Your search keyword '"Zhihui Shao"' showing total 11 results

1. Enantioselective synthesis of chiral α,α-dialkyl indoles and related azoles by cobalt-catalyzed hydroalkylation and regioselectivity switch

Author

Jiangtao Ren, Zheng Sun, Shuang Zhao, Jinyuan Huang, Yukun Wang, Cheng Zhang, Jinhai Huang, Chenhao Zhang, Ruipu Zhang, Zhihan Zhang, Xu Ji, and Zhihui Shao

Subjects

Science

Abstract

Abstract General, catalytic and enantioselective construction of chiral α,α-dialkyl indoles represents an important yet challenging objective to be developed. Herein we describe a cobalt catalyzed enantioselective anti-Markovnikov alkene hydroalkylation via the remote stereocontrol for the synthesis of α,α-dialkyl indoles and other N-heterocycles. This asymmetric C(sp3)−C(sp3) coupling features high flexibility in introducing a diverse set of alkyl groups at the α-position of chiral N-heterocycles. The utility of this methodology has been demonstrated by late-stage functionalization of drug molecules, asymmetric synthesis of bioactive molecules, natural products and functional materials, and identification of a class of molecules exhibiting anti-apoptosis activities in UVB-irradiated HaCaT cells. Ligands play a vital role in controlling the reaction regioselectivity. Changing the ligand from bi-dentate L6 to tridentate L12 enables CoH-catalyzed Markovnikov hydroalkylation. Mechanistic studies disclose that the anti-Markovnikov hydroalkylation involves a migratory insertion process while the Markovnikov hydroalkylation involves a MHAT process.

Published

2024

2. Enantioselective synthesis of N-alkylindoles enabled by nickel-catalyzed C-C coupling

Author

Lun Li, Jiangtao Ren, Jingjie Zhou, Xiaomei Wu, Zhihui Shao, Xiaodong Yang, and Deyun Qian

Subjects

Science

Abstract

Enantioenriched N-alkylindole compounds, in which nitrogen is bound to a stereogenic sp3 carbon, are target molecules in the fields of biological, medicinal, and organic chemistry. Here the authors show a nickel-catalyzed C-C coupling protocol to synthesize these molecules from N-indolylsubstituted alkenes.

Published

2022

3. Direct access to spirocycles by Pd/WingPhos-catalyzed enantioselective cycloaddition of 1,3-enynes

Author

Long Li, Shan Wang, Pengfei Luo, Ran Wang, Zheng Wang, Xiaoguang Li, Yuhua Deng, Fangzhi Peng, and Zhihui Shao

Subjects

Science

Abstract

Spirocycles are traditionally difficult structures to synthesize due to the congested nature of the central atom. Here the authors show a method to synthesize quaternary carbon spirocycles in one step from 1,3-enynes and pyrazolidine-type heterocycles, both relatively unactivated structures, proceeding via palladium catalysis.

Published

2021

4. Direct asymmetric N-propargylation of indoles and carbazoles catalyzed by lithium SPINOL phosphate

Author

Yingcheng Wang, Sheng Wang, Wenyu Shan, and Zhihui Shao

Subjects

Science

Abstract

Asymmetric functionalization of N–H bonds constitutes an important but less developed class of reactions. Here, the authors report the asymmetric direct N-propargylation of indoles and carbazoles with a lithium SPINOL phosphate as the chiral catalyst and shed light on the reaction mechanism.

Published

2020

5. Reversible interconversion between methanol-diamine and diamide for hydrogen storage based on manganese catalyzed (de)hydrogenation

Author

Zhihui Shao, Yang Li, Chenguang Liu, Wenying Ai, Shu-Ping Luo, and Qiang Liu

Subjects

Science

Abstract

The development of cost-effective, sustainable, and efficient catalysts for liquid organic hydrogen carrier systems is a significant goal. Herein, authors present a system based on manganese catalysis with a theoretical H2 capacity of 5.3 wt% and high selectivity for the dehydrogenation reaction.

Published

2020

6. Enantiodivergence by minimal modification of an acyclic chiral secondary aminocatalyst

Author

Jun Dai, Zhuang Wang, Yuhua Deng, Lei Zhu, Fangzhi Peng, Yu Lan, and Zhihui Shao

Subjects

Science

Abstract

Enantiodivergent methods, which to access both enantiomers of the same compound, are of importance in drug synthesis. Here, the authors show that by simply changing a NiBu- to a NMe-group in readily available amine organocatalysts, high stereocontrol and broad scope are achieved in eight asymmetric reactions.

Published

2019

7. Direct access to spirocycles by Pd/WingPhos-catalyzed enantioselective cycloaddition of 1,3-enynes

Author

Zheng Wang, Zhihui Shao, Pengfei Luo, Long Li, Xiaoguang Li, Shan Wang, Fangzhi Peng, Yu-Hua Deng, and Ran Wang

Subjects

Science, General Physics and Astronomy, chemistry.chemical_element, Synthetic chemistry methodology, General Biochemistry, Genetics and Molecular Biology, Article, Catalysis, chemistry.chemical_compound, Nucleophile, Asymmetric catalysis, Multidisciplinary, Enyne, Cycloaddition Reaction, Molecular Structure, Enantioselective synthesis, Stereoisomerism, General Chemistry, Combinatorial chemistry, Cycloaddition, Allyl Compounds, chemistry, Organic synthesis, Stereoselectivity, Palladium

Abstract

Spirocycles play an important role in drug discovery and development. The direct, catalytic, and enantioselective synthesis of spirocycles from readily available starting materials and in an atom economic manner remains a highly sought-after task in organic synthesis. Herein, an enantioselective Pd-hydride-catalyzed cycloaddition method for the synthesis of spirocyclic compounds directly from two classes of commonly available starting materials, 1,3-enynes and cyclic carbon−hydrogen (C−H) bonds, is reported. The reactions employ a chiral Pd/WingPhos catalyst to both suppress the formation of bis-allenyl by-products and control the stereoselectivity. 1,3-Enynes are used as dielectrophilic four-carbon units in the cycloaddition reactions, which also enables an enyne substrate-directed enantioselectivity switch with good levels of stereocontrol. The present spirocycle synthesis tolerates a broad range of functional groups of 1,3-enyne substrates, including alcohols, esters, nitriles, halides, and olefins. A variety of diverse cyclic nucleophiles, including pharmaceutically important heterocycles and carbocycles, can be flexibly incorporated with spiro scaffolds., Spirocycles are traditionally difficult structures to synthesize due to the congested nature of the central atom. Here the authors show a method to synthesize quaternary carbon spirocycles in one step from 1,3-enynes and pyrazolidine-type heterocycles, both relatively unactivated structures, proceeding via palladium catalysis.

Published

2021

8. Direct asymmetric N-propargylation of indoles and carbazoles catalyzed by lithium SPINOL phosphate

Author

Sheng Wang, Zhihui Shao, Yingcheng Wang, and Wenyu Shan

Subjects

Reaction mechanism, Science, General Physics and Astronomy, chemistry.chemical_element, Synthetic chemistry methodology, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Catalysis, chemistry.chemical_compound, Asymmetric catalysis, lcsh:Science, Multidisciplinary, 010405 organic chemistry, Enantioselective synthesis, General Chemistry, Homogeneous catalysis, Phosphate, Alkali metal, Combinatorial chemistry, 0104 chemical sciences, chemistry, Reagent, Surface modification, Lithium, lcsh:Q

Abstract

Catalytic asymmetric functionalization of the N–H groups of indoles and carbazoles constitutes an important but less developed class of reactions. Herein, we describe a propargylation protocol involving the use of a lithium SPINOL phosphate as the chiral catalyst and our recently developed C-alkynyl N,O-acetals as propargylating reagents. The direct asymmetric N-propargylation of indoles and carbazoles provides hitherto inaccessible N-functionalized products. Notably, the efficiency of the system allows reactions to be run at a very low catalyst loading (as low as 0.1 mol%). Mechanistic information about the titled reaction is also disclosed. This study represents an advance in the direct asymmetric functionalization of the N–H bonds of indoles and carbazoles, and additionally expands on the application of chiral alkali metal salts of chiral phosphoric acids in asymmetric catalysis., Asymmetric functionalization of N–H bonds constitutes an important but less developed class of reactions. Here, the authors report the asymmetric direct N-propargylation of indoles and carbazoles with a lithium SPINOL phosphate as the chiral catalyst and shed light on the reaction mechanism.

Published

2020

9. Enantiodivergence by minimal modification of an acyclic chiral secondary aminocatalyst

Author

Fangzhi Peng, Zhuang Wang, Jun Dai, Yu-Hua Deng, Lei Zhu, Zhihui Shao, and Yu Lan

Subjects

Multidisciplinary, Organocatalysis, 010405 organic chemistry, Chemistry, Science, Absolute configuration, General Physics and Astronomy, General Chemistry, 010402 general chemistry, 01 natural sciences, Combinatorial chemistry, Article, General Biochemistry, Genetics and Molecular Biology, 0104 chemical sciences, Catalysis, Drug synthesis, Stereochemistry, Asymmetric catalysis, Bioorganic chemistry, lcsh:Q, Stereoselectivity, Amine gas treating, Enantiomer, lcsh:Science

Abstract

The development of enantiodivergent catalysis for the preparation of both enantiomers of a chiral compound is of importance in pharmaceutical and bioorganic chemistry. With the design of a class of reactive and stereoselective organocatalysts, acyclic chiral secondary amines, a method for achieving the enantiodivergence is developed simply by changing the secondary N-i-Bu- to N-Me-group within the catalyst architecture while maintaining the same absolute configuration of the catalysts, which modulates the catalyst conformation. This catalyst-controlled enantiodivergent method not only enables challenging asymmetric transformations to occur in an enantiodivergent manner but also features a high level of stereocontrol and broad scope that is demonstrated in eight different reactions (90 examples), all delivering both enantiomers of a range of structurally diverse products including hitherto less accessible, yet important, compounds in good yields with high stereoselectivities., Enantiodivergent methods, which to access both enantiomers of the same compound, are of importance in drug synthesis. Here, the authors show that by simply changing a NiBu- to a NMe-group in readily available amine organocatalysts, high stereocontrol and broad scope are achieved in eight asymmetric reactions.

Published

2019

10. Reversible interconversion between methanol-diamine and diamide for hydrogen storage based on manganese catalyzed (de)hydrogenation

Author

Yang Li, Qiang Liu, Wenying Ai, Zhihui Shao, Shu-Ping Luo, and Chenguang Liu

Subjects

Hydrogen, Science, General Physics and Astronomy, chemistry.chemical_element, Manganese, 010402 general chemistry, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Catalysis, Hydrogen storage, chemistry.chemical_compound, Dehydrogenation, lcsh:Science, Multidisciplinary, 010405 organic chemistry, Chemical hydrogen storage, General Chemistry, Homogeneous catalysis, Combinatorial chemistry, 0104 chemical sciences, Hydrogen carrier, chemistry, Organometallic chemistry, lcsh:Q, Methanol, Selectivity

Abstract

The development of cost-effective, sustainable, and efficient catalysts for liquid organic hydrogen carrier systems is a significant goal. However, all the reported liquid organic hydrogen carrier systems relied on the use of precious metal catalysts. Herein, a liquid organic hydrogen carrier system based on non-noble metal catalysis was established. The Mn-catalyzed dehydrogenative coupling of methanol and N,N’-dimethylethylenediamine to form N,N’-(ethane-1,2-diyl)bis(N-methylformamide), and the reverse hydrogenation reaction constitute a hydrogen storage system with a theoretical hydrogen capacity of 5.3 wt%. A rechargeable hydrogen storage could be achieved by a subsequent hydrogenation of the resulting dehydrogenation mixture to regenerate the H2-rich compound. The maximum selectivity for the dehydrogenative amide formation was 97%., The development of cost-effective, sustainable, and efficient catalysts for liquid organic hydrogen carrier systems is a significant goal. Herein, authors present a system based on manganese catalysis with a theoretical H2 capacity of 5.3 wt% and high selectivity for the dehydrogenation reaction.

Published

2019

11. Asymmetric synthesis of syn-propargylamines and unsaturated β-amino acids under Brønsted base catalysis

Author

Chao Zheng, Zhihui Shao, Kongxi Zhu, Yingcheng Wang, Hongbin Zhang, Mingjie Mo, and Wei Wang

Subjects

Multidisciplinary, Molecular Structure, Propylamines, Chemistry, Enantioselective synthesis, General Physics and Astronomy, Thio, General Chemistry, Combinatorial chemistry, General Biochemistry, Genetics and Molecular Biology, Article, Catalysis, Stereocenter, chemistry.chemical_compound, Malonate, Nucleophile, Biochemistry, Amino Acids, Brønsted–Lowry acid–base theory, Mannich reaction

Abstract

Propargylamines are important intermediates for the synthesis of polyfunctional amino derivatives and natural products and biologically active compounds. The classic method of synthesizing chiral propargylamines involves the asymmetric alkynylation of imines. Here, we report a significant advance in the catalytic asymmetric Mannich-type synthesis of propargylamines through catalytic asymmetric addition of carbon nucleophiles to C-alkynyl imines, culminating in a highly syn-selective catalytic asymmetric Mannich reaction of C-alkynyl imines that provide syn-configured propargylamines with two adjacent stereogenic centres and a transition metal-free organocatalytic asymmetric approach to β-alkynyl-β-amino acids with high efficiency and practicality, via a chiral Brønsted base-catalysed asymmetric Mannich-type reaction of in situ generated challenging N-Boc C-alkynyl imines from previously unreported C-alkynyl N-Boc-N,O-acetals, with α-substituted β-keto esters and less-acidic malonate (thio)esters as nucleophiles, respectively. A catalytic activation strategy is also disclosed, which may have broad implications for use in catalysis and synthesis., Propargylamines are of interest both as biologically active compounds and versatile synthetic intermediates. Here, the authors report a method for the organocatalytic asymmetric synthesis of propargylamines through addition of carbon nucleophiles to alkynyl imines.

Published

2015