- AraBOX and XyliBOX based catalysts for cyclopropanations, Diels Alder cycloadditions and allylic additions
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The syntheses of three novel chiral 4,4′BOX ligands are described. The three ligands each have a chiral backbone and chiral sidearms, two of which are diastereomeric. These new ligands have been applied as copper complexes to asymmetric cyclopropanation r
- Kellehan, David,Kirby, Fiona,Frain, David,Rodriguez-Garcia, Antonio M.,Garcia, Jose I.,O'Leary, Patrick
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p. 750 - 757
(2013/07/25)
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- Synthesis of chiral disulfides: Potential reagents for enantioselective sulfurization
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Synthesis of chiral phosphorothioates for use as antisense oligonucleotides might benefit from the use of chiral disulfides. This paper reports the synthesis of chiral analogs of phenylacetyl disulfide and of 5-methyl-3H-1,2,4-dithiazol-3-one from the same set of 2-arylalkanoic acids. The X-ray crystal structures of the disulfides derived from (R) and [S]-2-phenylpropanoic acid establish the stereochemistry and the helicity of these materials, and density functional theory calculations suggest that the high specific rotations can be due to preferred retention of this helicity in solution. Chiral HPLC showed that the final products were formed with enantiomeric purities from 86.1% to >99.9%.
- Mukhlall, Joshua A.,Noll, Bruce C.,Hersh, William H.
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scheme or table
p. 199 - 212
(2012/01/06)
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- Synthesis, stereoselective enzymatic hydrolysis, and skin permeation of diastereomeric propranolol ester prodrugs
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Four diastereomeric propranolol ester prodrugs (1S2S, 1S2R, IR2S, 1R2R) were synthesized by treating pure R- and S-propranolol hydrochloride with pure enantiomers R- and S-phenylbutyryl chloride. A HPLC technique using α- 1 acid glycoprotein (chiral AGP) column was developed to study the racemization of propranolol enantiomers during synthesis and hydrolysis studies. A reversed phase HPLC method was also developed to simultaneously analyze propranolol and the ester prodrug. Hydrolysis of these esters was studied in different rat tissue homogenates, i.e., liver, intestine, plasma, skin, brain, and pure plasma cholinesterases, i.e., butyryl cholinesterase (EC 3.1.1.8) and acetyl cholinesterase (EC 3.1.1.7). In vitro percutaneous permeation studies across full thickness shaved rat skin were performed using standard side-by-side diffusion cells at 37 °C. The disappearance of the diastereomeric ester prodrugs in rat tissue homogenates followed apparent first-order kinetics and was stereoselective. The ratio of brain to plasma hydrolytic rate constants are 27.8, 5.58, 6.07, and 2.97 for 1S2S, 1R2R, 1R2S, and 1S2R esters, respectively. Hydrolysis of all four diastereomeric ester prodrugs was faster by acetyl cholinesterase than butyryl cholinesterase and is stereoselective. The permeability coefficients [K(p) x 103 (cm h-1)] are 1.40 ± 0.30, 1.41 ± 0.27, 42.20 ± 1.24, 29.26 ± 3.41, 16.27 ± 3.12, 12.99 ± 2.84 for (R)-propranolol, (S)-propranolol, 1S2S, 1R2S, 1S2R, and 1R2R ester prodrugs, respectively. The results indicate that the 1R2S diastereomeric ester prodrug of propranolol shows greatest stability in liver and intestinal tissues while it exhibits fairly rapid conversion in plasma. The results also suggest the configuration on the second chiral carbon atom to be the determinant in the rate of hydrolysis of all the diastereomeric prodrugs in all biological media examined. The K(p) of all four prodrugs markedly increased compared to that of the parent drug, with 1S2S showing a 30-fold increase in skin permeability, the highest among all four prodrugs.
- Udata, Chandrasekhar,Tirucherai, Giridhar,Mitra, Ashim K.
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p. 544 - 550
(2007/10/03)
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- Enantiospecific synthesis of 4-(4'-methoxyphenyl)-hexan-3-one as precursor for optically active (pS) or (pR) isomer of (Z) or (E)-3-(2'-((N,N-dimethylamino)methylferrocenyl)-4-(4''-methoxyphenyl)-hex-3-ene
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We describe herein an original method for the preparation of enantiomerically pure (Z)- or (E)-3-(2'-((N,N-dimethylamino)methylferrocenyl)-4-(4''-methoxyphenyl)-hex-3-ene possessing a p(S) or p(R) plane of chirality. The key step of the synthesis lies in obtaining enantiomerically pure (R) or (S) 4-(4'-methoxyphenyl)-hexan-3-one whose reaction with the lithiated N,N-dimethylaminomethylferrocene leads to two enantiomerically pure amino-alcohol diastereomers (pS,3S,4R) and (pR,3S,4R), or (pS,3R,4S) and (pR,3R,4S) respectively. Subsequent dehydration yields a mixture of three olefins, namely, two trisubstituted olefins and either the (Z)- or (E)-tetrasubstituted olefin with respect to the starting amino-alcohol diastereomer. Additionally we obtained the enantiomerically pure (R)- and (S)-4-phenyl-hexan-3-one and the corresponding diastereomeric amino-alcohols.
- Malezieux, Bernard,Gruselle, Michel,Troitskaya, Ludmila,Sokolov, Viatcheslav
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p. 259 - 269
(2007/10/03)
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