Intermolecular reactions alkyne termination

Malacria and coworkers [274] used an intermolecular trimerization of alkynes to gain efficient access to the skeleton of the phyllocladane family. Thus, the Co-cata-lyzed reaction of the polyunsaturated precursor 6/4-4 gave 6/4-5 in 42% yield. Here, six new carbon-carbon bonds and four stereogenic centers are formed. The first step is formation of the cyclopentane derivative 6/4-6 by a Co-catalyzed Conia-ene-type reaction [275] which, on addition o f his( Iri me ill y I si ly 1) e thy ne (btmse), led to the benzocyclobutenes 6/4-7 (Scheme 6/4.2). The reaction is terminated by the addition of dppe and heating to reflux in decane to give the desired products 6/4-5 by an electrocyclic ring opening, followed by [4+2] cycloaddition. 

Blechert et al. succeeded in intermolecular CM of terminal alkyne and terminal alkene. A reaction carried out in CH2CI2 at RT in the presence of 5-7mol% Ic gives a mixture of ( )- and (Z)-isomers (Table 2). Because of the nonselective stereochemical course, a silyl-protected ally alcohol is employed and the resulting metathesis product is deprotected and oxidized to afford the desired diene having an -configuration (Equation (13)). 

The reaction worked with both internal and terminal alkynes (except silylated alkynes) and in many solvents, even in the neat alcohol added [105]. The mechanism proposed involved two catalytic cycles first, gold catalysis would lead to dihydro-furan by a fast intramolecular reaction then, the subsequent slower intermolecular reaction would be produced by the addition of alcohol to the enol ether to deliver a ketal (Scheme 8.18). 

Mononuclear complexes [U(C5Me5)2(NHR)2] (R = 2,6-dimethylphenyl, Et, or Bu) have been synthesized and structurally characterized. It was shown that in the presence of terminal alkynes and amines these complexes catalyze the intermolecular hydroamination of terminal alkynes [453]. Complex formation reactions of U(VI) with neutral N-donors in DMSO were reported [454]. 

An intramolecular version of this process has been described, leading to bicyclic 2-pyrones. Diynes in which both alkyne functions are internal and are linked by three-, four- or five-atom chains cycloadd to carbon dioxide in the presence of catalytic Ni° and various trialkylphosphines (equation 51). Terminal diynes require stoichiometric metal and give lower yields, however. Extensive studies of ligand effects on yield and chemoselectivity have established a broad scope for the process and pointed out important practical differences between it and the intermolecular reactions described above. ... 

Metathesis with alkynes is also quite useful in synthesis,particularly for internal alkynes although terminal alkynes are not good partners in this reaction.358 internal metathesis reactions with alkynes are known,including the conversion of 439 to 440 (in 73% yield) in FUrstner s synthesis of prostaglandin E2-1,15-lactone.360 Note the use of a molybdenum metathesis catalyst for this reaction. Diynes also react with alkynes in an intermolecular reaction to form aromatic rings. An example is the conversion of 441 to a 6 1 mixture of 442/443, in 82% yield.36la a similar, palladium-catalyzed cycloaromatization is also known.362 The metathesis disconnections are... 

Quinoline and indole derivatives were also synthesized by cyclocondensation reactions of aniline derivatives with alkynes (Eqs. 42,43) [108]. These protocols involve the ruthenium-catalyzed intermolecular hydroaminations of terminal alkynes as the initial steps. 

As a typical intermolecular carbopalladation and termination, hydroarylation of alkynes are carried out extensively in the presence of HCO2H as a hydride source. Formation of regioisomers is observed in the reaction of asymmetric alkynes, and ratios depend on the nature of the substituents. High regioselectivity was observed in the reaction of the tertiary propargylic alcohol 14 to give 15 as a major product [5]. The (Z)-2-arylcinnamates 17, rather than 3-arylcinnamate 18, was obtained by the hydroarylation of methyl phenylpropiolate (16) [6]. 3-Substituled quinoline 21 was prepared by the regioselective hydroarylation of 19, followed by treatment of 20 with an acid without isolation [6]. 

Under enyne cross-metathesis conditions, the intermolecular reaction of the a,(D-dienes 153, derived from the MBH reaction, with different terminal alkynes 154 afforded triene intermediates that cyclized spontaneously under the reaction conditions to give substituted cis-hexahydro-l/f-indenes 155 (Scheme 4.45), which can be further transformed into steroid analogues via TBS deprotection and oxidation. However, metathesis reactions starting with 156 only furnished trienes 157 [as EfZ) mixtures] and no spontaneous intramolecular cycloaddition occurred. Even at elevated reaction temperatures, trienes 157 cyclized only slowly to give octahydronaphthalene diastereomers. With deprotection of the TBS and subsequent Dess-Martin oxidation, trienes 157 could be converted exclusively into cw-fused 7-substituted 6,7-dehy-drodealone-l-one-lO-carboxylic esters 158 in 50-60% yields. Moreover, c ross-metathesis of TBS-unprotected MBH adduct 159 with alkynes 154 along with treatment with Dess-Martin periodinane (DMP) in one pot could conveniently produce the corresponding bicyclic ketones 160 in moderate yields. ... 

Examples of palladium- and rhodium-catalyzed hydroaminations of alkynes are shown in Equations 16.90-16.92 and Table 16.9. The reaction in Equation 16.90 is one of many examples of intramolecular hydroaminations to form indoles that are catalyzed by palladium complexes. The reaction in Equation 16.91 shows earlier versions of this transformation to form pyrroles by the intramolecular hydroamination of amino-substituted propargyl alcohols. More recently, intramolecular hydroaminations of alkynes catalyzed by complexes of rhodium and iridium containing nitrogen donor ligands have been reported, and intermolecular hydroaminations of terminal alkynes at room temperature catalyzed by the combination of a cationic rhodium precursor and tricyclohexylphosphine are known. The latter reaction forms the Markovnikov addition product, as shown in Equation 16.92 and Table 16.9. These reactions catalyzed by rhodium and iridium complexes are presumed to occur by nucleophilic attack on a coordinated alkyne. 

Li has reported that cationic gold(III) complexes also catalyze the intermolecular hydroamination of terminal alkynes with aniline derivatives [17]. For example, reaction of a neat 1 1.5 mixture of phenylacetylene and aniline catalyzed by AUCI3 at room temperature followed by reduction with sodium borohydride led to isolation... 

I 75 Transition-Metal-Catalyzed Hydroamination Reactions Table 15.4 Group 4 metal-catalyzed intermolecular hydroamination of terminal alkynes. 

A new intermolecular gold(I)-catalyzed reaction of terminal alkynes with functionalized alkenes led to 8-oxabicyclo[3.2.1]oct-3-enes by a [2 + 2 + 2] cycloaddition process in which two C—C bonds and one C—O... 

The intennolecular acylpalladation corresponds to the addition of an acyl-palladium bond onto a rr-bond system of another molecule this elementary step can also be referred to as an insertion (Scheme I). This produces another organopalladium complex, which can in principle participate in subsequent propagation or termination reactions. This excludes processes that involve alkoxycarbonylation (R— = R O—) and hydrocarbonyla-tion (R— = H—). This section will focus on nonpolymeric intermolecular reactions of acylpalladium complexes with different 7r-bond systems (alkenes, imines, dienes, and alkynes). 

Schafer found that the bulky bis(amidate) complex is an effective catalyst for intermolecular hydroamination of terminal alkyl alkynes with alkylamines, giving exclusively the anti-Markovnikov aldimine product [309]. The same titanium complexes can also be utilized in the hydroamination of substituted allenes in good yields (Scheme 14.132). Under the catalysis of an imidotitanium complex, the highly strained methylenecyclopropane can undergo hydroamination reaction with either aromatic or aliphatic amines, to give ring-opened imine products in good to excellent yields and chemoselectivities [310]. 

Use of (PCy3)2Cl2Ru=CHPh (1) in Other Synthetie Transformations. As well as finding widespread use in metathesis, (1) has found applications as a catalyst for other important reactions. These include hydrosilylation of alk3Ties dehydrogenative condensation of alcohols and hydrosilylation of carbonyls intermolecular cyclotrimerization of terminal alkynes conversion of triynes to benzene derivatives Kharasch additions (Z)-selective cross-dimerization of ary-lacetylenes with silylacetylenes and hydrogenation of natural rubber. ... 

Sakai N, Annaka K, Konakahara T (2004) Palladium-catalyzed coupling reaction of terminal alkynes with aryl iodides in the presence of indium tribromide and its application to a one-pot synthesis of 2-phenylindole. Org Lett 6 1527-1530. doi 10.1021/ol036499u Sakai N, Annaka K, Eujita A, Sato A, Konakahara T (2008) InBr 3-promoted divergent approach to polysubstituted indoles and quinolines from 2-ethynylanilines switch from an intramolecular cyclization to an intermolecular dimerization by a type of terminal substituent group. J Org Chem 73 4160-4165. doi 10.1021/jo800464u... 

This solid-phase technique has made possible efficient syntheses of bi- and polycyclic systems from precursors frequently generated via Nicholas cations, (e.g. eq 60) and has been used for intermolecular reactions with methy lenecyclopropane (eq 61) and methylenecyclobutane to give spirocyclic cyclopentenone derivatives. (1) is the majorproduct when the alkyne is terminal (R = H), but only (2) was isolated when EtC2Et or Me3 SiC2Me were used. ... 

A number of actinide complexes have been investigated with respect to their catalytic activity in the intermolecular hydroamination of terminal alkynes with primary ahphatic and aromatic amines [98, 206-209]. Secondary amines generally do not react and the reaction is believed to proceed via an metal-imido species similar to that of group 4 metal complexes. The reaction of Cp 2UMc2 with sterically less-demanding aliphatic amines leads exclusively to the anti-Markovnikov adduct in form of the -imine (31) [207] however, sterically more demanding amines, e.g., t-BuNH2, result in exclusive alkyne dimerization. The ferrocene-diamido uranium complex 12 (Fig. 4) catalyzes the addition of aromatic amines very efficiently (32) [98]. 

The benzene derivative 409 is synthesized by the Pd-catalyzed reaction of the haloenyne 407 with alkynes. The intramolecular insertion of the internal alkyne, followed by the intermolecular coupling of the terminal alkyne using Pd(OAc)2, Ph3P, and Cul, affords the dienyne system 408, which cyclizes to the aromatic ring 409[281]. A similar cyclization of 410 with the terminal alkyne 411 to form benzene derivatives 412 and 413 without using Cul is explained by the successive intermolecular and intramolecuar insertions of the two triple bonds and the double bond[282]. The angularly bisannulated benzene derivative 415 is formed in one step by a totally intramolecular version of polycycli-zation of bromoenediyne 414[283,284],... 

The hexabutyldistannane used in this reaction is not involved in the propagation sequence but may be involved in initiation or scavenging of potential chain-termination radicals. Intermolecular additions of alkyl radicals to alkynes have also been observed. 

---