P-Cl acetophenone

Using isolated enzymes instead of whole cells, similar problems are to be considered only in a few cases. ADH from Thermoanaerobium brockii shows varying enantiomeric excess of the product depending on the structure of the ketone to be reduced. Conversions with this enzyme yield in products with low (20% for the reduction of acetophenone) or high ee value (100% for the reduction of p-Cl-acetophenone). Predictions about the stereospecificity of HLADH catalyzed reductions can be made for simple acyclic substrates applying Prelog s rule [37] and for more complex compounds using the cubic-space model developed by Jones and Jakovac [38],... 

Table 4. Purification of (S)-ADH from Rhodococcus erythropolis DSM 43 297 (1 U = reduction of 1 pmol p-Cl-acetophenone per min HIC = hydrophobic interaction chromatography Prep-Cell = preparative gel electrophoresis)...

Ary] 2-amino-5-(p-aminophenyl)thia2oles of the general formula 116 were prepared by condensing phenylthiosemicarbazides (115) with either w-bromoacetophenone by refluxing in alcohol for 2 hr (Method A) or with acetophenones and iodine on a steam bath for 8 hr (Method B) Scheme 53 (517), with R = para Me, MeO, Cl, Br, I, NOj, NHj, Ph ortho Me, NOjl or meta Br, I, NO. Yields ranged from 55 to 90% from Method A and 40 to 70% from Method B. 

Various 4-, 5-, or 4,5-disubstituted 2-aryIamino thiazoles (124), R, = QH4R with R = 0-, m-, or p-Me, HO C, Cl, Br, H N, NHAc, NR2, OH, OR, or OjN, were obtained by condensing the corresponding N-arylthiourea with chloroacetone (81, 86, 423), dichloroacetone (510, 618), phenacyichloride or its p-substituted methyl, f-butyl, n-dodecyl or undecyl (653), or 2-chlorocyclohexanone (653) (Method A) or with 2-butanone (423), acetophenone or its p-substituted derivatives (399, 439), ethyl acetate (400), ethyl acetyl propionate (621), a- or 3-unsaturated ketones (691), benzylidene acetone, furfurylidene acetone, and mesityl oxide in the presence of Btj or Ij as condensing agent (Method B) (Table 11-17). 

If, on the other hand, unsymmetrically substituted carbonyl compounds such as monosubstituted benzophenones (X = OCH3, CH3, Cl), tert-butyl methyl ketone, acetophenone, acetaldehyde, or benzaldehyde are used for trapping 39a, diastere-omeric mixtures are formed in each case they could all be resolved except for the products obtained with p-methoxybenzophenone and acetophenone 33>. An X-ray structure analysis has been performed for the E-isomer 57g 36) which, in conjunction with H-NMR studies, permitted structural assignment in cases 56 and 57e, g and h35>. Additional chemical evidence for the structure of the six-membered heterocycles is provided by the thermolysis of 56 a considered in another context (see Sect. 3.1). In general the reaction 39a- 56 or 57 is accompanied by formation of phosphene dimers, presumably via [4 + 4]- and via [4 + 2]-cycloaddition 35). 

Sinou and coworkers evaluated a range of enantiopure amino alcohols derived from tartaric acid for the ATH reduction of prochiral ketones. Various (2R,iR)-i-amino- and (alkylamino)-l,4-bis(benzyloxy)butan-2-ol were obtained from readily available (-I-)-diethyl tartrate. These enantiopure amino alcohols have been used with Ru(p-cymene)Cl2 or Ir(l) precursors as ligands in the hydrogen transfer reduction of various aryl alkyl ketones ee-values of up to 80% have been obtained using the ruthenium complex [93]. Using (2R,3R)-3-amino-l,4-bis(benzyloxy)butan-2-ol and (2R,3R)-3-(benzylamino)-l,4-bis(benzyloxy)butan-2-ol with [lr(cod)Cl]2 as precursor, the ATH of acetophenone resulted in a maximum yield of 72%, 30% ee, 3h, 25 °C in PrOH/KOH with the former, and 88% yield, 28% ee, 120 h with the latter. 

The hydrogen-transfer reduction of acetophenone under FBS conditions was also readily achieved in the presence of fluorous chiral diamines, diimines and (3-amino alcohols derived from tartaric acid (e.g. 18-20 Scheme 5.5) in combination with [Ir(COD)Cl]2 or Rii(p-cyrricri(jCJJ, [42], but much lower enantioselectivities (up to 31% ee in the case of 18/[Ir(COD)Cl]2) were obtained. 

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