyclization Reaction: Origins of the CH Activation and Stereoselectivity

289

The direct functionalization of C-H bonds is an attractive strategy in organic synthesis. Although several advances have been made in this area, the selective activation of inert sp(3) C-H bonds remains a daunting challenge. Recently, a new type of sp(3) C-H activation mode through internal hydride transfer has demonstrated the potential to activate remote sp(3) C-H linkages in an atom-economic manner. This Minireview attempts to classify recent advances in this area including the transition to non-activated sp(3) C-H bonds and asymmetric hydride transfers.

Section: Enantioselective 15‐hydride‐shift Processessupporting

confidence: 77%

The Redox‐Neutral Approach to CH Functionalization

Peng

Maulide

2013

289

“…(Table 1, entry 5), whereas the others were found to be ineffective Lewis acid mediators for the transformation. Other lanthanide metal salts could furnish the product in a range of yields and enantioselectivities, all of which were inferior to that obtained with scandium(III) triflate ( Table 1, entries [6][7][8][9]. The structure of the N,N'dioxide ligands had a large effect on the enantioselectivity.…”

Section: Resultsmentioning

confidence: 96%

“…Since Reinhoudt et al [2] provided an alternative method of cleavage of a C(sp 3 )ÀH bond through an intramolecular tandem 1,5-hydride shift/ring closure process in 1984, variants of this rearrangement have been reported. [3][4][5][6] One challenge associated with this chemistry has been to render it enantioselective under mild reaction conditions. Chiral organocatalysts (e.g., chiral phosphoric acid and iminium) and chiral Lewis acids (e.g., Mg II , Co II and Au I coordinating with chiral ligands) are general catalysts that are used for the asymmetric transitions.…”

Section: Introductionmentioning

confidence: 99%

“…Chiral organocatalysts (e.g., chiral phosphoric acid and iminium) and chiral Lewis acids (e.g., Mg II , Co II and Au I coordinating with chiral ligands) are general catalysts that are used for the asymmetric transitions. This concept has enabled the straightforward construction of tetrahydroquinoline,6a–c, f–h furan‐fused benzazepines,6d cyclic aminals,6e spiroethers,6i and others.…”

Section: Introductionmentioning

confidence: 99%

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Asymmetric Tandem 1,5‐Hydride Shift/Ring Closure for the Synthesis of Chiral Spirooxindole Tetrahydroquinolines

Cao

Liu

Guo

et al. 2014

The direct functionalization of sp(3) C-H bonds through a tandem 1,5-hydride shift/ring closure is described. Various optically active spirooxindole tetrahydroquinoline derivatives bearing contiguous quaternary or tertiary stereogenic carbon centers were readily synthesized. A chiral scandium complex of N,N'-dioxide promoted the reactions in good yields (up to 97%) with excellent diastereoselectivities (>20:1) and enantioselectivities (up to 94% ee). Kinetic isotope effect (KIE) experiments and internal redox reactions of chiral substrates were conducted, and the results provided intriguing information that helped clarify the mechanism of the reaction.

“…Such a mechanism is also known for alkyllithium compounds that contain a β‐hydrogen atom, and hence act as hydride donors 15. Conceptually related [1,5]‐hydride‐transfer reactions, from carbon atoms α to the nitrogen atom to an electron acceptor, such as an activated vinyl group,9d,f,k,l iminium bond,9e imine,9c,h,i or aldehyde9j have been reported in the literature.…”

Section: Resultsmentioning

confidence: 99%

Lewis Acid Mediated Vinyl‐Transfer Reaction of Alkynes to N‐Alkylimines by Using the N‐Alkyl Residue as a Sacrificial Hydrogen Donor

Malakar

Stas

Herrebout

et al. 2013

A variety of N-alkyl-α,α-dichloroaldimines were vinylated by terminal acetylenes in the presence of Lewis acids such as In(OTf)3 or BF3 ⋅OEt2 and hexafluoroisopropanol (HFIP) as an additive. The reaction proceeds at ambient temperature and leads to geometrically pure allylic β,β-dichloroamines. This approach is complementary to previously reported transition-metal-catalyzed vinyl-transfer methods, which are not applicable to aliphatic imines and are restricted to imines that contain an electron-withdrawing nitrogen substituent. In the present approach, terminal alkynes were used as a source of the vinyl residue, and the N-alkyl moiety of the imine acts as a sacrificial hydrogen donor. The additional advantage of this methodology is the fact that no external toxic or hazardous reducing agents or molecular hydrogen has to be used. This new methodology nicely combines a C(sp(2) )C(sp) bond formation, hydride transfer, and an unusual cleavage of an unactivated CN bond, thereby giving rise to functionalized primary allylic amines. A detailed experimental study supported by DFT calculations of the mechanism has been done.