The
asymmetric functionalization of C–H is one of the most
attractive strategies in asymmetric synthesis. In the past decades,
catalytic enantioselective C(sp3)–H functionalization
has been intensively studied and successfully applied in various asymmetric
bond formations, whereas asymmetric C(sp3)–H alkylation
was not well developed. Photoredox catalysis has recently emerged
as an efficient way to synthesize organic compounds under mild conditions.
Despite many photoinduced stereoselective reactions that have been
achieved, the related enantioselective C(sp3)–C(sp3) coupling is challenging, especially of the photocatalytic
asymmetric C(sp3)–H radical alkylation. Here, we
report a visible light induced Cu catalyzed asymmetric sp
3 C–H alkylation, which is effective for coupling
with unbiased primary, secondary, and tertiary alkyl fragments in
high enantioselectivities. This reaction would provide a new approach
for the synthesis of important molecules such as unnatural α-amino
acids and late-stage functionalization of bioactive compounds, and
will be useful for modern peptide synthesis and drug discovery.
The C-N cross coupling reaction has always been a fundamental task in organic synthesis. However, the direct use of N-H group of aryl amines to generate N-centered radicals which would couple with alkyl radicals to construct C-N bonds is still rare. Here we report a visible light-promoted C-N radical cross coupling for regioselective amination of remote C(sp3)-H bonds. Under visible light irradiation, the N-H groups of aryl amines are converted to N-centered radicals, and are then trapped by alkyl radicals, which are generated from Hofmann-Löffler-Freytag (HLF) type 1,5-hydrogen atom transfer (1,5-HAT). With the same strategy, the regioselective C(sp3)-C(sp3) cross coupling is also realized by using alkyl Hantzsch esters (or nitrile) as radical alkylation reagents. Notably, the α-C(sp3)-H of tertiary amines can be directly alkylated to form the C(sp3)-C(sp3) bonds via C(sp3)-H − C(sp3)-H cross coupling through the same photoredox pathway.
The visible light induced, photocatalysts or photoabsorbing EDA complexes mediated cleavage of pyridinium C-N bond were reported in the past years. Here, we report an ionic compound promote homolytic cleavage of pyridinium C-N bond by exploiting the photonic energy from visible light. This finding is successfully applied in deaminative hydroalkylation of a series of alkenes including naturally occurring dehydroalanine, which provides an efficient way to prepare β-alkyl substituted unnatural amino acids under mild and photocatalyst-free conditions. Importantly, by using this protocol, the deaminative cyclization of peptide backbone N-terminals is realized. Furthermore, the use of Et3N or PPh3 as reductants and H2O as hydrogen atom source is a practical advantage. We anticipate that our protocol will be useful in peptide synthesis and modern peptide drug discovery.
Hypervalent iodine
catalyst-catalyzed nucleophilic fluorination
of unsaturated amides using BF
3
·Et
2
O as
the fluorine source and activating reagent was reported. Various 5-fluoro-2-oxazoline
derivatives were synthesized in good to excellent yields (up to 95%
isolated yield) within 10 min. The process was efficient and metal-free
under mild conditions. A mechanism involving a fluorination/1,2-aryl
migration/cyclization cascade was proposed on the basis of previous
work and experimental results.
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