Homopropargyl-metals

Cyclization to six-membered rings (Eq. 15) provided modest diastereoselectivity and required the use of bulkier PhMeSiH2 to prevent olefin hy-drosilylation. Propargyl and homopropargyl amines 94 afforded a variety of heterocycles (Scheme 21), if the catalyst was added slowly over the reaction course to diminish side reactions resulting from metal coordination to the basic amine [56]. The reaction procedure was extended to the diastereoselect-ive bicyclization of dienyne substrate 95, giving 96 as product in a cascade fashion (Eq. 16) [57]. 

Allenyltrimethylsilanes add to ethyl glyoxalate in the presence of a chiral pybox scandium triflate catalyst to afford highly enantioenriched homopropargylic alcohols or dihydrofurans, depending on the nature of the silyl substituent (Tables 9.39 and 9.40) [62]. The trimethylsilyl-substituted silanes give rise to the alcohol products whereas the bulkier t-butyldiphenylsilyl (DPS)-substituted silanes yield only the [3 + 2] cycloadducts. A bidentate complex of the glyoxalate with the scandium metal center in which the aldehyde carbonyl adopts an axial orientation accounts for the observed facial preference ofboth additions. 

Allenyltin halides are not isolable but can be prepared in situ through reaction of a propargylic halide with a mixture of tin and aluminum metal, usually in powdered form. For example, propargyl bromide is converted to diallenyltin dibromide (Eq. 9.71). This intermediate reacts with aldehydes to produce homopropargylic alcohols in high yield. Allenyl adducts are not formed in this reaction [67]. 

Allenyl iodides can be prepared from propargylic mesylates by Sn2 displacement with LiCuI2 (Eq. 9.143) [118]. The reaction proceeds primarily by an anti pathway with slight racemization. Metallation of these iodides with powdered indium in various donating solvents leads to transient allenylindium intermediates which react in situ with aldehydes to afford anti homopropargylic alcohols (Table 9.52). Additions... 

The addition of allenyl metal reagents to aldehydes affords homopropargylic alcohols with contiguous OH- and Me-substituted stereocenters, which serves as a complementary approach to the aldol condensation for polyketide synthesis. Marshall has developed this method extensively and this work is the subject of a more detailed review (cf. Chapter 9) [50]. The applications of this method to the synthesis of naturally occurring compounds have also been wide-ranging and a few are highlighted below. 

The excellent ability of late transition metal complexes to activate alkynes to nucleophilic attack has made them effective catalysts in hydroamination reactions. The gold(l)-catalyzed cyclizations of trichloroacetimidates 438, derived from homopropargyl alcohols, furnished 2-(trichloromethyl)-5,6-dihydro-4f/-l,3-oxazines 439 under exceptionally mild conditions (Equation 48). This method was successfully applied to compounds possessing aliphatic and aromatic groups R. With R = Ph, cyclization resulted in formation of 439 with complete (Z)-stereoselectivity <2006OL3537>. 

A diallenyltin dibromide reagent can be prepared from propargyl bromide, metallic tin, and aluminum (Eq. 73) [88]. Addition to aldehydes leads to homopropargylic alcohols as the exclusive products. 

From a methodological point of view, it should be pointed out the formation of 51, which is a result of the addition of acetone to an allenylidene ligand. Heteroatom-containing cyclic metal-carbene complexes [24] have been conveniently prepared via metal co-haloacyl, carbamoyl, alkoxycarbonyl, or imido intermediates [25], opening of epoxides by deprotonated Fischer-type carbene complexes [26], and activation of homopropargylic alcohols with low-valent d complexes [27], including ruthenium(II) derivatives [28]. In general, the preparation of unsaturated cyclic carbene complexes requires the previous preparation of functional carbenes to react with P-dicarbonyl derivatives, acrylates, and enol ethers [29]. 

This section covers cyclizations to the pyrrole nucleus catalyzed by other metals (Ti, Mn, Ru, Pd, Pt, Zn, In). Dembinski and co-workers used zinc(II) chloride as ligand-free catalyst for the microwave-assisted cyclization of homopropargyl azides 26 to afford substituted pyrroles 27 (Scheme 8) [62]. A similar methodology for the synthesis of 2,4,5-trisubstituted pyrroles was described by Driver et al. employing substituted 1-azidobuta-l,3-dienes in a cyclization reaction using catalytic amounts of zinc(ll) iodide [63]. A three-component zinc-catalyzed one-pot cyclization of aromatic and aliphatic propargylic acetates, silyl enol ethers, and primary amines to substituted pyrroles has been described by Zhan et al. The reaction sequence includes propargylation of the silyl enol ether, amination, 5-exo-(7ig-cyclization, and isomerization [64]. Hiroya and co-workers have shown... 

Efficient and regioselective iron-catalyzed aerobic oxidative reactions afforded 3,5-disubstituted isoxazoles 5 from homopropargylic alcohols 4, r-BuONO as the nitrogen source, and H2O under mild conditions (140L6298).A transition metal-free one-pot synthesis of 3,5-disubstituted isoxazoles used terminal alkynes by treatment with -BuLi, then aldehydes and iodine to afford intermediate a-alkynyl ketones 6 converted into isoxazoles 7 with hydroxylamine (14JOC2049). 

Homopropargylic alcohols are important intermediates, as these structural units are present in a variety of natural products and biologically active compounds [1]. Synthesis of these compounds is generally accomplished by reactions of their organometallic equivalents using an array of metals (Mg, Li, Ti, Zn, Al, Sn, Si) [2]. However, their utility is limited due to their ambident nucleophilic nature, which makes them to react with electrophiles unselectively to produce a mixture of products. 

Other Unsaturated Alcohols. The review mentioned above of carbometallation of alkynes, includes a survey of additions of alkenyl-metal derivatives to epoxides to give homoallylic alcohols. The zirconium-catalysed carboalumination of propargylic systems (Scheme 16) is also applicable to the homopropargylic to homoallylic alcohol transformation. ... 

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