O. Schupp

Bio: O. Schupp is an academic researcher from University of Würzburg. The author has contributed to research in topics: Pyran & Enantioselective synthesis. The author has an hindex of 12, co-authored 38 publications receiving 421 citations. Previous affiliations of O. Schupp include University of Milan.

Atropisomerization Barriers of Configurationally Unstable Biaryl Compounds, Useful Substrates for Atroposelective Conversions to Axially Chiral Biaryls†

Abstract: Configurationally unstable biaryl lactones of type (M)-1 ⇌ (P)-1 and ring-opened 2-acyl-2‘-hydroxy biaryl compounds of type (M)-4 ⇌ (P)-4 are versatile precursors for the atroposelective preparation of axially chiral biaryls. The activation barriers of their atropisomerization process, which constitutes a fundamental precondition for the dynamic kinetic resolution, were determined by dynamic NMR spectroscopy for rapid processes and by HPLC-monitored racemization of enantiomerically enriched material for smaller interconversion rates. For the lactones, the free activation energies ΔG⧧298 increase with the steric demand of the substituent R ortho to the biaryl axis in the series H < OMe (t1/2 ≈ ms) < Me (t1/2 ≈ s) < Et < i-Pr (t1/2 ≈ min) < t-Bu (t1/2 ≈ d). The formally ring-opened 2-acyl-2‘-hydroxy biaryls, which interconvert via the lactol isomers 5 as the cyclic (and thus configurationally less stable) intermediates, have a significantly slower atropisomerization rate as a result of the high loss in acti...

Aryl-aryl bond formation by transition-metal-catalyzed direct arylation.

Abstract: The biaryl structural motif is a predominant feature in many pharmaceutically relevant and biologically active compounds. As a result, for over a century 1 organic chemists have sought to develop new and more efficient aryl -aryl bond-forming methods. Although there exist a variety of routes for the construction of aryl -aryl bonds, arguably the most common method is through the use of transition-metalmediated reactions. 2-4 While earlier reports focused on the use of stoichiometric quantities of a transition metal to carry out the desired transformation, modern methods of transitionmetal-catalyzed aryl -aryl coupling have focused on the development of high-yielding reactions achieved with excellent selectivity and high functional group tolerance under mild reaction conditions. Typically, these reactions involve either the coupling of an aryl halide or pseudohalide with an organometallic reagent (Scheme 1), or the homocoupling of two aryl halides or two organometallic reagents. Although a number of improvements have developed the former process into an industrially very useful and attractive method for the construction of aryl -aryl bonds, the need still exists for more efficient routes whereby the same outcome is accomplished, but with reduced waste and in fewer steps. In particular, the obligation to use coupling partners that are both activated is wasteful since it necessitates the installation and then subsequent disposal of stoichiometric activating agents. Furthermore, preparation of preactivated aryl substrates often requires several steps, which in itself can be a time-consuming and economically inefficient process.

Atroposelective Synthesis of Axially Chiral Biaryl Compounds

Abstract: A rotationally hindered and thus stereogenic biaryl axis is the structurally and stereochemically decisive element of a steadily growing number of natural products, chiral auxiliaries, and catalysts. Thus, it is not surprising that significant advances have been made in the asymmetric synthesis of axially chiral biaryl compounds over the past decade. In addition to the classic approach (direct stereoselective aryl-aryl coupling), innovative concepts have been developed in which the asymmetric information is introduced into a preformed, but achiral-that is, symmetric or configurationally labile-biaryl compound, or in which an aryl--C single bond is stereoselectively transformed into an axis. This Review classifies these strategies according to their underlying concepts and critically evaluates their scope and limitations with reference to selected model reactions and applications. Furthermore, the preconditions required for the existence of axial chirality in biaryl compounds are discussed.

Atroposelective total synthesis of axially chiral biaryl natural products.

Abstract: Intellectual curiosity has always been one of the major driving forces leading to new advances in chemistry. At the onset of the 20th century, the fact that biaryls could be optically active even if lacking asymmetrically substituted carbon atoms arose interest, hinting at a novel type of stereomerism. It took quite a while (and some bizarre explanations)1 until in 1922 Christie and Kenner2 first correctly recognized that the phenomenon was the consequence of a hindered rotation about the aryl-aryl single bondshence termed atropisomerism by Kuhn. Still, no particular attention was initially paid to this class of stereoisomers until enantiomerically pure biaryls, such as BINAP (1),3 were found to be excellent ligands in asymmetric catalysis and until the chiral biaryl unit was recognized as the decisive structural element of many natural products (Figure 1).4,5 With the modern screening techniques and the bioassayguided search for novel compounds, the number of isolated axially chiral natural biaryls is steadily increasing.4 This class of secondary metabolites is characterized by a broad structural diversity, reaching from relatively simple molecules like the C2-symmetric biphenyl 2, which solely contains the element of axial chirality,6 to more complex compounds, like, e.g., the dimeric naphthylisoquinoline alkaloids michellamine A [(P,P)-3] and its axial epimer (i.e., its atropodiastereomer), michellamine B [(P,M)-3],7,8 which possess even three biaryl axes, of which the two outer ones are stereogenic, while * To whom correspondence should be addressed. E-mail: bringmann@ chemie.uni-wuerzburg.de; breuning@chemie.uni-wuerzburg.de. † These authors contributed equally to this work. ‡ Present address: Institute of Organic Chemistry, RWTH Aachen, Landoltweg 1, 52074 Aachen, Germany. § Present address: Kekulé Institute of Chemistry and Biochemistry, University of Bonn, Gerhard-Domagk Str. 1, 53121 Bonn, Germany. Gerhard Bringmann was born in 1951 and studied chemistry in Gie en and Münster, Germany. After his Ph.D. with Prof. B. Franck in 1978 and postdoctoral studies with Prof. Sir D. H. R. Barton in Gif-sur-Yvette (France), he passed his habilitation at the University of Münster in 1984. In 1986, he received offers for full professorships of Organic Chemistry at the Universities of Vienna and Würzburg, of which he accepted the latter in 1987. In 1998, he was offered the position of director at the Leibniz Institute of Plant Biochemistry in Halle, which he declined. His research interests focus on the field of analytical, synthetic, and computational natural product chemistry, i.e., on axially chiral biaryls. He received several prizes and awards, among them the Otto-Klung Award in chemistry (1988), the Prize for Good Teaching of the Free State of Bavaria (1999), the Adolf-Windaus Medal (2006), the Honorary Doctorate of the University of Kinshasa (2006), the Paul-J.-Scheuer Award (2007), and the Honorary Guest Professorship of Peking University (2008). Chem. Rev. 2011, 111, 563–639 563

Rare-earth metal triflates in organic synthesis

Abstract: 2.1.8. Michael Reaction 2245 2.1.9. Others 2247 2.2. Cyclization Reactions 2248 2.2.1. Carbon Diels−Alder Reactions 2248 2.2.2. Aza-Diels−Alder Reactions 2252 2.2.3. Other Hetero-Diels−Alder Reactions 2255 2.2.4. Ionic Diels−Alder Reaction 2256 2.2.5. 1,3-Dipolar Cycloadditions 2256 2.2.6. Other Cycloaddition Reactions 2258 2.2.7. Prins-type Cyclization 2259 2.3. Friedel−Crafts Acylation and Alkylation 2259 2.4. Baylis−Hillman Reaction 2263 2.5. Radical Addition 2264 2.6. Heterocycle Synthesis 2267 2.7. Diazocarbonyl Insertion 2270 3. C−X (X ) N, O, P, Etc.) Bond Formation 2271 3.1. Aromatic Nitration and Sulfonylation 2271 3.2. Michael Reaction 2272 3.3. Glycosylation 2273 3.4. Aziridination 2275 3.5. Diazocarbonyl Insertion 2276 3.6. Ring-Opening Reactions 2277 3.7. Other C−X Bond Formations 2280 4. Oxidation and Reduction 2280 4.1. Oxidation 2280 4.2. Reduction 2281 5. Rearrangement 2283 6. Protection and Deprotection 2285 6.1. Protection 2285 6.2. Deprotection 2288 7. Polymerization 2291 8. Miscellaneous Reactions 2291 9. Lanthanide(II) Triflates in Organic Synthesis 2295 10. Conclusion 2295 11. Acknowledgment 2295 12. References 2295