Carbonyl ylides 1,3-dipolar cycloadditions

An enantioselective version of the above reactions has been reported. Lewis acids such as Yb(OTf)3 can profoundly affect the stereochemical outcome of the carbonyl ylide 1,3-dipolar cycloadditions [137]. This provided an indication to effect asymmetric carbonyl ylide cycloaddition using a chiral Lewis acid. The first example of such asymmetric induction using the chiral lanthanide catalysts has been reported [138,139]. For example, the reaction of diazoacetophenone 89 with benzyloxyacetaldehyde, benzyl pyruvate and 3-acryloyl-2-oxazoHdinone in the presence of chiral 2,6-bis(oxazolinyl)pyridine ligands and scandium or ytterbium complexes furnished the corresponding cycloadducts 165-167 with high enantioselectivity (Scheme 53). 

Over the last 15 years, Padwa et al. (73,74) have been heavily involved with the study and application of carbonyl ylides as cycloaddition precursors in synthesis. Their work has helped make the tandem ylide formation-dipolar cycloaddition process a synthetically accessible transformation. Much of Padwa s early work focused on determining the extent and limitations of this methodology. Many of the early systems were carbocyclic in nature and helped define basic parameters such as... 

The rhodium-catalyzed tandem carbonyl ylide formation/l,3-dipolar cycloaddition is an exciting new area that has evolved during the past 3 years and high se-lectivities of >90% ee was obtained for both intra- and intermolecular reactions with low loadings of the chiral catalyst. 

The application of 1,3-dipolar cycloaddition processes to the synthesis of substituted tetrahydrofurans has been investigated, starting from epoxides and alkenes under microwave irradiation. The epoxide 85 was rapidly converted into carbonyl ylide 86 that behaved as a 1,3-dipole toward various alkenes, leading to quantitative yields of tetrahydrofuran derivatives 87 (Scheme 30). The reactions were performed in toluene within 40 min instead of 40 h under classical conditions, without significantly altering the selectivi-ties [64]. 

Compounds in which a carbonyl or other nucleophilic functional group is close to a carbenoid carbon can react to give ylide intermediate.221 One example is the formation of carbonyl ylides that go on to react by 1,3-dipolar addition. Both intramolecular and intermolecular cycloadditions have been observed. 

Interaction of a carbonyl group with an electrophilic metal carbene would be expected to lead to a carbonyl ylide. In fact, such compounds have been isolated in recent years 14) the strategy comprises intramolecular generation of a carbonyl ylide whose substituent pattern guarantees efficient stabilization of the dipolar electronic structure. The highly reactive 1,3-dipolar species are usually characterized by [3 + 2] cycloaddition to alkynes and activated alkenes. Furthermore, cycloaddition to ketones and aldehydes has been reported for l-methoxy-2-benzopyrylium-4-olate 286, which was generated by Cu(acac)2-catalyzed decomposition of o-methoxycarbonyl-m-diazoacetophenone 285 2681... 

Diels-Alder reaction of the 1,3,4-oxadiazole with the pendant olefin and loss of N2, the C2-C3 7t bond participates in a subsequent 1,3-dipolar cycloaddition with the carbonyl ylide to generate complex polycycles such as 45 as single diastereomers with up to six new stereocenters. That the cascade reaction is initiated by a Diels-Alder reaction with the alkene rather than with the indole is supported by the lack of reaction even under forcing conditions with substrate 46, in which a Diels-Alder reaction with the indole C2-C3 n bond would be required [26a]. 

C6 and C9 are at opposite ends of a four-carbon unit, but since one of these atoms (C7) is saturated and quaternary, a Diels-Alder reaction is unlikely (can t make diene). The combination of a diazo compound with Rh(II) generates a carbenoid at C9. The nucleophile 06 can add to the empty orbital at C9, generating the 06-C9 bond and a carbonyl ylide at C6-06-C9. Carbonyl ylides are 1,3-dipoles (negative charge on C9, formal positive charge on 06, electron deficiency at C6), so a 1,3-dipolar cycloaddition can now occur to join C2 to C6 and Cl to C9, giving the product. Note how a relatively simple tricyclic starting material is transformed into a complex hexacyclic product in just one step ... 

Cyclodditions to Carbonyl Derivatives. Electrophilic transient carbenes are known to react with carbonyl derivatives through the oxygen lone pair to give carbonyl ylides 26.43 These 1,3-dipolar species are usually characterized by [3 + 2]-cycloaddition reactions or can even be isolated44 a small amount of the corresponding oxiranes is sometimes obtained.433,45 To date, no reaction of transient nucleophilic carbenes with carbonyl derivatives has been reported. 

The chemical behavior of heteroatom-substituted vinylcarbene complexes is similar to that of a,(3-unsaturated carbonyl compounds (Figure 2.17) [206]. It is possible to perform Michael additions [217,230], 1,4-addition of cuprates [151], additions of nucleophilic radicals [231], 1,3-dipolar cycloadditions [232,233], inter-[234-241] or intramolecular [220,242] Diels-Alder reactions, as well as Simmons-Smith- [243], sulfur ylide- [244] or diazomethane-mediated [151] cyclopropanati-ons of the vinylcarbene C-C double bond. The treatment of arylcarbene complexes with organolithium reagents ean lead via conjugate addition to substituted 1,4-cyclohexadien-6-ylidene complexes [245]. 

Fig. 4.14. Preparation of polycyclic compounds by intramolecular 1,3-dipolar cycloaddition of carbonyl ylides to alkenes 11301].

Experimental Procedure 4.2.7. Carbonyl Ylide Formation and Intramolecular 1,3-Dipolar Cycloaddition Ethyl 2-Hydroxy-8,9-dimethoxy-3-oxo-1,2,3.5,6,11, 12,13,14,14a-decahydroisoquino[ 1,2-/Iquinoline-2-carboxylate [1143]... 

As with any modern review of the chemical Hterature, the subject discussed in this chapter touches upon topics that are the focus of related books and articles. For example, there is a well recognized tome on the 1,3-dipolar cycloaddition reaction that is an excellent introduction to the many varieties of this transformation [1]. More specific reviews involving the use of rhodium(II) in carbonyl ylide cycloadditions [2] and intramolecular 1,3-dipolar cycloaddition reactions have also appeared [3, 4]. The use of rhodium for the creation and reaction of carbenes as electrophilic species [5, 6], their use in intramolecular carbenoid reactions [7], and the formation of ylides via the reaction with heteroatoms have also been described [8]. Reviews of rhodium(II) ligand-based chemoselectivity [9], rhodium(11)-mediated macrocyclizations [10], and asymmetric rho-dium(II)-carbene transformations [11, 12] detail the multiple aspects of control and applications that make this such a powerful chemical transformation. In addition to these reviews, several books have appeared since around 1998 describing the catalytic reactions of diazo compounds [13], cycloaddition reactions in organic synthesis [14], and synthetic applications of the 1,3-dipolar cycloaddition [15]. 

In more recent work, Chiu and co-workers [167, 168] have reported an intramolecular 1,3-dipolar cycloaddition approach toward the pseudolaric acids 85, in which the di-polarophile is an unactivated 1,1-disubstituted alkene. Hence, treatment of the diazo ketone 86 with catalytic Rh2(OAc)4 furnished a mixture of tricyclic products 87 and 88 in nearly equal proportions (Scheme 19.13). The synthesis of 2-pyridones [169] and their application to the ipalbidine core [170] has been described. The pentacyclic skeleton of the aspidosperma alkaloids was prepared via the cycloaddition of a push-pull carbonyl ylide [171]. The dehydrovindorosine alkaloids 89 have also been investigated, in which the a-diazo-/ -ketoester 90 undergoes a facile cycloaddition to furnish 91 in... 

Padwa has reported an approach to the ring system of the ribasine alkaloids 98 [174], using an intramolecular 1,3-dipolar cycloaddition of the a-diazo ketone 99 to produce the pentacyclic skeleton 100 (Scheme 19.17). Wood [175] used an intermolecular 1,3-dipolar cycloaddition of a carbonyl ylide for the total synthesis of ( )-epoxysorbicilli-nol 101 (Scheme 19.18). The key cycloaddition in this approach is the conversion of 102 to the natural product core 103, which sets the substitution pattern around the entire ring system in a single step. 

Dialkyl-l,2,4-oxadithiolane-2-5 -oxides (160) have been synthesized from the dihydro thia-diazole (161) via nitrogen extrusion and 1,3-dipolar cycloaddition of the intermediate ylide with sulfur dioxide (Scheme 45) <90BSB265>. The formation and trapping of carbonyl oxides is described... 

The proposed reaction pathway invokes initial formation of carbonyl ylide 100 by intramolecular cyclization of the intermediate keto carbenoid onto the oxygen atom of the amide. Subsequent isomerization to the azomethine ylide is followed by 1,3-dipolar cycloaddition to DMAD to furnish the intermediate cycloadduct 101, which undergoes in situ alkoxy 1,3-shift to the final drhydropyrrolizine 102 (Scheme 3.28). 

Carbonyl ylides derived from nitrogen-substituted carbonyl moieties provided for the synthesis of very stable push-pull dipolar intermediates. Although these compounds are quite stable, they still have sufficient reactivity to engage in cycloaddition and related processes. Carbonyl ylides derived from amides have been trapped in intermolecular cycloadditions to give aminals (Scheme 4.34) (56). 

Five-membered carbonyl ylide derivatives form with ease, but tend to suffer from proton-transfer reactions to the carbonyl more readily than their six-membered counterparts. Generally, disubstitution of the position a to the carbonyl led to smooth carbonyl ylide formation and subsequent dipolar cycloaddition (35,77). 

Dittami et al. (170,171) was able to generate a carbonyl ylide via photocycliza-tion of an aryl vinyl ether (Scheme 4.85). The photocyclization proceeded through a six-electron rearrangement providing initially the carbonyl ylide, then subsequent to the cyclization, a dipolar cycloaddition takes place with a pendant olefinic tether. 

One novel and interesting method of generating a silacarbonyl ylide occurred through the addition of a carbonyl species with a silylene formed under photolytic conditions. Komatsu and co-workers (177) found that photolysis of trisilane (315) in solution with a bulky carbonyl species led initially to the formation of a silacarbonyl ylide followed by a dipolar cycloaddition of an olefinic or carbonyl substrate. Reaction of simple, nonbulky aldehydes led to only moderate yields of cycloadduct, the siladioxolane. One lone ketone example was given, but the cycloadduct from the reaction was prepared in very low yield (Scheme 4.89). 

Suga et al. (197) reported the first stereocontrolled 1,3-dipolar cycloaddition reactions of carbonyl ylides with electron-deficient alkenes using a Lewis acid catalyst. Carbonyl ylides are highly reactive 1,3-dipoles and cannot be isolated. They are mainly generated through transition metal carbenoid intermediates derived in situ from diazo precursors by treatment with a transition metal catalyst. When methyl o-(diazoacetyl)benzoate is treated with A-methylmaleimide at reflux... 

Padwa and Prein (105,106) applied chiral, but racemic, isomiinchnone dipoles in diastereoselective 1,3-dipolar cycloadditions. The carbonyl ylide related isomiinch-none derivative rac-70 was obtained from the rhodium-catalyzed cyclization of diazo-derivative rac-69 (Scheme 12.24) (105). The reactions of the in situ formed dipole with a series of alkenes was described and in particular the reaction with maleic acid derivatives 71a-c gave rise to reaction with high selectivities. The tetracyclic products 72a-c were all obtained in good yield with high endo/ exo and diastereofacial selectivities. In another paper by the same authors, the reactions of racemic isomilnchnones having an exo-cyclic chirality was described (106). 

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