Conspectus
Asymmetric synthesis using organic
catalysts has evolved since
it was first realized and defined. Nowadays, it can be considered
a valid alternative to transition metal catalysis for synthesizing
chiral molecules. According to the literature, the number of asymmetric
organocatalytic processes associated with atropisomer synthesis has
rapidly increased over the past 10 years because organocatalysis addresses
the challenges posed by the most widespread strategies used for preparing
axially chiral molecules with satisfactory results.
These strategies,
useful to prepare a wide range of C–C,
C–heteroatom, and N–N atropisomers, vary from kinetic
resolution to direct arylation, desymmetrization, and central-to-axial
chirality conversion. In this field, our contribution focuses on determining
novel methods for synthesizing atropisomers, during which, in most
cases, the construction of one or more stereogenic centers other than
the stereogenic axis occurred. To efficiently address this challenge,
we exploited the ability of catalysts based on a cinchona alkaloid
scaffold to realize enantioselective organic transformations. Desymmetrization
of N-(2-tert-butylphenyl) maleimides
was one of the first strategies that we pursued for preparing C–N
atropisomers. The main principle is based on the presence of a rotationally
hindered C–N single bond owing to the presence of a large tert-butyl group. Following the peculiar reactivity of this
type of substrate as a powerful electrophile and dienophile, we realized
several transformations.
First, we investigated the vinylogous
Michael addition of 3-substituted
cyclohexenones, where a stereogenic axis and two contiguous stereocenters
were concomitantly and remotely formed and stereocontrolled using
a primary amine catalyst. Subsequently, we realized desymmetrization
via an organocatalytic Diels–Alder reaction of activated unsaturated
ketones that enabled highly atropselective transformation with efficient
diastereoselectivity, thereby simultaneously controlling four stereogenic
elements. Employing chiral organic bases allowed us to realize efficient
desymmetrizations using carbon nucleophiles, such as 1,3-dicarbonyl
compounds, cyanoacetates, and oxindoles. These reactions, performed
with different types of catalysts, highlighted the versatility of
organocatalysis as a powerful strategy for atropselective desymmetrization
of pro-axially chiral maleimides.
Hereafter, we studied the
Friedel–Crafts alkylation of naphthols
with indenones, a powerful method for enantioselective synthesis of
conformationally restricted diastereoisomeric indanones. We realized
the first axially chiral selective Knoevenagel condensation using
cinchona alkaloid primary amine as the catalyst. This reaction provided
a powerful method to access enantioenriched olefins containing the
oxindole core. Subsequently, we initiated an intense program for the
computational investigation of the reaction mechanism of our atropselective
processes. An understanding of the catalytic activity for vinylogous
atropselect...
