10420-89-0Relevant articles and documents
Asymmetric Supported Reactions: Synthesis Of Chiral Amines
Calmes, Monique,Daunis, Jacques,Hanouneh, Ahmad,Jacquier, Robert
, p. 817 - 820 (1994)
Deracemization of amines, linked via Schiff bases to a chiral polyacrylic polymer has been studied.An enantiomeric excess of 72percent has been obtained with α-methyl benzylamine.
Biocatalytic transamination with near-stoichiometric inexpensive amine donors mediated by bifunctional mono- and di-amine transaminases
Galman, James L.,Slabu, Iustina,Weise, Nicholas J.,Iglesias, Cesar,Parmeggiani, Fabio,Lloyd, Richard C.,Turner, Nicholas J.
, p. 361 - 366 (2017)
The discovery and characterisation of enzymes with both monoamine and diamine transaminase activity is reported, allowing conversion of a wide range of target ketone substrates with just a small excess of amine donor. The diamine co-substrates (putrescine, cadaverine or spermidine) are bio-derived and the enzyme system results in very little waste, making it a greener strategy for the production of valuable amine fine chemicals and pharmaceuticals.
Nonenzymatic kinetic resolution of amines in ionic liquids
Sabot, Cyrille,Subhash, Pithani V.,Valleix, Alain,Arseniyadis, Stellios,Mioskowski, Charles
, p. 268 - 272 (2008)
Ionic liquids are remarkably suitable and clean media for performing nonenzymatic kinetic resolution (KR) of amines through enantioselective N-acetylation: high levels of selectivity were obtained with a large variety of amines at room temperature (up to s = 30). Georg Thieme Verlag Stuttgart.
n-Butylamine as an alternative amine donor for the stereoselective biocatalytic transamination of ketones
Slabu, Iustina,Galman, James L.,Iglesias, Cesar,Weise, Nicholas J.,Lloyd, Richard C.,Turner, Nicholas J.
, p. 96 - 101 (2018)
Formal reductive amination has been a main focus of biocatalysis research in recent times. Among the enzymes able to perform this transformation, pyridoxal-5′-phosphate-dependent transaminases have shown the greatest promise in terms of extensive substrate scope and industrial application. Despite concerted research efforts in this area, there exist relatively few options regarding efficient amino donor co-substrates capable of allowing high conversion and atom efficiency with stable enzyme systems. Herein we describe the implementation of the recently described spuC gene, coding for a putrescine transaminase, exploiting its unusual amine donor tolerance to allow use of inexpensive and readily-available n-butylamine as an alternative to traditional methods. Via the integration of SpuC homologues with tandem co-product removal and cofactor regeneration enzymes, high conversion could be achieved with just 1.5 equivalents of the amine with products displaying excellent enantiopurity.
Efficient kinetic resolution of racemic amines using a transaminase in combination with an amino acid oxidase
Truppo, Matthew D.,Turner, Nicholas J.,Rozzell, J. David
, p. 2127 - 2129 (2009)
A range of enantiomerically pure (R)- and (S)-configured chiral amines has been prepared in excellent e.e. (99%) by combining a transaminase enzyme with an amino acid oxidase and catalytic quantities of pyruvate.
6-TIPS-β-Cyclodextrin-Modified Fe3O4 for Facile Enantioseparation of 1-(1-Naphthyl)ethylamine
Wang, Lu,Liang, Xiang-Yong,Ding, Li-Sheng,Zhang, Sheng,Li, Bang-Jing
, p. 3513 - 3519 (2016)
A new type of chiral magnetic nanoparticle was prepared from covalently linked magnetic nanoparticles (Fe3O4) and heptakis-(6-O-triisopropylsilyl)-β-cyclodextrin (6-TIPS-β-CD). The resulting selectors (TIPS-β-CD-MNPs) combined the good magnetic properties Fe3O4 and efficient chiral recognition ability of 6-TIPS-β-CD. The enantioselectivity of TIPS-β-CD-MNPs towards 1-(1-naphthyl)ethylamine was six times higher than that of the parent β-CD modified Fe3O4 particles.
A METHOD FOR PREPARATION OF DIASTEREOMERIC LACTATE SALTS OF 1-(1-NAPHTHYL)ETHYL AMINE AND PURE ENANTIOMERS OF 1-(1-NAPHTHYL)ETHYL AMINE
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Paragraph 0051, (2021/09/11)
The invention relates to method for preparation of pure enantiomers of 1-(1-naphthyl)ethyl amine by preparing lactate salt with chiral lactic acid as resolving agent. The method comprises reaction of L-lactic acid or D-lactic acid with racemic 1-(1-naphthyl)ethyl amine to form diastereomeric salts of (R/S)-1-(1-naphthyl)ethyl amine-(D/L)-lactate from which pure enantiomer is isolated. The invention also comprises method for preparation of compound with enriched enantiomers of 1-(1-naphthyl)ethyl amine from the mother liquor separated from the diastereomeric lactate salt. The enriched enantiomer is reacted with pure enantiomers of mandelic acid or lactic acid, preferably D-mandelic acid or L-mandelic acid and converted to diastereomeric mandelate salt. Pure (R)- or (S)-1-(1-naphthyl)ethyl amine is obtained from the diastereomeric mandelate salt. The chiral purity of pure enantiomer obtained is between 99% and 100%.
Method for asymmetrically synthesizing (R)-cinacalcet
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Paragraph 0036-0038, (2019/03/28)
The invention discloses a new method for asymmetrically synthesizing (R)-cinacalcet. The method includes: taking racemic 2-bromo-propionic acid (4-methoxybenzyl) ester as a starting raw material, andbeing in asymmetric Negishi cross coupling reaction with 2-nathphyl zinc bromide under catalysis of CoI2 and chiral ligand to generate (R)-2-(1-nathphyl) propionic acid (4-methoxybenzyl) ester; beingin reaction with oxalyl chloride through LiOH reduction to generate (R)-2-(1-nathphyl) propionyl chloride; being reaction with ammonia water to generate (R)-2-(1-nathphyl) propionamide, and allowing Hofmann degradation to obtain (R)-1-nathphalene ethylamine; being in reaction with 3-(trifluoromethyl) phenylpropionic acid to generate (R)-N-(1-nathphalene ethyl)-3-(3-trifluoromethylphenyl) propionamide, and allowing LiAlH4 reduction to obtain (R)-cinacalcet. Cobalt catalyzed asymmetric Negishi cross coupling reaction is utilized for the first time to build the chiral center of (R)-cinacalcet, the method is mild in reaction condition and environment-friendly, and optical purity of (R)-cinacalcet is high (99%ee).