Aromatic hydrocarbons are some of the most elementary feedstock chemicals, produced annually on a million metric ton scale, and are used in the production of polymers, paints, agrochemicals and pharmaceuticals. Dearomatization reactions convert simple, readily available arenes into more complex molecules with broader potential utility, however, despite substantial progress and achievements in this field, there are relatively few methods for the dearomatization of simple arenes that also selectively introduce functionality. Here we describe a new dearomatization process that involves visible-light activation of small heteroatom-containing organic molecules—arenophiles—that results in their para-cycloaddition with a variety of aromatic compounds. The approach uses N–N-arenophiles to enable dearomative dihydroxylation and diaminodihydroxylation of simple arenes. This strategy provides direct and selective access to highly functionalized cyclohexenes and cyclohexadienes and is orthogonal to existing chemical and biological dearomatization processes. Finally, we demonstrate the synthetic utility of this strategy with the concise synthesis of several biologically active compounds and natural products.
Vinyl azides are highly versatile synthons that provide access to numerous N-heterocycles and other functional groups. α-Substituted vinyl azides (azido vinylidenes) are a special class that display unique reactivity, able to react not only as azides, but also as radical acceptors, enamine-type nucleophiles, and even electrophiles, thus delivering a wide range of nitrogen-containing compounds and their derivatives. An impressive variety of intermediates - such as iminodiazonium ions, nitrilium ions, iminyl radicals, and metal enaminyl radicals - can be generated from vinyl azides and exploited in cycloadditions, C-H functionalizations, hydrolysis processes, and cascade reactions under transition metal/photoredox catalysis. In addition to presenting synthetic protocols to access vinyl azides, this Review offers a comprehensive coverage of the development of their multifaceted reactivity, and highlights their potential as versatile precursors for synthetic applications.
A diverse
collection of copper-catalyzed intermolecular aminative
difunctionalizations of unactivated alkenes with N-halodialkylamines as the terminal dialkylamino source is reported.
A bidentate auxiliary tethered on the alkene substrates is crucial,
which can promote the migratory insertion of nonactivated alkenes
into the aminyl radical–metal complex and stabilize the resultant
high-valent copper intermediate to allow for further transformations.
By employing this strategy, the intermolecular aminohalogenation reactions
and a three-component aminoazidation reaction of unactivated alkenes
with dialkylamino source were successively achieved in a remarkable
regio- and stereoselective manner. These reactions were performed
under neutral conditions and maintained excellent functional group
tolerance toward a wide range of N-halodialkylamines
and unactivated alkenes. Further mechanistic studies and DFT calculations
supported a concerted migratory insertion of the C–C double
bond into the aminyl radical–metal complex to form a Cu(III)
intermediate.
A new
type of intermolecular alkylative olefination of unactivated
olefins and alkyl halides has been realized for the first time. This
copper-promoted Heck-type reaction employs a directing-group strategy
to efficiently produce the coupled alkyl olefin products with excellent
regio- and stereoselectivity. A broad substrate scope including 1°,
2°, and 3° alkyl bromides and various nonactivated alkenes
could be well tolerated. DFT calculations disclosed a dimethyl sulfoxide
assisted concerted H–Br elimination process of a conformationally
strained Cu(III) cyclic transition state.
“Diazo” not needed: The title reaction results in the rearrangement of oxonium ylides, which were prepared from readily available homopropargylic allylic ethers instead of diazo compounds, through two different mechanisms: a concerted 2,3‐sigmatropic rearrangement, or a stepwise 1,4‐allyl migration followed by a Claisen rearrangement (see scheme).
A 4-substituted-1-tosyl-1,2,3-triazole-based stereoselective synthesis of structurally diverse oxaspirocycles is reported. The synthesis involves Rh-catalyzed loss of nitrogen from 4-substituted-1-tosyl-1,2,3-triazoles, Grignard reaction, and a ring-closing metathesis reaction as key steps. By employing readily available and stable 4-substituted-1-tosyl-1,2,3-triazoles as surrogates of diazo compounds and nitrogen sources, two types of oxaspirocycles were obtained. The latter compounds, which contain adjacent nitrogen stereocenters, could serve as the core structures of many natural products. This chemistry has been successfully applied to the total syntheses of (±)-tuberostemospiroline and (±)-stemona-lactam R.
Two novel rhodium(II)-catalyzed tandem reactions were developed for the synthesis of dihydroisobenzofuran and indanone derivatives from 2-triazole-benzaldehydes and 2-triazole-alkylaryl ketones. Dihydroisobenzofuran derivatives were obtained in good yields with high regioselectivities when alcohols were used as nuclophiles in these reactions, whereas the replacement of the alcohol with water resulted in the diastereoselective formation of highly functionalized indanone derivatives.
The development of an efficient diastereoselective synthesis of the oxabicyclo[3.2.1]octane ring system bearing two oxygenated quaternary chiral centres represents a significant challenge. This motif can be found in a wide range of natural products with significant biological activities. Here we report the synthesis of such kind of scaffold using a cyclohexane-trans-1,4-diol with an alkyne side chain in the presence of Au(I) catalyst. This is a domino process in which two C–H, two C–O and one C–C bond is assembled through a sequence of cyclization/semi-pinacol rearrangements. This strategy has been successfully applied to the asymmetric formal total synthesis of (+)-cortistatins.
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