4703-38-2Relevant articles and documents
Nickel-Catalyzed Multicomponent Coupling: Synthesis of α-Chiral Ketones by Reductive Hydrocarbonylation of Alkenes
Chen, Jian,Zhu, Shaolin
supporting information, p. 14089 - 14096 (2021/09/13)
A nickel-catalyzed, multicomponent regio- and enantioselective coupling via sequential hydroformylation and carbonylation from readily available starting materials has been developed. This modular multicomponent hydrofunctionalization strategy enables the straightforward reductive hydrocarbonylation of a broad range of unactivated alkenes to produce a wide variety of unsymmetrical dialkyl ketones bearing a functionalized α-stereocenter, including enantioenriched chiral α-aryl ketones and α-amino ketones. It uses chiral bisoxazoline as a ligand, silane as a reductant, chloroformate as a safe CO source, and a racemic secondary benzyl chloride or an N-hydroxyphthalimide (NHP) ester of a protected α-amino acid as the alkylation reagent. The benign nature of this process renders this method suitable for late-stage functionalization of complex molecules.
Methionine derivative and application thereof
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Paragraph 0057-0066, (2020/12/06)
The invention relates to the technical field of chemical synthesis, and particularly discloses a methionine derivative and application thereof. The structure of the methionine derivative is shown as aformula (I). The methionine derivative provided by the invention is used as an oxidizing agent to be applied to an oxidation system, hydroxyl of a reaction substrate is oxidized into corresponding aldehyde or ketone, and no peculiar smell substance is generated in the reaction process; the yield of a target product is guaranteed, meanwhile, the reaction temperature can be effectively increased, the oxidation reaction can be normally conducted at the temperature higher than 0 DEG C, and the yield is high; and the methionine derivative can be recycled many times, the cost is saved, energy is saved, consumption is reduced, and the methionine derivative is environmentally friendly.
Formation of Non-Natural α,α-Disubstituted Amino Esters via Catalytic Michael Addition
Teegardin, Kip A.,Gotcher, Lacey,Weaver, Jimmie D.
supporting information, p. 7239 - 7244 (2018/11/25)
The enolate monoanion of amino esters is explored, and the first catalytic Michael addition of α-amino esters is demonstrated. These studies indicate that the acidity of the αC-H is the primary factor determining reactivity. Thus, polyfluorophenylglycine amino esters yield novel α-amino esters in the presence of a catalytic amount of a guanidine-derived base and Michael acceptors. Reactivity requires an acidic N-H, which is accomplished using common protecting groups such as N-Bz, N-Boc, and N-Cbz. Calculations and labeling experiments provide insight into the governing principles in which a key C-to-N proton transfer occurs, resulting in an expansion of the scope to include a number of natural amino esters. The study culminates with a late-stage functionalization of peptidic γ-secretase inhibitor, DAPT.
