Thiourea Bronsted bases

The roles of the catalytic functions are not necessarily opposite or limited to Lewis acid/base pairs. For example, amine thiourea derivatives like Takemoto s catalyst 4 merge the hydrogen bond donor capability of the thiourea moiety with Bronsted base functionality of the amine function and revealed itself particularly efficient organocatalysts for Michael reactions of various 1,3-dicarbonyl compounds with nitroolefins (Scheme 3) [17-19]. 

Br0nsted Base-Derived Thiourea Catalysts 353 Chiral Bifunctional Bronsted Base Thiourea Catalyst... 

Figure 13,6 Basic scaffold of chiral Bronsted base derived thiourea catalysts.

The synthetic utility of the bifunctional catalysts in various organic transformations with chiral cyclohexane-diamine derived thioureas was established through the works of Jacobsen, Takemoto, Johnston, Li, Wang, and Tsogoeva. In the last decade, asymmetric conjugate-type reactions have become popular with cinchona alkaloid derived thioureas. The next section presents non-traditional asymmetric reactions of nitroolefins, enones, imines, and cycloadditions to highlight the role of chiral Bronsted base derived thiourea catalysts. 

A number of BINOL-based bifunctional organocatalysts, for example (7.171-7.173), containing both Bronsted acidic and Lewis basic sites have been used to good effect in the asymmetric MBH reaction. The amine-thiourea (7.171) promotes the MBH reaction of aliphatic aldehydes with 2-cyclohexenone with ees ranging from 80 to 94% while both the (pyridinylaminomethyl)BINOL (7.172) and phosphine (7.173) catalyse the aza-Bayhs-Hilhnan reaction of simple a,p-carbonyls such as MVK and phenyl acrylate with N-tosyl arylaldmines with similar levels of enantioselectivity. 

Ibrahem, Cordoba and colleagues demonstrated more recently that a hydrogen-bond donor additive could accelerate the rate of the reaction, much better than the addition of water or Bronsted acid or base. In particular, thiourea 10 used as a cocatalyst (10 mol%) with OTBDMS-L-Thr (20 mol%) led to the expected (3-hydro>y ketones with configurations anti-6 or syn-7 depending on the substrate. 

The greater scope of this reaction was attributed to the dual cyclic Bronsted acid/H-Bond donar cocatalysis mechanism. The catalytic cycle initially involves imine protonation by the chiral thiourea catalyst 170 associated via H-bonding to the conjugate base (X ) of a weak Bronsted acid (H-X, benzoic acid in this case) additive. Intramolecular cyclization of the protonated iminium ion 146, followed by rearomatization regenerates the Bronsted acid cocatlayst (benzoic acid). Note for brevity, the plausible rearrangement (RR) step of the inital CCij-spiroalkylated adduct to the final tetrahydrohydroisoquinoline scaffold 147 is not shown. 

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