Terminal acetylenes, synthesis

Z-tamoxifen 403 tandem cyclization 290, 295 tandem Heck reaction-anion capture 253-4 tandem Heck reaction-phenoxide capture 253 tandem Heck reactions 251, 252-4 tandem intramolecular Heck-intermolecular Stille cross-coupling 255 taxol 140, 143,243,245 ( )-tazettine 146,234 telomerization 352 telomerization products 343, 345 template effect 140 teraconic anhydride 468 terminal acetylenes, synthesis of 216-20 terminal alkynes 6, 213 terminal 2,2-diorgano-l-aIkcnylboronates 51 terminal diynes 207 ternary complex 444 ternary coupling 177... 

Protecting groups are clearly required if these reactions are to be employed in terminal acetylene synthesis since, with few exceptions [10], attempts to carry out both Glaser and Cadiot-Chodkiewicz couplings with acetylene itself or with bromoacetylene lead to, extensive and, uncontrollable polymerization, whilst cuprous acetylide itself is inert under the conditions of the Castro reaction. 

Thalllum(III) Compounds. Tb allium (ITT) derivatives have been used extensively as oxidants in organic synthesis. In particular, thaUic acetate and ttifluoroacetate are extremely effective as electrophiles in oxythaHation and thaHation reactions. For example, ketones can be prepared from terminal acetylenes by means of (OOCCH ) in acetic acid (oxythaHation) (30) ... 

Methyl ketones are important intermediates for the synthesis of methyl alkyl carbinols, annulation reagents, and cyclic compounds. A common synthetic method for the preparation of methyl ketones is the alkylation of acetone derivatives, but the method suffers limitations such as low yields and lack of regioselectivity. Preparation of methyl ketones from olefins and acetylenes using mercury compounds is a better method. For example, hydration of terminal acetylenes using HgSO gives methyl ketones cleanly. Oxymercuration of 1-olefins and subsequent oxidation with chromic oxide is... 

The palladium-catalyzed reaction of o-iodoanilides with terminal acetylenic carbinols provides a facile route to the synthesis of quinolines using readily available starting materials (93TL1625). When o-iodoanilide 126 was stirred with acetylenic carbinol 127 in the presence of bis-triphenyl phosphine palladium(ll) chloride in triethylamine at room temperature for 24 h, the substituted alkynol 128 was obtained in 65% yield. On cyclization of 128 with sodium ethoxide in ethanol, 2-substituted quinoline 129 was obtained in excellent yield. 

Although a number of reagents can be used to reduce an isoxazole ring, molybdenum hexacarbonyl31 was selected for use in this synthesis. The action of this reagent on 24 reduces the weak N-0 bond of the isoxazole ring and produces a //-amino-a,//-unsaturated aldehyde (i.e. a vinylogous formamide) (see Scheme 19). Intermediate 87 forms smoothly upon deprotection of the terminal acetylene carbon with basic methanol-THF. 

In 1980 Sonogashira reported a convenient synthesis of ethynylarenes - the Pd-catalyzed cross-coupfing of bromo- or iodoarenes with trimethylsilylacetylene followed by protiodesilylation in basic solution [15]. Prior to this discovery, formation of terminal acetylenes required manipulation of a preformed, two-carbon side chain via methods that include halogenation/dehydrohalogenation of vinyl- and acetylarenes, dehalogenation of /1,/1-dihaloalkenes, and the Vils-meier procedure [ 14]. With the ready availability of trialkylsilylacetylenes, the two-step Sonogashira sequence has become the cornerstone reaction for the construction of virtually all ethynylated arenes used in PAM and PDM synthesis (vide infra). 

Cross-coupling of terminal acetylenes used as nucleophiles with aryl or alkenyl halides (referred to as the Sonogashira-Hagihara, or SH, reaction) is a versatile method of synthesis for acetylenic compounds, which are rapidly gaining importance as advanced new materials and building blocks for implementing unusual molecular architectures. 

The Fukuyama indole synthesis involving radical cyclization of 2-alkenylisocyanides was extended by the author to allow preparation of2,3-disubstituted derivatives <00S429>. In this process, radical cyclization of 2-isocyanocinnamate (119) yields the 2-stannylindole 120, which upon treatment with iodine is converted into the 2-iodoindole 121. These N-unprotected 2-iodoindoles can then undergo a variety of palladium-catalyzed coupling reactions such as reaction with terminal acetylenes, terminal olefins, carbonylation and Suzuki coupling with phenyl borate to furnish the corresponding 2,3-disubstituted indoles. 

The reaction of chiral six-membered cyclic nitronates with internal and terminal acetylenes was used with advantage in the synthesis of enantiomerically pure fused substituted aziridines containing several stereocenters (96) (Scheme... 

The most convenient method of preparing the flexible (low Tg) system is to employ the Ullmann ether reaction of dibromobenzene and aromatic bis-diols followed by catalytic replacement of the bromine atoms by terminal acetylene groups. A host of commercially available bis-diols have been used in the synthesis with both meta and para dibromobenzene. Low Tg arylether oligomers have been prepared containing sulfone, sulfide, carbonyl, isopropyl and perfluoroisopropyl groups in the backbone (9). 

Kukula H,Veit S, Godt A (1999) Eur J Org Chem 277 Synthesis of monodisperse oligo-PEs using orthogonal protecting groups with different polarity for terminal acetylene units... 

Scheme 7.1 Click chemistry synthesis of 1,4-disubstituted-l,2,3-triazoles by a 1,3-dipolar cycloaddition reaction of organic azides with terminal acetylenes.

Thus, the (R)-glycidol (R)-897 was transformed to ethyl (S)-6-benzyloxy-3-methyl-4(E)-hexenoate (S)-899 via addition of acetylide followed by spontaneous isomerization, stereoselective reduction, and Claisen-Johnson rearrangement. The chiral ester (S)-899 was converted to (R)-4-methyl-6-phenylthiohexanol (R)-902. The primary alcohol (R)-902 was then transformed to the terminal acetylene (R)-904, a common intermediate for the synthesis of carbazoquinocins A (272) and D (275). Chain elongation of (R)-904 by two carbon atoms led to (R)-905, the chiral precursor for carbazoquinocin D (275) (639) (Scheme 5.116). 

Radical cyclizations are often used in ring formations and are an effective methodology in the synthesis of piperidines. The intramolecular cyclization of an oxime ether, such as 63 onto an aldehyde or ketone gives a new entry into cyclic amino alcohols <99JOC2003, 99H(51)2711>. Similarly, reaction of a terminal acetylene with BujSnH generates a vinyl radical, which will cyclize with an imine moiety to give 3-methylenepiperidine <99TL1515>. The indolizidine alkaloid ipalbidine was prepared by a sulfur-controlled 6-exo-selective radical cyclization of an a/p/ia-phenylthio amide <99H(50)31>. 

Efficiency of the deprotection and coupling reactions are critical to the success of any iterative solid-phase synthesis. Shown in Scheme 1 is a triad of reactions for phenylacetylene oligomer synthesis trimethylsilyl deprotection,28 29 triazene unmasking of an iodobenzene,30 and the Sonogashira coupling of a terminal acetylene with an aryl iodide.31-33 Representative procedures for each step in this sequence are included at the end of this chapter. 

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