“On‐Water” Palladium‐Catalyzed Tandem Cyclization Reaction for the Synthesis of Biologically Relevant 4‐Arylquinazolines

The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient “on‐water” palladium‐catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access...

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Published inChemistry : a European journal Vol. 25; no. 57; pp. 13109 - 13113
Main Authors Yuan, Shuo, Yu, Bin, Liu, Hong‐Min
Format Journal Article
LanguageEnglish
Published WEINHEIM Wiley 11.10.2019
Wiley Subscription Services, Inc
Subjects
cascade reactions
catalysis
Chemical synthesis
Chemistry
Chemistry, Multidisciplinary
Functional groups
on-water synthesis
Palladium
Physical Sciences
quinazolines
Scaffolds
Science & Technology
Substrates
DOMAIN
ANNULATION
on-water synthesis
OXIDATIVE DECARBOXYLATIVE AMINATION
catalysis
CASCADE
QUINAZOLINE DERIVATIVES
DISCOVERY
cascade reactions
POTENT
CHEMISTRY
palladium
INHIBITORS
quinazolines
SPIRO
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Abstract The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient “on‐water” palladium‐catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access to 4‐arylquinazoline scaffolds in good to excellent yields (45 examples, up to 98 % yield). This protocol has shown good functional group tolerance and broad substrate scope. The reaction was also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11, showing the practicability and synthetic utility of the protocol. In this reaction, the quinazoline scaffold is efficiently constructed with the simultaneous formation of one C−C bond and one C−N bond. Collectively, the protocol could serve as an alternative strategy to synthesize biologically important quinazoline scaffolds. Better “on water”: An efficient palladium‐catalyzed tandem cyclization reaction from readily available arylboronic acids and benzonitriles on water has been developed to offer a rapid access to the quinazoline scaffolds in good to excellent yields (up to 98 % yield). This protocol is also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11.
AbstractList The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient “on‐water” palladium‐catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access to 4‐arylquinazoline scaffolds in good to excellent yields (45 examples, up to 98 % yield). This protocol has shown good functional group tolerance and broad substrate scope. The reaction was also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11, showing the practicability and synthetic utility of the protocol. In this reaction, the quinazoline scaffold is efficiently constructed with the simultaneous formation of one C−C bond and one C−N bond. Collectively, the protocol could serve as an alternative strategy to synthesize biologically important quinazoline scaffolds.
The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient "on-water" palladium-catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access to 4-arylquinazoline scaffolds in good to excellent yields (45 examples, up to 98 % yield). This protocol has shown good functional group tolerance and broad substrate scope. The reaction was also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3K delta inhibitor N11, showing the practicability and synthetic utility of the protocol. In this reaction, the quinazoline scaffold is efficiently constructed with the simultaneous formation of one C-C bond and one C-N bond. Collectively, the protocol could serve as an alternative strategy to synthesize biologically important quinazoline scaffolds.
The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient "on-water" palladium-catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access to 4-arylquinazoline scaffolds in good to excellent yields (45 examples, up to 98 % yield). This protocol has shown good functional group tolerance and broad substrate scope. The reaction was also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11, showing the practicability and synthetic utility of the protocol. In this reaction, the quinazoline scaffold is efficiently constructed with the simultaneous formation of one C-C bond and one C-N bond. Collectively, the protocol could serve as an alternative strategy to synthesize biologically important quinazoline scaffolds.The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient "on-water" palladium-catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access to 4-arylquinazoline scaffolds in good to excellent yields (45 examples, up to 98 % yield). This protocol has shown good functional group tolerance and broad substrate scope. The reaction was also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11, showing the practicability and synthetic utility of the protocol. In this reaction, the quinazoline scaffold is efficiently constructed with the simultaneous formation of one C-C bond and one C-N bond. Collectively, the protocol could serve as an alternative strategy to synthesize biologically important quinazoline scaffolds.
The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient “on‐water” palladium‐catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access to 4‐arylquinazoline scaffolds in good to excellent yields (45 examples, up to 98 % yield). This protocol has shown good functional group tolerance and broad substrate scope. The reaction was also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11, showing the practicability and synthetic utility of the protocol. In this reaction, the quinazoline scaffold is efficiently constructed with the simultaneous formation of one C−C bond and one C−N bond. Collectively, the protocol could serve as an alternative strategy to synthesize biologically important quinazoline scaffolds. Better “on water”: An efficient palladium‐catalyzed tandem cyclization reaction from readily available arylboronic acids and benzonitriles on water has been developed to offer a rapid access to the quinazoline scaffolds in good to excellent yields (up to 98 % yield). This protocol is also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11.
The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient "on-water" palladium-catalyzed tandem cyclization reaction from commercially available arylboronic acids and benzonitriles that enable the rapid access to 4-arylquinazoline scaffolds in good to excellent yields (45 examples, up to 98 % yield). This protocol has shown good functional group tolerance and broad substrate scope. The reaction was also performed on a gram scale and successfully applied to the synthesis of the highly potent and selective PI3Kδ inhibitor N11, showing the practicability and synthetic utility of the protocol. In this reaction, the quinazoline scaffold is efficiently constructed with the simultaneous formation of one C-C bond and one C-N bond. Collectively, the protocol could serve as an alternative strategy to synthesize biologically important quinazoline scaffolds.
Author Liu, Hong‐Min
Yuan, Shuo
Yu, Bin
Author_xml – sequence: 1
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  surname: Yuan
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  surname: Yu
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  email: liuhm@zzu.edu.cn
  organization: Zhengzhou University
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Issue 57
Keywords DOMAIN
ANNULATION
on-water synthesis
OXIDATIVE DECARBOXYLATIVE AMINATION
catalysis
CASCADE
QUINAZOLINE DERIVATIVES
DISCOVERY
cascade reactions
POTENT
CHEMISTRY
palladium
INHIBITORS
quinazolines
SPIRO
Language English
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Snippet The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient “on‐water”...
The quinazoline scaffold is prevalent in pharmaceutically relevant molecules that show diverse biological activities. Herein, we report an efficient "on-water"...
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SubjectTerms cascade reactions
catalysis
Chemical synthesis
Chemistry
Chemistry, Multidisciplinary
Functional groups
on-water synthesis
Palladium
Physical Sciences
quinazolines
Scaffolds
Science & Technology
Substrates
Title “On‐Water” Palladium‐Catalyzed Tandem Cyclization Reaction for the Synthesis of Biologically Relevant 4‐Arylquinazolines
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fchem.201903464
http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=Summon&SrcAuth=ProQuest&DestApp=WOS&DestLinkType=FullRecord&UT=000486899000001
https://www.ncbi.nlm.nih.gov/pubmed/31433086
https://www.proquest.com/docview/2304948088
https://www.proquest.com/docview/2293971098
Volume 25
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