Propargylic alcohols isomerization

Still, occasionally the other fuctional groups react as well, for example in 38 under basic conditions the propargylic alcohol isomerizes to the a,/3-unsaturated ketone [73] (Scheme 1.15), whereas in a closely related substrate from the synthesis of a subunit of compactin an allylic alcohol remains unchanged [74],... 

Scheme 7.15) [24]. In all cases, the aldehydes corresponding to propargylic alcohol isomerization were formed as side-products. 

Emissive dopants, for OLED efficiency characteristics, 12, 141 organometallics emitters, 12, 143 phosphor-doped OLEDs, 12, 142 phosphorescent emitters, 12, 142 Emitters, in OLEDs, 12, 158 Enallenes, in Alder-ene reactions, 10, 591 a,/3-Enals, via propargylic alcohol isomerization, 10, 96 Enamides... 

Acetylene is also protected as propargyl alcohol (300)[2H], which is depro-tected by hydrolysis with a base, or oxidation with MnOi and alkaline hydrolysis. Sometimes, propargyl alcohols are isomerized to enals. Propargyl alcohol (300) reacts with 3-chloropyridazine (301) and EtiNH to give 3-diethylami-noindolizine (303) in one step via the enal 302[2I2]. Similarly, propargyl alcohol reacts with 2-halopyridines and secondary amines. 2-Methyl-3-butyn-2-ol (304) is another masked acetylene, and is unmasked by treatment with KOH or NaOH in butanol[205,206,213-2l5] or in situ with a phase-transfer cata-lyst[2l6]. 

Palladium-catalyzed cyclization reactions with aryl halides have been used to synthesize pyrazole derivatives. V-Aryl-lV-(c>-bromobenzyl)hydrazines 26 participated in a palladium-catalyzed intramolecular amination reaction to give 2-aryl-2W-indazoles 27 . Palladium-catalyzed cascade intermolecular queuing-cyclocondensation reaction of o-iodophenol (28) with dimethylallene and aryl hydrazines provided pyrazolyl chromanones 29 <00TL7129>. A novel one-pot synthesis of 3,5-disubstituted-2-pyrazolines 32 has been achieved with an unexpected coupling-isomerization sequence of haloarene 30, propargyl alcohol 31, and methylhydrazine <00ACIE1253>. 

Muller and co-workers reported the three-component one-pot synthesis of various pyrimidines through the in situ generation of unsaturated carbonyl compounds. The palladium catalyzed coupling of aryl halides bearing electron withdrawing substituents 7 with propargyl alcohols 8 produced unsaturated carbonyl compounds 9 after isomerization, which condensed with amidines 10 to form triaryl pyrimidines 11 . 

Various transition metal complexes, in particular of late transition metals, were reported to be effective catalysts for such double bond isomerization. Because organic synthesis is the focus of this volume, this section will cover the transition metal-catalyzed isomerization of alkenes, which has the significant synthetic and industrial utilities. This chapter will also include the synthetic application, asymmetric reactions,4-6 and isomerization of alkynes, in particular, that of propargylic alcohols. 

For /3-silylallylie alcohols, [Rh(cod)2]BF4/2PPh3 is a more effective catalyst than RhH(PPh3)4 to afford 3-silyl ketones in good yields (Scheme 1).1 As an interesting extension of this reaction, a tandem hydrosilation-isomerization process, starting from propargylic alcohols, was reported (Scheme 25).49... 

First example for the isomerization of propargylic alcohols to isolable a,(3-enals was reported in 1989. A variety of prop-2-ynols can be isomerized to a,/3-unsaturated aldehydes in the presence of a catalytic amount of RuCl2(PPh3)3/ Pr 3P (Scheme 53).92... 

The isomerization of propargylic alcohols to a,/3-enones was also developed by using an iridium catalyst. A variety of secondary propargylic alcohols can be isomerized to the corresponding a,/3-unsaturated ketones in the presence of 1 mol% IrHs(Pr 3P)2 (Scheme 54).93... 

A ruthenium(n)-indenyl complex, which is an efficient catalyst for the isomerization of allylic alcohols, is also an effective catalyst for the isomerization of propargylic alcohols to both a,/3-enals and a,/ -enones (Scheme 57).96 In this reaction, the addition of 20—40 mol% InClj is highly effective. The reaction exhibits extraordinary chemoselectivity and a variety of functional groups are unaffected, which allows a highly efficient synthesis of dienals (R1 =Me2C = CH, R2 = H). 

This ruthenium-catalyzed isomerization of propargylic alcohols was successfully applied to the synthesis of a,(3-cnal 6, a key intermediate in the total synthesis of sphingofungin analogs (Equation (30)).97... 

Efforts to tune the reactivity of rhodium catalysts by altering structure, solvent, and other factors have been pursued.49,493 50 Although there is (justifiably) much attention given to catalysts which provide /raor-addition processes, it is probably underappreciated that appropriate rhodium complexes, especially cationic phosphine complexes, can be very good and reliable catalysts for the formation of ( )-/3-silane products from a air-addition process. The possibilities and range of substrate tolerance are demonstrated by the two examples in Scheme 9. A very bulky tertiary propargylic alcohol as well as a simple linear alkyne provide excellent access to the CE)-/3-vinylsilane products.4 a 1 In order to achieve clean air-addition, cationic complexes have provided consistent results, since vinylmetal isomerization becomes less competitive for a cationic intermediate. Thus, halide-free systems with... 

Denmark pursued intramolecular alkyne hydrosilylation in the context of generating stereodefined vinylsilanes for cross-coupling chemistry (Scheme 21). Cyclic siloxanes from platinum-catalyzed hydrosilylation were used in a coupling reaction, affording good yields with a variety of aryl iodides.84 The three steps are mutually compatible and can be carried out as a one-pot hydro-arylation of propargylic alcohols. The isomeric trans-exo-dig addition was also achieved. Despite the fact that many catalysts for terminal alkyne hydrosilylation react poorly with internal alkynes, the group found that ruthenium(n) chloride arene complexes—which provide complete selectivity for trans-... 

An unexpected isomerization was observed for several Sonogashira adducts of certain heteroaromatics [122]. Although the reaction between 3-bromopyridine and phenyl propargyl alcohol resulted in the normal adduct 150 [122, 123], 2-iodopyridine 151 produced the isomerized chalcone 152, presumably due to promotion by triethylamine, under the same conditions [122]. 

In this context, albeit not real isomerizations, the [2,3]-Wittig rearrangements induced by a tin-lithium exchange must also be mentioned. Starting from enantio-merically pure propargylic alcohols, high ee values for the axial chiral allenes could be observed as shown for 153 (Scheme 1.69) [505, 506],... 

The reaction of the propargyl alcohols 53 with the reagent 54 furnished the S-alle-nylsulfinylamines 55 in good to excellent yields [108, 109]. Furthermore, the propargyl alcohols can be transformed with sulfur dichloride to the S-allenylsulfmates 56, which isomerize on heating in solution to the diallenyl sulfones 57 [79, 110, 111]. 

A very unusual Nazarov cyclization of propargyl vinyl ketones has been reported by Hashmi et al. (Eq. 13.16) [18]. Propargyl alcohol 50 was oxidized to ketone 51 with the Dess-Martin periodinane. Attempts to purify 51 by column chromatography on silica gel led to cyclopentenone 53 in 59% isolated yield. This suggests that the solid support catalyzed the isomerization of 51 to allenyl vinyl ketone 52, which was not isolated, but which underwent spontaneous cyclization to 53. This result is consistent with earlier observations of the great ease with which allenyl vinyl ketones undergo the Nazarov reaction (cf. 8, Eq. 13.2). 

The propargylic alcohol 102, prepared by condensation between 100 and the lithium acetylide 101, was efficiently reduced to the hydrocarbon 103, which on treatment with potassium tert-butoxide was isomerized to the benzannulated enyne-allene 104 (Scheme 20.22) [62], At room temperature, the formation of 104 was detected. In refluxing toluene, the Schmittel cyclization occurs readily to generate the biradical 105, which then undergoes intramolecular radical-radical coupling to give 106 and, after a prototropic rearrangement, the llJ-f-benzo[fo]fluorene 107. Several other HJ-f-benzo[fo]fluorenes were likewise synthesized from cyclic aromatic ketones. 

In general, acyl azides are too unstable to survive at the temperatures required for addition to acetylenes, although benzoyl azide adds readily to ynamines in toluene. Ethoxycarbonyl azide also gives triazoles in good yield with ynamines. The azide adds to propargylic alcohols in boiling ethanol, and to acetylene at 100° under pressure. Addition to phenylacetylene and to electron-deficient acetylenes has been carried out at 130°. Oxazoles are also formed at this temperature by competing thermal decomposition of the azide, and addition of ethoxycarbonylnitrene to the acetylenes. The triazole obtained from phenylacetylene is 2-ethoxycarbonyl-4-phenyltriazole the two 1-ethoxycarbonyltriazoles can be isolated if the addition is carried out at 50° over several weeks. Since the IH- to -triazole isomerization takes place readily in these systems, a IH-structure cannot be assumed for a triazole formed by addition of these azides. 

In order to obtain some information on the reaction mechanism, the reaction of propargylic alcohol with acetone in the presence of a catalytic amount of 5a was monitored. The result indicated that the catalytic formation of the hexadienone proceeded via the initial isomerization of propargylic alcohol to dnnamaldehyde followed by aldol condensation between the produced aldehyde and acetone, and then dehydration. In fad, heating of propargylic alcohol in the presence of a catalytic amount of 5a gave only dnnamaldehyde (Scheme 7.41), and the separate reaction ofcinna-... 

Scheme 7.41). It seems to be reasonable to presume that the isomerization of propargylic alcohol to cinnamaldehyde proceeds via an intramolecular nucleophilic attack of coordinated water on an electropositive a-carbon of the allenylidene ligand (Scheme 7.42). Then, dicationicdiruthenium complexes work as Lewis acids to promote the aldol condensation between cinnamaldehyde and acetone. Thus, the dual catalytic activity of dicationic chalcogenolate-bridged diruthenium complexes is essential to promote the present novel reaction between propargylic alcohols and acetone. 

Whereas the Markovnikov addition of carboxylic acids to propargylic alcohols produces P-ketoesters, resulting from intramolecular transesterification [30, 31], the addition to propargylic alcohols in the presence of Ru(methallyl)2(dppe) 1 at 65 °C leads to hydroxylated alk-l-en-l-yl esters via formation of a hydroxy vinylidene intermediate [32, 33]. The stereoselectivities are lo ver than those obtained from non-hydroxylated substrates. These esters, which are protected forms of aldehydes, can easily be cleaved under thermal or acidic conditions to give conjugated enals, corresponding to the formal isomerization products of the starting alcohols (Scheme 10.6). 

Iodoallenes are prepared from propargyl alcohols by means of phosphonium iodide produced in situ from triphenyl phosphite and methyl iodide. In addition, small amounts of the isomeric iodoacetylenes are formed in this process. 

The tandem hydrosilylation-isomerization process of sec-propargyl alcohols 140 provides an easy access to /J-silylketones 142 via silylallylic alcohols 141 (equation 57)136. 

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