Phosphonium ylides stabilized

The stabilized phosphonium ylide (601) reacts with aromatic aldehydes to give N-phenacylpyrazoles (602) in good yields (73CC7). Ketone semicarbazones and ketazines react with two moles of phosphorus oxychloride-DMF, the Vilsmeier-Haack reagent, with the formation of 4-formylpyrazoles (603 R = H or PhC=CH2) (70JHC25, 70TL4215). 

Reaction of Stabilized Phosphonium Ylides with Activated C=C... 

A related preparation of specific stabilized phosphonium yUdes corresponds to the reaction of triarylphosphines with acetylene dicarboxylic esters in presence of fullerene, which affords a cyclopropanyl-fullerene substituted stabilized phosphonium ylide [9] or the corresponding evolution products [10]. 

Further, Wasserman and coworkers developed a direct acylation of stabilized phosphonium ylides by carboxylic acids in presence of the EDCI/DMAP (way c). This last method allows the introduction of a-aminoacid structures into the resulting P-oxo phosphorus ylides [19-25],opening the way to the total synthesis of depsipeptide elastase inhibitors [22,24] or cyclic peptidic protease inhibitor EurystatinA [20]. 

The thermolysis of various substituted phosphonium ylides between 600 °C and 900 °C can afford either substituted alkynes [16,25,27] or cyclic dienes [20] by extrusion of PhjPO, or new stabilized ylides by cyclization of the functional groups [27,28]. 

Particularly interesting are the results obtained with the phosphonium ylides including an acyl rest derived from aminoacid if the N-H bond reactivity is blocked by an amide protection, the alkyne formation takes place [25,27], but if the N-H bond is not deactivated, an intramolecular cyclization occurs to give a new stabilized ylide [27,28]. 

D.K. Taylor and co-workers investigated thoroughly a new route to diastere-omerically pure functionalized cyclopropanes utilizing stabilized phosphonium ylides and y-hydroxyenones derived from 1,2-dioxines (Scheme 7) [34-38]. 

In a related work, the same authors present an expeditious synthesis of functionalized dihydronaphtofurans starting from dihydronaphtodioxines and stabilized phosphonium ylides [39]. 

As in the preceding case with molybdenum, the spectroscopic and X-ray crystallographic data suggest that the complexes obtained can be described as organometallic analogs of resonance-stabilized phosphonium ylides [74]. 

A novel chiral dissymmetric chelating Hgand, the non-stabiUzed phosphonium ylide of (R)-BINAP 44, allowed in presence of [Rh(cod)Cl]2 the synthesis of a new type of eight-membered metallacycle, the stable rhodium(I) complex 45, interesting for its potential catalytic properties (Scheme 19) [81]. In contrast to the reactions of stabihzed ylides with cyclooctadienyl palladium or platinum complexes (see Scheme 20), the cyclooctadiene is not attacked by the carbanionic center. Notice that the reactions of ester-stabilized phosphonium ylides of BINAP with rhodium(I) (and also with palladium(II)) complexes lead to the formation of the corresponding chelated compounds but this time with an equilibrium be-... 

Beyond their ubiquitous role in organic synthesis, stabilized, semistabiUzed, or nonstabilized phosphonium ylides are fascinating ligands of transition metals. Their coordination chemistry is dominated by C-coordination to the metal center they are known to act exclusively as carbon-centered ligands rather than as v -C=P ligands. 

Phosphonium ylides form complexes with almost every metal of the periodic table [8-13]. The first ylide complexes involved carbonyl-stabilized ylides at Pd (II) and Pt(II) metal centers. One early example was reported by Amup and Baird in 1969 [61]. The scope of the ylide coordination chemistry was then extensively investigated by Schmidbaur [8]. 

With the fully functionalized heterocyclic core completed, synthetic attention next focused on introduction of the 3,5-dihydroxyheptanoic acid side-chain. This required initial conversion of the ethyl ester of 35 to the corresponding aldehyde through a two-step reduction/oxidation sequence. In that event, a low-temperature DIBAL reduction of 35 provided primary alcohol 36, which was then oxidized to aldehyde 37 with TRAP. Subsequent installation of the carbon backbone of the side-chain was accomplished using a Wittig olefination reaction with stabilized phosphonium ylide 38 resulting in exclusive formation of the desired -olefin 39. The synthesis of phosphonium ylide 38 will be examined in Scheme 12.5 (Konoike and Araki, 1994). 

TABLE 2. Bond lengths0 in some conjugatively stabilized phosphonium ylides R3P=CX—C-(=Y)Z... 

Dixon and Smart71 examined a series of fluorine-substituted phosphonium ylides. Fluorine stabilizes carbanions via an inductive effect, favouring pyramidal carbanions. Dixon and Smart argued that the first substitution of F on the ylidic carbon (H3P=CHF) causes the carbon to become very pyramidal (the sum of the angles at C is 338.5°), which reduces the potential overlap of the anionic orbital with any P orbitals. The leads to the long P—C distance of 1.723 A. The second F substitution (H3P=CF2) actually breaks the P—C bond and the system is best described as a weak interaction of phosphine with CF2. Trifluoromethyl groups act to stabilize the anions via hyperconjugation. This leads to a planar ylidic carbon in H3P=C(CF3)2. 

Ostoja Starzewski and Bock83 reported the photoelectron spectra of an extensive series of phosphonium ylides, focusing on the substituent effects. Their lowest ionization potential (IP) is associated with the carbanion orbital. Their main results are given in Table 9. A number of important trends can be identified and interpreted. Replacement of the methyl groups on P with phenyl groups reduces the IP of the carbanion. The phenyl group is able to stabilize the P+ charge, which reduces the ability of the phosphonium to stabilize the... 

In comparison to the stabilized phosphonium ylides which fail to react with cv,/3-unsaturated esters or ketones, the corresponding arsonium ylides react smoothly with ,/3-unsaturated esters or ketones (e.g., PhCO—CH=CH—CH3) to form cyclopropanes in fair to good yields. Furthermore, the reaction is stereospecific (45, 45). 

The synthetic utility of a-phosphorus- and a-thio-stabilized carbanions is the subject of numerous reviews.21 Notable are additions of phosphonium ylides (237),183 sulfonium ylides (238),l84 ° oxosulfo-nium ylides (239)184 " and sulfoximine ylides (240)184,1 to electron-deficient alkenes which afford nucleophilic cyclopropanation products. In contrast, with a-(phenylthio)-stabilized carbanions, which are not acyl anion equivalents, either nucleophilic cyclopropanation or retention of the hetero substituent occurs, depending on the acceptor and reaction conditions used. For example, carbanion (241) adds to 1,1-... 

A limited number of other anionic species have been employed as Michael donors in tandem vicinal difunctionalizations. In a manner similar to sulfur ylides described above, phosphonium ylides can be used as cyclopropanating reagents by means of a conjugate addition-a-intramolecular alkylation sequence. Phosphonium ylides have been used with greater frequency261-263 than sulfur ylides and display little steric sensitivity.264 Phosphorus-stabilized allylic anions can display regiospecific 7-1,4-addition when used as Michael donors.265... 

Fig. 11.1. Parent compound of phosphonium ylides (A) and a typical phosphonium ylide (B). Below the Ph3P -CH2 conformer, which is capable of maximum anomeric stabilization, and the corresponding MO diagram.

Fig. 11.2. Working without bases in the Wittig reaction with the (semi)stabilized phosphonium ylide D in-situ formation of this reagent from the alkoxide C resulting from the SN2 ring opening of butylenoxide through the bromide ion of the phosphonium salt A.

Fig. 11.8. trans-Selective Wittig olefination of aldehydes II—Synthesis of /J-carotene from a dialdehyde. The ylide used here is already known from Figure 11.2. In a way, it is "(semi)stabilized" since it is prepared in situ like a semista-bilized phosphonium ylide, but reacts as trans-selectively as a stabilized ylide. 

Carbon nucleophiles may react at the sulfur-sulfur bond, or at C-3. Thus Grignard reagents react with monocyclic dithiol-3-ones (3a) and -3-imines (3c) at S-2 (74LA1261,73LA247). The product (84) of reaction of a Grignard reagent with benzo-1,2-dithiol-3-one (77a) (74T4113) could be alternately formed by attack at S-2, at C-3 or at C-5. Phosphonium ylides or other stabilized carbanions react at the 3-position of dithiol-ones... 

Application of the Wittig reaction in the carbohydrate field is accompanied by certain difficulties. A correct choice of the initial sugar components is the main problem, owing to the basicity of phosphoranes and, especially, to the drastically basic conditions employed with phosphonium ylides (2a). It is not surprising, therefore, that protected (acetalated and aeetylated) aldehydo sugars and resonance-stabilized phosphoranes were used at first,3-5 although partially protected, and even unprotected, aldoses were shown to be amenable to the reaction with various resonance-stabilized phosphoranes, thanks to the presence of the carbonyl form in the mobile equilibrium. The latter reactions, however, are extremely complicated (see Section IV, p. 284). 

Interaction of 4,5 6,7-di-0-cyclohexylidene-2,3-dideoxy-l-C-phe-nyl-L-arafeino-hept-2-enose (65) with phenylmethylenetriphenylphos-phorane was accompanied9 6 by the formation of triphenylphosphine, instead of the expected triphenylphosphine oxide, thus indicating the abnormal character of this reaction. This result may be interpreted as involving possible addition of the phosphonium ylide to the alkenic bond, with subsequent stabilization of the intermediate betaine 82 through elimination of triphenylphosphine, and closure of the three-membered ring2(f) with formation of the cyclopropane derivative 83, as shown in equation 5. 

Sulfonium salts react in several ways. They may behave as a leaving group, undergoing substitution by a nucleophile or fragmenting with the formation of an alkene. However, the most important reaction of sulfonium salts involves the formation of an ylide in the presence of a base. The carbanion of this sulfur ylide is stabilized by the adjacent positively charged sulfonium ion. The reaction of the carbanion with a carbonyl group parallels that of a phosphonium ylide in the Wittig reaction. However, the decomposition of the intermediate dipolar species is different and leads to the formation of an epoxide (oxirane) rather than an alkene. 

---