Enynes, carbonylation reaction

Two other Ni(CO)4 substitutes, Ni(CO)3PPh3 and Ni(COD)2/dppe, prove to be appropriate for the catalysis of tandem metallo-ene/carbonylation reactions of allylic iodides (Scheme 7)399. This process features initial oxidative addition to the alkyl iodide, followed by a metallo-ene reaction with an appropriately substituted double or triple bond, affording an alkyl or vinyl nickel species. This organonickel species may then either alkoxycar-bonylate or carbonylate and undergo a second cyclization on the pendant alkene to give 51, which then alkoxycarbonylates. The choice of nickel catalyst and use of diene versus enyne influences whether mono- or biscyclization predominates (equations 200 and 201). 

The major drawback in the development of efficient catalytic PK protocols is the use of carbon monoxide. Many groups probably refuse to use this reaction in their synthetic plans in order to avoid the manipulation of such a highly toxic gas. Carbonylation reactions without the use of carbon monoxide would make them more desirable and would lead to further advances in those areas. Once the use of rhodium complexes was introduced in catalytic PKR, two independent groups realized these species were known for effecting decarbonylation reactions in aldehydes, which is a way to synthesize metal carbonyls. Thus, aldehydes could be used as a source of CO for the PKR. This elegant approach begins with decarbonylation of an aldehyde and transfer of the CO to the enyne catalyzed by rhodium, ruthenium or iridium complexes under argon atmosphere (Scheme 36). 

Prior to the development of enyne bicyclization reactions promoted by Zr and other Group IV metals, the Co-catalyzed enyne bicyclization-carbonylation reaction (the Pauson-Khand reaction ) was known. This reaction is discussed in Volume 5, Chapter 9.1. In the Pauson-Khand reaction, the overall transformation is the conversion of enynes into bicyclic enones, and the organometallic bicyclic intermediates are usually neither readily available nor isolated. The use of Co2(CO)s, an 18-electron species, necessitates relatively high reaction temperatures. These and other limitations suggested the desirability of developing alternative enyne bicyclization reactions. 

Following activation of conjugated enynes, the reaction with carbonyl compounds and mines gives products with multiple stereocenters. ... 

Enines derived from allylic substitution products by propargylation offer many possibilities in organic synthesis. We have pursued Au-catalyzed cycloadditions with carbonyl compounds [31], enyne metathesis reactions in combination with Diels-Alder reactions [32], and a Pauson-Khand reaction as part of a synthesis of kainic acid [33]. The latter synthesis is described in Scheme 11.16 as a ret-rosynthetic scheme. The Ir-catalyzed allylic amination under in situ conditions proceeded with excellent enantioselectivity. Overall, our synthesis required 12 steps and gave a total yield of 12%. 

In a more demanding 1,7-enyne cycloisomerization reaction (36 to give 37), six-membered ring formation using standard conditions proved unfeasible due to the presence of a carbonyl group in the tether and steric hindrance in the alkene moiety. The employment of Pd2 (dba)3 and formic acid, a mandatory acid, allowed smooth cycloisomerization to occur cortpound 37 is an intermediate in the synthesis of (+)-cassiol. Cyclopentenone synthesis is also possible from related 1,6-enynes under similar conditions (eq 23).35... 

Deprotonation of l,3-bis(trimethylsilyl)propyne with Bu Li and subsequent addition of carbonyl compounds in the presence or absence of an additive such as MgBr2 has been reported to furnish the enyne products with moderate to good Z-selectivity (Scheme 2.84) [235, 236]. It has been reasonably postulated that the reaction proceeds via a kinetically controlled pericyclic process as illustrated by intermediate 134, where steric factors and the interaction between the counter ion and the oxygen atom play major roles. Other additives are also employed in Z-selective enyne formation reactions, such as Ti(OPr )4, B(OMe)3, and B-methoxy-9-borabicydo[3.3.1]nonane (B-MeO-9-BBN) [225, 226, 237-240]. 

Iwasawa et al. developed a tungsten-mediated benzannulation reaction (Scheme 15.15). On treatment of o-ethynylphenyl ketones 11 with 3 equiv of preformed W(C0)5(THF), followed by the addition of electron-rich alkenes 8, such as enam-ines and enol ethers, the corresponding naphthalenes 19 were produced together with W(CO)6 [26]. Ohe, Miki, and co-workers prepared pyranyUdene-metal complexes from conjugated enyne-carbonyl compounds using Mo, W, and Cr complexes, which were treated with dimethyl acetylenedicarboxylate to give benzene derivatives [27]. 

The lithium etiolate of acetaldehyde DMH has recently been utilized in the opening reaction of the ot-epoxide obtained by DM DO oxidation ofenol ether 142, to provide hemiacetal 143 after mild oxidative acid hydrolysis. The protected carbonyl functionality was subsequently used for the introduction of the trans enyne chain through a Wittig olefmation reaction to provide alcohol 144, which was then transformed into (+)-laurenyne (Scheme 8.37) [71]. 

Enynes 71 react with aldehydes 61 in the presence of the [Ni(COD)J/SIPr catalytic system to afford two distinct products 72 and 73 (Scheme 5.20) [20b], The enone 72 is derived from aldehyde addition with the alkyne moiety while the adduct 73 arises from the aldehyde addition with the alkene moiety. The product distribution is dependent on the substituent on either the alkyne or alkene moieties. The reaction between 71 and ketones 74 led to the unprecedented formation of pyrans 75 (Scheme 5.20). The reaction showed to be highly regioselective in aU the cases, the carbonyl carbon was bound to the olefin. 

S)-(-)-CITRONELLOL from geraniol. An asymmetrically catalyzed Diels-Alder reaction is used to prepare (1 R)-1,3,4-TRIMETHYL-3-C YCLOHEXENE-1 -CARBOXALDEHYDE with an (acyloxy)borane complex derived from L-(+)-tartaric acid as the catalyst. A high-yield procedure for the rearrangement of epoxides to carbonyl compounds catalyzed by METHYLALUMINUM BIS(4-BROMO-2,6-DI-tert-BUTYLPHENOXIDE) is demonstrated with a preparation of DIPHENYL-ACETALDEHYDE from stilbene oxide. A palladium/copper catalyst system is used to prepare (Z)-2-BROMO-5-(TRIMETHYLSILYL)-2-PENTEN-4-YNOIC ACID ETHYL ESTER. The coupling of vinyl and aryl halides with acetylenes is a powerful carbon-carbon bond-forming reaction, particularly valuable for the construction of such enyne systems. 

Co complexes, Buchwald reported the Ti-catalyzed carbonylative coupling of enynes-the so-called Pauson-Khand-type reaction [28]-and realized the first such catalytic and enantioselective reaction using a chiral Ti complex [29]. Here, a variety of enynes were transformed into bicyclic cyclopentenones with good to high ee-values however, several steps were required to prepare the chiral Ti catalyst, while the low-valent complex proved to be so unstable that it had to be treated under oxygen-free conditions in a glove box. 

By contrast, in 2000 Shibata reported the Ir-catalyzed enantioselective Pauson-Khand-type reaction of enynes [30aj. The chiral Ir catalyst was readily prepared in situ from [lrCl(cod)]2 and tolBINAP (2,2 -bis(di-p-tolylphosphino)-l,T-binaphthyl), both of which are commercially available and air-stable, and the reaction proceeded under an atmospheric pressure of carbon monoxide. The Ir-catalyzed carbonylative coupling had a wide generality in enynes with various tethers (Z), substituents on the alkyne terminus (R ) and the olefinic moiety (R ). In the case of less-reactive enynes, a lower partial pressure of carbon monoxide achieved a higher yield and ee-value (Table 11.1) [30b]. 

Gyclization/hydrosilylation of enynes catalyzed by rhodium carbonyl complexes tolerated a number of functional groups, including acetate esters, benzyl ethers, acetals, tosylamides, and allyl- and benzylamines (Table 3, entries 6-14). The reaction of diallyl-2-propynylamine is noteworthy as this transformation displayed high selectivity for cyclization of the enyne moiety rather than the diene moiety (Table 3, entry 9). Rhodium-catalyzed enyne cyclization/hydrosilylation tolerated substitution at the alkyne carbon (Table 3, entry 5) and, in some cases, at both the allylic and terminal alkenyl carbon atoms (Equation (7)). 

Suisse and co-workers have studied the asymmetric cyclization/silylformylation of enynes employing catalytic mixtures of a rhodium(i) carbonyl complex and a chiral, non-racemic phosphine ligand. Unfortunately, only modest enantioselectivities were realized.For example, reaction of diethyl allylpropargylmalonate with dimethylphenyl-silane (1.2 equiv.) catalyzed by a 1 1 mixture of Rh(acac)(GO)2 and (i )-BINAP in toluene at 70 °G for 15 h under GO (20 bar) led to 90% conversion to form a 15 1 mixture of cyclization/silylformylation product 67 and cyclization/ hydrosilylation product 68. Aldehyde 67 was formed with 27% ee (Equation (46)). 

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