Olefin Cross‐Metathesis: Studies towards the Total Synthesis of (+)‐Bitungolide F

A stereoselective synthesis of (5S,6S)‐6‐[(2S,5S,7R,8E,10E)‐5‐(benzyloxy)‐7‐{[(tert‐butyl)dimethylsilyl]oxy}‐11‐phenylundeca‐8,10‐dien‐2‐yl]‐5‐ethyl‐5,6‐dihydro‐2H‐pyran‐2‐one (=(+)‐9‐O‐benzyl‐11‐O‐[(tert‐butyl)dimethylsilyl]bitungolide F) is reported. The strategy involves Gilman reaction, olefin cross‐metathesis, and Horner? Wadsworth? Emmons olefination as key steps.     

A stereoselective total synthesis of (−)-andrachcinidine via an olefin cross-metathesis protocol

A stereoselective total synthesis of 1-(2S,6R)-6-[(2S)-2-hydroxypentyl]-hexahydro-2-pyridinylacetone, (−)-andrachcinidine is reported. The strategy utilizes olefin cross-metathesis and intramolecular S_N2 cyclization as the key steps.     

First Diastereoselective PasseriniSmiles and UgiSmiles Reactions Using Chiral Aldehydes

A diastereoselective O/N‐arylative Passerini/Ugi reaction of chiral aldehydes with commercially available isocyanides affording O‐aryl amides and N‐aryl amides, respectively, as products in moderate to good yields, together with de values, is reported.     

A Versatile and Stereocontrolled Total Synthesis of Dihydroxylated Docosatrienes Containing a Conjugated E,E,Z‐Triene

A versatile strategy featuring a Colvin rearrangement, hydrozirconation, a Sonogashira cross‐coupling reaction and a Z‐selective Wittig olefination, was successfully developed for the construction of a conjugated E,E,Z‐triene subunit, flanked on both sides by two Z‐allylic hydroxyl groups. This chemical pattern is found in many endogenous lipid metabolites such as maresin 1 (MaR1), neuroprotectin D1 (NPD1), and its aspirin triggered‐isomer AT‐NPD1, which not only counter‐regulate inflammation but also actively orchestrate (at nanomolar doses) the resolution and termination program of acute inflammation while promoting wound healing, return to homeostasis and neuroprotection. Unlike previous approaches, the advantages of the present strategy are obvious, as it allows us to modify the nonpolar tail, the carboxylated head or both ends of the molecule without repeating the whole synthetic sequence (about 26–34 steps according to the literature). Thus, the first total syntheses of NPD1 methyl ester epimer (which can also be considered as an enantiomer of AT‐NPD1) and its n‐3 docosapentaenoic acid derived analogue were achieved from a highly functionalized and late advanced pivotal intermediate. This innovative route may be easily adapted to gain access to other dihydroxylated metabolites and analogues of polyunsaturated fatty acids containing a conjugated E,E,Z‐triene subunit. Different epimers/diastereoisomers may be obtained by purchasing the suitable optically pure (S)‐ and/or (R)‐1,2,4‐butanetriol(s) as a chiral pool for both stereogenic centers.     

(Chiral) lithium–(magnesium–)zinc and lithium–cobalt combinations as dual reagents for aromatic deproto-metalation and aryl transfer to aldehydes

The deprotonating ability of mixed lithium–zinc or lithium–magnesium–zinc combinations containing amido and alkyl ligands in tetrahydrofuran were compared using anisole as substrate and iodine to quantitatively trap the formed arylmetal species. The results showed that the deprotonating ability is hampered if a Grignard reagent is employed to introduce the alkyl ligand, and is reduced when 2,2,6,6-tetramethylpiperidino ligands are replaced by less hindered/basic chiral amido or alkyls. Concerning the interception of the generated lithium–zinc aryl species by aldehydes, the presence of amido ligands leads to side reactions/lower yields, and no clear improvement was observed if lithium–magnesium–zinc aryl species are used. Racemic mixtures to very low enantioselectivities were noted when chiral amido ligands were incorporated in the composition of the bases.Still with enantioselective aryl transfer to aldehyde as purpose, the deprotonating ability of mixed lithium–cobalt combinations containing amido and alkyl ligands were compared using anisole as substrate and anisaldehyde to trap the formed arylmetal species. As before, the deprotonating ability is reduced when 2,2,6,6-tetramethylpiperidino ligands are replaced by less hindered/basic alkyls or chiral amido. The trapping step using aldehydes being in this case more efficient, even in the presence of amido ligands, the alcohols were obtained in higher yields. With recourse to a lower interception temperature, and using only bis[(R)-1-phenylethyl]amino as ligands, 32 and 22% yield, and 69 and 65% ee were obtained using, respectively, anisaldehyde and 3,4,5-trimethoxybenzaldehyde to intercept the metalated anisole.     

Deprotonative metalation of substituted aromatics using mixed lithium-cobalt combinations

The deprotonation of anisole was attempted using different homo- and heteroleptic TMP/Bu mixed lithium-cobalt combinations. Using iodine to intercept the metalated anisole, an optimization of the reaction conditions showed that in THF at room temperature 2 equiv of base were required to suppress the formation of the corresponding 2,2′-dimer. The origin of the dimer was not identified, but its formation was favored with allyl bromide as electrophile. The metalated anisole was efficiently trapped using iodine, anisaldehyde, and chlorodiphenylphosphine, and moderately employing benzophenone, and benzoyl chloride. 1,2-, 1,3-, and 1,4-dimethoxybenzene were similarly converted regioselectively to the corresponding iodides. It was observed that 2-methoxy- and 2,6-dimethoxypyridine were more prone to dimerization than the corresponding benzenes when treated similarly. Involving ethyl benzoate in the metalation-iodination sequence showed that the method was not suitable to functionalize substrates bearing reactive functions.     

Diastereoselective Passerini reactions using p-toluenesulfonylmethyl isocyanide (TosMIC) as the isonitrile component

p-Toluenesulfonylmethyl isocyanide (TosMIC) is used for the first time as the isonitrile component in a diastereoselective Passerini reaction with sugar-derived aldehydes to afford products in moderate to good yields (40-90%) and selectivities (30-90% de’s).