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Enantiopure Triazolium Salts: Chemoenzymatic Synthesis and Applications in Organocatalysis

Author:
Ríos Lombardía, NicolásUniovi authority; Porcar García, Raúl; Busto García, Benjamín EduardoUniovi authority; Alfonso Rodríguez, IgnacioUniovi authority; Montejo Bernardo, José ManuelUniovi authority; García-Granda, SantiagoUniovi authority; Gotor Santamaría, Vicente MiguelUniovi authority; Luis Lafuente, Santiago Vicente; García Verdugo, Eduardo; Gotor Fernández, VicenteUniovi authority
Subject:

Asymmetric Synthesis; Biocatalysis; Chirality; Organocatalysis; Triazole

Publication date:
2011
Publisher version:
http://dx.doi.org/10.1002/cctc.201100218
Citación:
Chemoenzymatic Synthesis and Applications in Organocatalysis. ChemCatChem, 3(12), p. 1921–1928 (2011); doi:10.1002/cctc.201100218
Abstract:

A novel family of triazolium salt enantiomers has been efficiently synthesized by combining chemical and biocatalytic methods. The stereoselective action shown by hydrolytic enzymes led to the design of simple and general chemoenzymatic routes in which tunable vectors, such as ring size, substituent stereochemistry, oxygen substitution, anion nature, or N4-triazole alkylating chain, were considered to produce 30 enantiopure triazolium salts in very high overall yields. Finally, selected triazolium salts were tested as phase-transfer catalysts in the asymmetric Michael addition of diethyl malonate to trans-chalcone to rationalize their activity and stereopreference. Low to complete conversion values were achieved in the formation of the Michael addition adduct, which mainly gave low levels of stereoselectivity depending on the different structural patterns considered in this systematic study.

A novel family of triazolium salt enantiomers has been efficiently synthesized by combining chemical and biocatalytic methods. The stereoselective action shown by hydrolytic enzymes led to the design of simple and general chemoenzymatic routes in which tunable vectors, such as ring size, substituent stereochemistry, oxygen substitution, anion nature, or N4-triazole alkylating chain, were considered to produce 30 enantiopure triazolium salts in very high overall yields. Finally, selected triazolium salts were tested as phase-transfer catalysts in the asymmetric Michael addition of diethyl malonate to trans-chalcone to rationalize their activity and stereopreference. Low to complete conversion values were achieved in the formation of the Michael addition adduct, which mainly gave low levels of stereoselectivity depending on the different structural patterns considered in this systematic study.

URI:
http://hdl.handle.net/10651/8463
ISSN:
1867-3899
Identificador local:

20110753

DOI:
10.1002/cctc.201100218
Patrocinado por:

Ministerio de Ciencia e Innovación. Grant Numbers: MICINN CTQ2007-61126, CTQ2008-04412, CTQ2008-04309, CTQ2009-14366-C02. UJI-BANCAIXA. Grant Number: P1-1A2009-58. MICINN. FICYT.

Id. Proyecto:

MICINN/CTQ2007-61126

MICINN/CTQ2008-04412

MICINN/CTQ2008-04309

MICINN/CTQ2009-14366-C02

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