Thiol mediated radical cyclisations of isocyanides : synthesis of #NU# heterocycles

Lamberto, Massimiliano

January 2003

No description available.

547.413

Alkenyl and alkynyl isocyanides

Asymmetric synthesis of the frog alkaloid epibatidine

Jones, Clifford David

January 1998

No description available.

547

Alkenyl sulfone

Intramolecular cyclizations of substitutes 5-hexenyl radicals

Phillipou, George.

January 1974

No description available.

Ring formation (Chemistry)

Alkenyl radicals

The Synthesis and Applications of N-alkenyl Aziridines

Afagh, Nicholas A.

05 April 2010

N-alkenyl aziridines are a unique class of molecules that do not behave as typical enamines as a result of the inability of the nitrogen atom lone-pair of electrons to delocalize. The attenuated nucleophilicity of these enamines presents opportunities for selective functionalization and reactivity not available to classical enamines. An operationally simple and mild copper-mediated coupling has been developed that facilitates the preparation of a broad range of N-alkenyl aziridines not available through existing methods. The preparation and reactivity of highly functionalized N-alkenyl aziridines are reported. Also reported is the application of the chemoselective amine/aldehyde/alkyne (A3) multicomponent coupling involving amphoteric aziridine aldehydes as the aldehyde component. This coupling allows access to propargyl amines with pendent aziridine functionality.

Aziridine

N-Alkenyl Aziridine

0490

The Synthesis and Applications of N-alkenyl Aziridines

Afagh, Nicholas A.

05 April 2010

N-alkenyl aziridines are a unique class of molecules that do not behave as typical enamines as a result of the inability of the nitrogen atom lone-pair of electrons to delocalize. The attenuated nucleophilicity of these enamines presents opportunities for selective functionalization and reactivity not available to classical enamines. An operationally simple and mild copper-mediated coupling has been developed that facilitates the preparation of a broad range of N-alkenyl aziridines not available through existing methods. The preparation and reactivity of highly functionalized N-alkenyl aziridines are reported. Also reported is the application of the chemoselective amine/aldehyde/alkyne (A3) multicomponent coupling involving amphoteric aziridine aldehydes as the aldehyde component. This coupling allows access to propargyl amines with pendent aziridine functionality.

Aziridine

N-Alkenyl Aziridine

0490

Intramolecular cyclizations of substitutes 5-hexenyl radicals / by G. Phillipou

Phillipou, George

January 1974

v, 174 leaves ; 26 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Organic Chemistry, 1974

Ring formation (Chemistry)

Alkenyl radicals.

Intramolecular cyclizations of substitutes 5-hexenyl radicals / by G. Phillipou

Phillipou, George

January 1974

v, 174 leaves ; 26 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Organic Chemistry, 1974

Ring formation (Chemistry)

Alkenyl radicals.

Intramolecular cyclizations of substitutes 5-hexenyl radicals /

Phillipou, George.

January 1974

Thesis (Ph.D.)-- University of Adelaide, Dept. of Organic Chemistry, 1974.

Reaching for the High-Hanging Fruits in Olefin Metathesis:

Mu, Yucheng

January 2021

Thesis advisor: Amir Hoveyda / Chapter 1: E- and Z-, Di- and Trisubstituted Alkenyl Nitriles through Catalytic Cross MetathesisWe have described the development of several catalytic cross-metathesis strategies, which can deliver a considerable range of Z- or E-disubstituted alkenyl nitriles and their corresponding trisubstituted variants. Through careful examination of the steric and electronic attributes of the starting materials, a Mo-based monoaryloxide pyrrolide or chloride complex may be the optimal choice depending on the reaction type. In the event, equimolar amounts of the two substrates are necessary to maximize reaction efficiency; a pyridine ligand is more desirable than a phosphine ligand, as a stabilizing ligand for a Mo-based complex, for improving reaction stereoselectivity. We also highlighted the utility of this approach with the synthesis of several biologically active compounds, such as LR5182 (Cocaine abuse treatment), alliarinoside (anti-feedant), perhydrohistrionicotoxin (natural product), CC-5079 (anti-cancer) and indatraline (anti-depressant). Chapter 2: Traceless Protection for More Broadly Applicable Olefin Metathesis We have devised an operationally simple in-situ protection/deprotection strategy that significantly expands the scope of kinetically controlled catalytic olefin metathesis. Pretreatment of an olefin containing a protic group with commercially available HB(pin) or HB(trip)2 is sufficient for generating the desired product efficiently through the catalytic cross-metathesis reaction. A wide range of stereochemically defined Z- and E-alkenyl halides and boronates as well as Z-trifluoromethyl-substituted alkenes with a hydroxy or carboxylic acid group were prepared. We also discovered that a small amount of HB(pin) may be used for the removal of residual water and impurities, significantly enhancing the efficiency of a multigram-scale olefin metathesis transformation. Chapter 3: E- and Z-Macrocyclic Trisubstituted Alkenes for Natural Product Synthesis and Skeletal Editing We have introduced a reliable catalytic strategy for the synthesis of a variety of macrocyclic trisubstituted olefins in either stereoisomeric form. This was achieved by overcoming the unexpected difficulties through careful mechanistic studies, including addressing complications arising from pre-metathesis alkene isomerization. Macrocyclic ring-closing metathesis can be performed with a commercially available Mo-based complex and an easily accessible linear diene precursor. Accordingly, we can synthesize a skeletally diverse array of otherwise difficult-to-access macrocyclic alkenes, a critical set of compounds in drug discovery, in either isomeric form. The utility of the method is highlighted in two instances. The first is the near complete reversal of substrate-controlled selectivity in the generation of the macrolactam intermediate, in the total synthesis of the anti-fungal agent Fluvirucin B1. The second is an exceptionally stereoselective late-stage formation of a 24-membered macrocyclic E-trisubstituted alkene, enabling the completion of the total synthesis of a cytotoxic natural product dolabelide C, which is seven times more efficient than that reported previously. Chapter 4: Stereodefined Alkenes with a Fluoro-Chloro Terminus as a Uniquely Enabling Compound Class We have offered a practical solution for the synthesis of trisubstituted alkenyl fluorides by unveiling a widely applicable strategy for stereodivergent synthesis of olefins bearing a fluoro and chloro terminus. The core transformation is unprecedented: cross-metathesis between two trisubstituted olefins, one of which is a commercially available but scarcely utilized trihalo alkene. Alkenes bearing a fluoro,chloro-terminus are versatile substrates for the generation of otherwise difficult-to-access trisubstituted alkenyl fluorides, through stereospecific catalytic cross-coupling reactions. We also highlighted the utility of the method throguh synthesis of, among others, a fluoro-nematic liquid crystal component, peptide analogs bearing an E- or a Z-amide bond mimic, and all four stereoisomers of difluoro-rumenic ester (anti-cancer). / Thesis (PhD) — Boston College, 2021. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Alkenyl fluoride

Alkenyl Nitrile

Macrocyclic trisubstituted alkene

Molybdenum

Olefin Metathesis

Traceless Protection

Organoboron reagents and recent strategies in rhodium catalysed additions

Edwards, Hannah Joy

January 2012

The research presented herein is concerned with the exploration of the rhodium catalysed addition of organoboron reagents. Chapter 1 firstly introduces the area of organoboron reagents, focussing on the applications of potassium alkenyl trifluoroborate reagents. Secondly, an extensive discussion of the rhodium catalysed conjugate addition of organboron reagents demonstrates its utility as a key coupling step in recent syntheses. Chapter 2 describes synthetic methods towards alkenylboron reagents and describes the synthesis of functionalised and enantiopure alkenyl trifluoroborate salts. Chapter 3 discusses the rhodium catalysed addition of potassium alkenyl trifluoroborate salts to α,β-unsaturated compounds. A gas chromatography study addresses issues concerning protodeboronation and highlights the potential for olefin transposition. A new rhodium catalysed olefin transposition reaction has been thoroughly investigated and applied using the synthesised potassium alkenyl trifluoroborate salts. Chapter 4 describes the synthesis of biologically relevant, enantiopure dihydropyranones for use as acceptors in the rhodium catalysed conjugate addition reaction. The hetero-Diels-Alder reaction is employed to synthesise the dihydropyranones. Rhodium catalysed conjugate addition of arylboronic acids and potassium alkenyl trifluoroborates is utilised to concisely assemble late stage intermediates of natural products including diospongin B. Chapter 5 describes the synthesis and characterisation of the compounds discussed in chapters 2, 3 and 4.

546