124379-29-9Relevant articles and documents
Asymmetric hydrogenation of a 4,4-diaryl-3-butenoate; a novel approach to sertraline.
Boulton, Lee T,Lennon, Ian C,McCague, Raymond
, p. 1094 - 1096 (2003)
The asymmetric hydrogenation of a selectively crystallised (E)-4,4-diaryl-3-butenoate with a rhodium-PhanePhos catalyst is described, providing an intermediate to the antidepressant sertraline.
Copper-Catalyzed Enantioselective Arylation via Radical-Mediated C-C Bond Cleavage: Synthesis of Chiral ω,ω-Diaryl Alkyl Nitriles
Cui, Guo-Qing,Dai, Jing-Cheng,Li, Yan,Li, Yuan-Bo,Hu, Duo-Duo,Bian, Kang-Jie,Sheng, Jie,Wang, Xi-Sheng
supporting information, p. 7503 - 7507 (2021/10/02)
The first example of copper-catalyzed ring-opening, enantioselective arylation of cyclic ketoxime esters to access ω,ω-diaryl alkyl nitriles has been developed in high yield (up to 92% yield) with excellent enantioselectivity (up to 91% ee). Side-arm bis(oxazoline) ligand plays a significant role in this asymmetric catalytic transformation, which provides an efficient route to construct diverse chiral ω,ω-diaryl alkyl nitriles. Synthetic utility has also been demonstrated in the further derivatization of the ω,ω-diaryl alkyl nitrile to the corresponding amide.
Chemoenzymatic Synthesis of Sertraline
Marx, Lisa,Ríos-Lombardía, Nicolás,Süss, Philipp,H?hne, Matthias,Morís, Francisco,González-Sabín, Javier,Berglund, Per
, p. 510 - 513 (2020/01/25)
A chemoenzymatic approach has been developed for the preparation of sertraline, an established anti-depressant drug. Ketoreductases (KREDs) were employed to yield a key chiral precursor. The bioreduction of the racemic tetralone exhibited excellent enantioselectivity (>99 % ee) and diastereomeric ratio (99:1) at 29 % conversion (the maximum theoretical yield is 50 %) after 7 hours. The resulting (S,S)-alcohol was efficiently oxidized to an enantiopure (S)-ketone, an immediate precursor of sertraline, by using sodium hypochlorite as oxidant and 2-azaadamantane N-oxyl (AZADO) as organocatalyst. Alternative routes aiming at the direct biocatalytic amination using imine reductases and transaminases were unsuccessful.
Correction to: Nickel-catalyzed asymmetric reductive cross-coupling to access 1,1-diarylalkanes (Journal of the American Chemical Society (2017) 139 (5684-5687) DOI: 10.1021/jacs.7b01705)
Poremba, Kelsey E.,Kadunce, Nathaniel T.,Suzuki, Naoyuki,Cherney, Alan H.,Reisman, Sarah E.
supporting information, p. 7746 - 7746 (2018/06/26)
Pages 5684 and 5685, Table of Contents, and Supporting Information. The stereochemistry of L1, depicted as the (S,S)- enantiomer in Figure 1, Table 1, the TOC graphic (identical to Figure 1), and the Supporting Information of the original publication, was incorrect. (R,R)-L1 was used in this study. The stereochemistry of (R,R)-L1 has been confirmed by singlecrystal X-ray diffraction; the X-ray diffraction data and CIF file for (R,R)-L1 have been added to the Supporting Information. The corrected TOC graphic/Figure 1 is shown here. (R,R)-L4 and (R,R)-L5 were also used in Table 1 and incorrectly depicted as (S,S)-L4 and (S,S)-L5 in the original publication. To reflect that different enantiomeric series of catalysts were used, Table 1 has been updated to indicate that entries 2, 3, and 6 produce (S)-3a. This correction does not change the stereochemical assignment of the diarylalkane products, or the conclusions of the Communication. The stereochemistry of the products was assigned by obtaining an X-ray structure of diarylalkane 3k, and the rest of the compounds were assigned by analogy. (Table Presented).