221054-79-1Relevant articles and documents
Isolation and characterization of a novel equol-producing bacterium from human feces
Yokoyama, Shin-Ichiro,Suzuki, Tohru
, p. 2660 - 2666 (2008)
An equol-producing bacterium was newly isolated from the feces of healthy humans and its morphological and biochemical properties were characterized. The cells were obligate anaerobes. They were non-sporulating, non-motile, gram-positive bacilliform bacteria with a pleomorphic morphology. The strain was catalase-positive, and oxidase-, urease-, and indole-negative. The only other sugar utilized by the strain was glycerin. The strain also degraded gelatin, but not esculin. It was most closely related to Eggerthella hongkongensis HKU10, with 93.3% 16S rDNA nucleotide sequence homology. Based on these features, the isolate was identified as a novel species of the genus Eggerthella. It was named Eggerthella sp. YY7918. Strain YY7918 converted substrates daidzein and dihydrodaidzein into S-equol, but did not convert daidzin, glysitein, genistein, or formononetin into it. An antimicrobial susceptibility assay indicated that strain YY7918 was susceptible to aminoglycoside-, tetracycline-, and new quinolone-antibiotics.
A Concise Enantiodivergent Synthesis of Equol
Uemura, Takahito,Saito, Yusuke,Sonoda, Motohiro,Tanimori, Shinji
, p. 693 - 696 (2020/12/23)
Equol, a nonsteroidal estrogen produced from the metabolism of the isoflavonoid phytoestrogen daidzein, has been synthesized as both enantioenriched forms based on MacMillan's α-Arylation of carbonyl compound mediated by amino acid derived indazolidinones and copper precatalysts. The natural form of (S)-equol and its enantiomer (R)-equol have been synthesized in 8 steps from 2,4-dimethoxybenzaldehyde with good enantiomeric purity (90% ee and 90% ee, respectively).
Method for preparing equol
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, (2020/01/08)
The invention relates to a method for preparing equol. The method comprises the following steps: S1, synthesizing benzohydropyran: namely weighing daidzein raw materials, dissolving the daidzein raw materials in dimethyl formamide (DMF), adding palladium carbon into a hydrogenation kettle, carrying out reacting at a same speed under constant temperature and constant pressure, filtering out the catalyst, adding ice water into the filtrate, carrying out stirring to separate out white solid, and carrying out filtering, water washing and drying to obtain an intermediate a; S2, synthesizing a condensate: namely adding the intermediate a, dichloroethane and polyphosphoric acid into a three-mouth bottle, carrying out a reflux reaction, carrying out cooling, adding the obtained substance into icewater, taking an organic phase by layering, carrying out drying with sodium sulfate, concentrating dichloroethane to obtain a yellow oily substance, and carrying out recrystallizing with 90% ethanol water to obtain an intermediate b; and S3, synthesizing equol: namely adding the intermediate b, DMF and a catalyst into a hydrogenation kettle, filtering out the catalyst after a reaction at constanttemperature and constant pressure, adding the filtrate into ice water, carrying out stirring to separate out a gray solid, carrying out filtering, and recrystallizing the filter cake with 70% methanolwater to obtain the equol. The method has the advantages of simple steps, high total yield, environmental protection and easy operation.
Enantioselective Total Synthesis of Natural Isoflavans: Asymmetric Transfer Hydrogenation/Deoxygenation of Isoflavanones with Dynamic Kinetic Resolution
Ke?berg, Anton,Lübken, Tilo,Metz, Peter
supporting information, p. 3006 - 3009 (2018/05/28)
A concise and highly enantioselective synthesis of structurally diverse isoflavans from a single chromone is described. The key transformation is a single-step conversion of racemic isoflavanones into virtually enantiopure isoflavans by domino asymmetric transfer hydrogenation/deoxygenation with dynamic kinetic resolution.
