First efficient preparation of enantiopure 10-bromofenchone: the key intermediate to C10-substituted fenchone-derived chiral sources

Organocatalytic asymmetric halogenation/semipinacol rearrangement: highly efficient synthesis of chiral α-oxa-quaternary β-haloketones

A novel asymmetric halogenation/semipinacol rearrangement reaction catalyzed by cinchona alkaloid derivatives was developed. Two types of β-haloketones (X = Br, Cl) were obtained with up to 95% yield and 99% enantiomeric excess. The desired (+) and (-) enantiomers of the β-haloketones were readily obtained.

Self-recognition and hydrogen bonding by polycyclic bridgehead monoalcohols

Our interest in the relationship between the hydrogen bonding motifs displayed by monoalcohols and the properties of the solids which contain these motifs has led us to determine the crystal structures of three polycyclic bridgehead monoalcohols. One C10H16O isomer crystallises in the space group P2(1)2(1)2(1) but the three molecules which comprise the asymmetric unit are related approximately by the operations of a 3(1) screw axis. They are linked by hydrogen bonds to form an infinite helix. A second C10H16O isomer forms rings containing four molecules joined by cooperative hydrogen bonds. The chiral space group P4(1)2(1)2 accommodates molecules of the S,S and R,R enantiomers in the molar ratio 92:8 (ee 84%) owing to disorder. A related C9H14O2 keto-alcohol forms infinite chains by C-OH...O = C hydrogen bonding. These hydrogen bond motifs are shown to be typical for 45 tertiary monoalcohols, CmHnOH, present in the Cambridge Structural Database. Tertiary monoalcohols display in a more pronounced form the strong preferences for trigonal and tetragonal space groups and for asymmetric units containing several molecules which are established features of the crystallochemistry of monoalcohols.

C10-substituted camphors and fenchones by electrophilic treatment of 2-methylenenorbornan-1-ols: enantiospecificity, scope, and limitations

Valuable chiral sources of C(10)-substituted camphors and C(10)-substituted fenchones can be straightforwardly obtained by treatment of an appropriate, easily obtainable, camphor- or fenchone-derived 2-methylenenorbornan-1-ol with an electrophilic reagent. The process takes place via a tandem regioselective carbon-carbon double-bond addition/stereocontrolled Wagner-Meerwein rearrangement. A complete study of the enantiospecificity, scope, and limitations of this process, as well as about the role played by the hydroxyl group attached at the C(1) bridgehead position of the starting 2-methylenenorbornan-1-ols, has been realized. The feasibility of the described methodology has been exemplified by the highly efficient enantiospecific preparation of several interesting C(10)-halogen-, C(10)-O-, C(10)-S-, C(10)-Se-, or C(10)-C-substituted camphors and fenchones.