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The AD Catalytic Cycle. Chem. Rev. 1994, 94, 2483-2547. Shutting Down the Secondary Cycle. The Cinchona Alkaloids. (DHQ) 2 PHAL “AD- a ”. The AD-Mix Mnemonic. Works best for: trans alkenes terminal olefins quite bad with aromatic ring to sit in “attractive area”.
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The AD Catalytic Cycle Chem. Rev. 1994, 94, 2483-2547 Sean Parris, Olefin Bisfunctionalisation
Shutting Down the Secondary Cycle Sean Parris, Olefin Bisfunctionalisation
The Cinchona Alkaloids (DHQ)2PHAL “AD-a” Sean Parris, Olefin Bisfunctionalisation
The AD-Mix Mnemonic • Works best for: • trans alkenes • terminal olefins quite bad • with aromatic ring to sit in • “attractive area” Sean Parris, Olefin Bisfunctionalisation
Which Ligand System? Sean Parris, Olefin Bisfunctionalisation
Racemic Dihydroxylation – Beyond Upjohn Upjohn (NMO, OsO4) can be slow & prone to over-oxidation J. Eames, H. Mitchell, A. Nelson, P. O’Brien, S. Warren, P. Wyatt, Perkin 1 1999, p1095 Sean Parris, Olefin Bisfunctionalisation
Sharpless Asymmetric Aminohydroxylation (AA) Sean Parris, Olefin Bisfunctionalisation
Sharpless Asymmetric Aminohydroxylation (AA) Sharpless et al. Angew. Int.1997 438 Sean Parris, Olefin Bisfunctionalisation
AA –Mechanism Review: McLeod et al, Perkin 1, 2002, 2733 Sean Parris, Olefin Bisfunctionalisation
AA – Standard Conditions? Review: P. O’Brien, Angew. Int,1999, 326 Sean Parris, Olefin Bisfunctionalisation
Competing Dihydroxylation • First turnover of catalyse is AD • Can reduce AD with slow addition of substrate Sean Parris, Olefin Bisfunctionalisation
AA – Best Substrates Cinnamates best using (DHQ)2PHAL (as drawn) (DHQ)2AQN (regioisomer) a,b-unsat’d (DHQ)2PHAL (as drawn) effect ligand unknown Sean Parris, Olefin Bisfunctionalisation
AA – More Substrates • Styrenes, a,b-unsat’d esters & vinyl arenes only work with acetamide & carbamate • Other egs where DHQ vs DHQD give regioisomers in similar ee of opposite stereoinduction! Sean Parris, Olefin Bisfunctionalisation
Sharpless Aminohydroxylation – Further Work • a,b-unsat’d amides & carboxylic acids found to be good substrates for a racemic AH (Angew.1997, p2751; Angew.2001 3455) because exist solely in “secondary cycle” • Start to develop a AA using the secondary cycle only which places far more stringent requirements on the ligand, with only partial success: 50-70% ee for AD, 25-60% ee for AA (Angew. 2002, 474) • Muniz et al got around the problem of a racemic AH for acrylamindes by using chiral substrate (Tet. Asymm. 2005, 3492) • Hergenrother et al found could change regioselectivity in AA of styrenes by controlling pH with modest ee (Org. Let.2003, 281) Sean Parris, Olefin Bisfunctionalisation
Other Aminhydroxylations - TA Tethered Aminohydroxylation (TA) • Stereochemistry comes from allylic alcohol • Stereoinduction requires cyclic system Donohoe et al, JACS2002, 12934 Sean Parris, Olefin Bisfunctionalisation
Tethered Aminohydroxylation Sean Parris, Olefin Bisfunctionalisation
Tethered Aminohydroxylation - Mechanism Sean Parris, Olefin Bisfunctionalisation
Diamination to Conjugated Dienes (1) disfavour 3 (2) favour Nu addn to give diamine (3) amine souce that won’t react with other species Sean Parris, Olefin Bisfunctionalisation
Question Time – Predict the Products Sean Parris, Olefin Bisfunctionalisation
Diamination – Initial Results • Conditions are modified Wacker conditions • - Regioselectivity of first complexation • Unsymmetric ureas (solubility also a problem) • needs chloride Pd pre-catalyst Sean Parris, Olefin Bisfunctionalisation
Question Time – Wacker Oxidation Sean Parris, Olefin Bisfunctionalisation
Diamination – Further Results • Benzoquinone (method A) is superior oxidant • best for symmetric dienes Sean Parris, Olefin Bisfunctionalisation
Enatioselective Diboronation of Olefins 50-98% 50-96% ee • Works for terminal & di-substiuted alkene, not tri subst • Works best for trans alkenes • Tolerates protected alcohols Morken et al, JACS2003, 8702; JOC 2005 9538 Sean Parris, Olefin Bisfunctionalisation
Enatioselective Diboronation of Olefins Morken et al, JOC 2005 9538 Sean Parris, Olefin Bisfunctionalisation
Carbohyroxyltion of Olefins One-pot diboronation-Suzuki cross coupling Morken et al, Org. Lett. 2004,131 Sean Parris, Olefin Bisfunctionalisation
Diboronation Mechanism Sean Parris, Olefin Bisfunctionalisation
Regioselective Aminoacetoxylation • Racemic addition • Requires adjacent ether in substrate • Interesting IIII reagent oxidises Pd-C bond… Stahl et al, JACS2006, 7179 Sean Parris, Olefin Bisfunctionalisation
Regioselective Aminoacetoxylation Sean Parris, Olefin Bisfunctionalisation
Hydroxysulfenation Sean Parris, Olefin Bisfunctionalisation
Hydroxysulfenation • R1 = Ar, alk • R1=R2 = c-hex, Ar • R3 = Ar, Cy • Complete diastereoselectivity • can also replace S-Ar with Si-iPr, SePh & SnBu Taniguchi, JACS 2006, 7876 Sean Parris, Olefin Bisfunctionalisation
Hydroxysulfenation Sean Parris, Olefin Bisfunctionalisation
Hydroxysulfenation Sean Parris, Olefin Bisfunctionalisation