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Spiro Compounds


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[32]. The catalyst 214 was successfully implemented in the [4+2] cyclization between methyleneindolinones 15 and 2‐vinyl‐1H‐indoles 215 to assemble carbazolespirooxindoles 216 in excellent yields (62–99%) and stereoselectivities (81–>99% ee, >20 : 1 dr). The methodology has a broad tolerance to structural changes in both substrates (25 examples). Control experiments suggest that N−H groups in both substrates actively interact with the organocatalyst 214, having sizable influence on the observed enantioselectivity (Scheme 3.20). Moreover, water plays a critical role in the enantioselectivity via an H2O‐relay H‐bond between the catalyst and the 2‐vinyl‐1H‐indole.

Schematic illustration of a chemical reaction depicting chiral H-bond donor-catalyzed asymmetric Tamura [4+2]-cycloaddition.

      Source: Modified from Manoni and Connon [31].

      3.3.3 Organocatalytic [4+3] and [2+2] Cycloaddition and Switchable Strategies to Construct Spirocompounds

Schematic illustration of a chemical reaction depicting enantioselective Diels–Alder cyclization for the synthesis of carbazolespirooxindoles.

      Source: Modified from Ren et al. [32].

Schematic illustration of a chemical reaction depicting nHC-catalyzed [4+3] annulation of oxotryptamines with enals to access enantioenriched spiro-ϵ-lactam oxindoles.

      Source: Modified from Liu et al. [33].

Schematic illustration of a chemical reaction depicting organocatalytic enamine-activation of cyclopropanes for highly stereoselective formation of spiranic cyclobutanes.

      Source: Modified from Halskov et al. [34].

Schematic illustration of a chemical reaction depicting chiral primary amine-catalyzed regiodivergent asymmetric cycloadditions.

      Source: Modified from Zhou et al. [35].

      3.3.4 Organocatalytic Miscellaneous Strategies to Construct Spiro Compounds