Alkynols, carbonylation

In addition to the W and Mo carbonyl complexes that have most commonly been used for the cycloisomerization of alkynols, an Rh-based catalyst system has recently been developed which uses substantially lower catalyst loadings (1.5-2.5 mol%) than have typically been required for the W and Mo systems (10-50 mol%).369 Among the various ligands studied, P(/>-F-C6H4)3 proved to be particularly effective. Interestingly, this ligand has also been found to be optimal for an Ru system that catalyzes the same type of cycloisomerization (Equation (104)).370,371... 

Substituted propargylic alcohols were found to undergo direct carbonylation to the corresponding butenolides in 67-98% yield (Eq. 9.120) [86]. This reaction requires a catalytic amount of Pd2(dba)3-CHC13 (4%) and l,4-bis(diphenylphosphi-no)butane (8%) in CH2C12 under an atmosphere of CO (600 psi) and H2 (200 psi) at 95 °C for 36 h. The cyclocarbonylation reaction is believed to proceed via an allenyl-palladium intermediate, which is formed by initial insertion of Pd(0) into the C-O bond of the alkynol followed by rearrangement (Scheme 9.25). 

Similarly, allenes [32] and alkynols [33] were used as starting materials and their carbonylation provides /3,y-unsaturated acids and unsaturated diacids, respectively. The specific reactivity of alkynols is explained by three formal steps during nickel catalysis (i) carbonylation of the triple bond leading to an acid containing an allylic alcohol moiety (ii) second carbonylation of the double bond to provide a hydroxydiacid and (iii) a dehydration step giving the corresponding unsaturated diacid (Scheme 2). 

Carbonylation reactions under water-gas-shift conditions have been largely explored, alkynols giving saturated lactones and alkynyl amines giving saturated lactams [43]. Intramolecular alkoxycarbonylations of alkynols producing unsaturated lactones will be further described in the following paragraph. 

Intramolecular alkoxycarbonylation of alkynols is parallel to what has been described for alkenols except that functionalization of the triplebond produces a double bond. No lactone formation is observed in the Pd(II)-catalyzed oxidative cyclization-carbonylation of alkynes. Instead [(methoxycarbonyl)methylene]tetrahydrofurans are selectively formed [134, 135]. Moreover, starting from an enynol, furan-2-acetic ester is obtained resulting from a final aromatization step [136]. 

Carbonylative coupling of iodobenzene with 2-methyl-3-butyn-2-ol under 65 bar carbon monoxide afforded phenylfuranones (double carbonylation) in reasonable yields (Scheme 6.32) [69]. The reaction is thought to proceed through the formation of a benzoylpalladium intermediate which either reacts with the alkynol or liberates benzoic acid hence the formation of considerable amounts of the latter. 

MOLYBDENUM CARBONYL-CATALYZED ALKYNOL CYCLOISOMERIZATION PREPARATION OF 2-PHENYL-2,3-DIHYDROFURAN (Furan, 2,3-dihydro-2-phenyl-)... 

The anionic complexes (50) are obtained from the group VI carbonyl and the dilithium derivatives of the hydroxyalkynes HC=CCR2(OH) subsequent protonation or acylation affords propadienylidene (51) or carbene (52) complexes by complex cyclization and addition reactions (Scheme 3) (28). Attempts to obtain the dimethyl complex by reaction of the chromium alkynolate dianion with COCl2 gave only polymeric material. More stable complexes were obtained with R = aryl (73). 

Alkyne-vinylcyclopropanes, metal-catalyzed [5+23-cycloadditions, 10, 605 Alkynides, with tungsten carbonyls, 5, 666 Alkynoic acids, stannylmetallation, 9, 374 Alkynoles, hydration-dehydration reactions, 6, 841... 

Conversion of alkynols into iodo-unsaturated carbonyl compounds using HTI and... 

Alkynols complexed to cobalt can be oxidized to alkynals without decomplexation. Propargyl aldehydes are protected from polymerization upon complexation with Co2(CO)6. These aldehydes smoothly undergo Wittig-type reactions. Carbonyl-ene reactions have been demonstrated (Scheme 194). Complexation to cobalt protected the enyne in complex (132) from Michael-type reactions (Scheme 195). Alkenyl-substituted complexes undergo [3 + 2]cycloadditions with nitrile A-oxides (Scheme 196). 

Besides the conventional methods, the metallo-carbene route to access cyclic compounds has become a versatile tool in sugar chemistry. Synthesis of stavudine 112, an antiviral nucleoside, from an allyl alcohol [101] is realized by a Mo(CO)5-mediated cyclization reaction (O Scheme 26). Molybdenum hexacarbonyl smoothly reacts with the triple bond of 113 to generate the intermediate Mo-carbene, which undergoes a clean cyclorearrangement to yield the furanoid glycal 114. Alkynol isomerization is effected by group-6 transition metal carbonyl complexes [102]. 

The most popular Pd-catalyzed method for the production of furans and benzofurans involves reactions of alkynols. Acyclic alkynols are converted into furans, while benzene substituted alkynols are transformed into benzofurans. The use of this strategy is widespread for the synthesis of benzofurans however, it is occasionally used for the syntheses of furans. For example, intramolecular alkoxylation of alkyne 189 proceeds via an alkenylpalladium complex and subsequent carbonylation to form furan 190 [156, 157]. In addition, 3 -hydroxyalkyl-benzo[/)J furans were prepared by Bishop et al. via a Pd-catalyzed heteroannulation of silyl-protected alkynols with 2-iodophenol in a fashion akin to the Larock indole synthesis [158]. In a related series of experiments, Qing demonstrated that alkynes 191 could be efficiently converted into furans 192 [159]. 

Three important processes have evolved from Reppe s work. Vinylation, the formation of vinyl derivatives by reaction of such compounds as acids, glycols, and alcohols with acetylene, produces the important vinyl esters and vinyl ethers. Ethinylation is defined as the reaction of acetylene with the carbon atom of a reactant without loss of the triple bond. A major application of the ethinylation reaction is to aldehydes and ketones to give alkynols and alkyndiols—e.g., the reaction of acetylene with formaldehyde to give propargyl alcohol and butyn-2-diol-l,4. Carboxylation (also referred to as carbonylation), the reaction of acetylene with carbon monoxide in the presence of metal carbonyls, has been applied to the production of acrylic acid, acrylates, and hydroquinone. 

In the key step of a synthesis of spironolactone (an aldosterone antagonist, used as a diuretic) reductive carbonylation of the optically active steroidal alkynol ethisterone yields a saturated cyclic hemiacetal (lactol) 15 with rhodium(II) acetate dimer/triphenylphosphane in 90% yield173. This reaction proceeds without loss of optical information and is interpreted as a combination of hydroformylation and hydrogenation173. 

One of the most practical ways to achieve chiral propargyl alcohol is to add acetylene anion to a carbonyl group in an enantiofacial manner. This art was well demonstrated by Mukayama et al. in 1979 using (2S,2 S)-2-hydroxymethyl-l-[(l-methylpyrrolidine-2-yl)methyl]pyrrohdine as a chiral ligand. The addition of lithium trimethylsilyl acetylide to benzaldehyde afforded the corresponding alkynol in over 92% optical yield. It is noted that the enantioselectivity of the present reaction depended predominantly on the trialkylsilyl group of the acetylene. Scheme 21.7 confirms these observations. 

For example, malonic esters can be made by PTC carbonylation of ethyl chloroa-cetate at 1 bar CO at 25 °C in the presence of cobalt carbonyl. Ni(CN)2 was used for the PTC double carbonylation of alkynols, using PEG-400 as the phase-transfer catalyst, LaCls as an additional co-catalyst, toluene as the solvent, and 0.5 M NaOH as the optimum base concentration. Yields of ene-dicarboxylic acids were up to 97%. 

---