3-diazo decompositions

Increasing the temperature of the coupling reaction usually has an unfavorable effect because the diazo decomposition reactions have greater... 

In some technical azo coupling processes the addition of common salt before coupling gives a higher yield. This can be attributed to the different dependences of the reactions rates of coupling and diazo decomposition on ionic strength... 

Abstract The dirhodium(II) core is a template onto which both achiral and chiral ligands are placed so that four exist in a paddle wheel fashion around the core. The resulting structures are effective electrophilic catalysts for diazo decomposition in reactions that involve metal carbene intermediates. High selectivities are achieved in transformations ranging from addition to insertion and association. The syntheses of natural products and compounds of biological interest have employed these catalysts and methods with increasing frequency. 

Diazocarbonyl compounds are especially useful in these reactions because of their ease of formation, relative stability, and controlled reactivity in catalytic reactions [ 1,11 ]. As outlined in Scheme 1, a wide diversity of methodologies are available for this synthesis, with access dependent on the nature of Z. Vinyl- and aryldiazoacetates are accessible by other pathways [2]. The order of reactivity toward diazo decomposition has diazoketones and diazoacetates much more reactive than diazoacetoacetates or diazomalonates. However, the influence of electronic effects on reactivities is more pronounced with phenyl- and vinyl-diazoacetates than with diazoacetoacetates and, especially, diazoacetates [12]. 

Although dirhodium(II) carboxamidates are less reactive toward diazo decomposition than are dirhodium carboxylates, and this has limited their uses with diazomalonates and phenyldiazoacetates, the azetidinone-ligated catalysts 11 cause rapid diazo decomposition, and this methodology has been used for the synthesis of the cyclopropane-NMDA receptor antagonist milnacipran (17) and its analogs (Eq. 2) [10,58]. In the case of R=Me the turnover number with Rh2(45-MEAZ)4 was 10,000 with a stereochemical outcome of 95% ee. 

The starting diazo esters 110 were prepared by diazo transfer from the corresponding malonate esters 109. A selection of chiral Hgands in conjunction with 2mol% (with respect to the diazo compound) of [Cu(OTf)2] in (CH2C1)2 was then examined at 65 °C (Scheme 31). All of the Hgands tested were sufficiently reactive to produce diazo decomposition at 65 °C, although the yields of cyclopropanation products were quite variable. Even tertiary... 

Desymmetrizations by C—H insertion using diazo decomposition strategies is well established. Chiu and coworkers have recently applied this strategy to the oxabicyclic system 195. A ferf-leucine-derived Rh(II) catalyst provided the best results [Eq. (10.58a)]. Wardrop and coworkers have applied a similar strategy en route to sordidin unfortunately, both yield and ee proved to be suboptimal [Eq. (10.58b)] ... 

Padwa et al. (44) studied the diazo-decomposition of 119 and found that the cyclic ylide 120 could be trapped by a variety of heterodipolarophiles such as ethyl cyanoacetate (Mander s reagent) to provide aminal 121 or with benzaldehyde to generate the bicyclic acetal 122. In both cases, only a single isomer was formed, with the regiochemistry easily predicted from frontier orbital considerations. Nair et al. (45) were able to employ the highly functionalized o-quinone 125 for the trapping of carbonyl ylide 124 to provide the highly complex cycloadduct 126 in 76% yield. 

The alternative regiochemical disposition of the diazo and tether of indole 260 failed to deliver any product upon addition of catalyst. Friedrichsen and co-workers (136) also applied this method to amine substituted tethers to generate polyaza-cyclic compounds (Scheme 4.70). The presence of the amino substituted furan subsequent to diazo-decomposition made it possible to cleave the ether bridge through the facility of the amino group formed to produce adduct 263. 

The isomunchnone dipole approach has been successfully applied to the synthesis of alkaloids ( )-lycopodine. As outlined in Scheme 9, 5-methylcyclohexenone 73 was converted to a-diazo imide 74 in seven steps. The diazo decomposition of 74 with Rh2(pfb)4 in CH2CI2 at 25 °C gives expected tandem ylide cycloaddition products 76 and... 

An alternative approach in the asymmetric catalysis in 1,3-dipole cycloaddition has been developed by Suga and coworkers. The achiral 1,3-dipole 106 was generated by intramolecular reaction of an Rh(ii) carbene complex with an ester carbonyl oxygen in the Rh2(OAc)4-catalyzed diazo decomposition of <9-methoxycarbonyl-o -diazoacetophenone 105 (Scheme 12). The asymmetric induction in the subsequent cycloaddition to G=G and G=N bond was achieved by chiral Lewis acid Sc(iii)-Pybox-/-Pr or Yb(iii)-Pybox-Ph, which can activate the dipolarophile through complexation. With this approach, up to 95% ee for G=0 bond addition and 96% ee for G=G bond addition have been obtained, respectively. ... 

Similar to those of oxygen and sulfur ylide, ammonium ylide or azomethine ylide can be generated by the interaction of metal carbene and amine or imine, respectively. As is the case of sulfur, nitrogen also has a strong coordinating ability to a metal complex. Consequently, metal complex-catalyzed diazo decomposition in the presence of an amine or imine usually requires high reaction temperatures (Figure 6). 

The cyclic ammonium ylide/[l,2]-shift approach has been successfully applied by West and Naidu to a key step in the total synthesis of (—)-epilupinine, one of the biologically active lupin alkaloids. Cu(acac)2-catalyzed diazo decomposition of enantiomeric pure diazoketone 160 in refluxing toluene generates a spiro ammonium ylide 161 and 162, which then undergoes [l,2]-shift to give rise to a quinolizidine skeleton as a mixture of diastereomers (95 5) (Scheme Major diastereomer 164 has enantiomeric purity of 75% ee. The partial retention of stereo-... 

Doyle and co-workers have recently reported Rh(ii) or copper complex-catalyzed reaction of aryldiazoacetate or vinyldiazoacetate with imines. " Diastereoselective aziridine formation is observed in the Rh2(OAc)4-catalyzed diazo decomposition of diazo phenylacetate in the presence of arylimine (Equation (28)). " When the reaction was carried out with aldehyde, epoxide 187 was obtained. 

In addition to copper and rhodium catalysts commonly used in the generation of metal carbene complexes, other transition metals have also been explored in the diazo decomposition and subsequent ylide generation.Che and co-workers have recently studied ruthenium porphyrin-catalyzed diazo decomposition and demonstrated a three-component coupling reaction of a-diazo ester with a series of iV-benzylidene imines and alkenes to form functionalized pyrrolidines in excellent diastereoselectivities (Scheme 20). ... 

Electron-withdrawing substituents generally increase diazo compounds stability toward decomposition. Dicarbonyl diazomethane, which bears two carbonyl groups flanking the diazomethane carbon, are more stable than diazo compounds with only one carbonyl substituent. In general, metal catalysed decomposition of dicarbonyl diazomethane requires higher temperature than does monocarbonyl substituted diazomethane. As indicated before, rhodium(II) carboxylates are the most active catalysts for diazo decomposition. With dicarbonyl diazomethane, the rhodium(II) carboxylate-promoted cyclopropanation process can also be carried out under ambient conditions to afford a high yield of products. 

Keywords Asymmetric C-H insertion, C-H activation, [3+4] cycloaddition, [3+2] cycloaddition, 1,3-dipolar cycloaddition, Rhodium-catalyzed diazo decomposition... 

Titanium(IV) enolates derived from a-diazo-/i-keto esters or ketones (28) efficiently add to T1CI4-activated A-tosylimines to give the corresponding 5-A-tosylamino derivative.76 Subsequent diazo decomposition - catalysed by rhodium(II) or light - yields useful pyrroles or y -lactams, respectively. 

A similar reaction of ylide 200 can also be carried out under thermal conditions or in the presence of catalytic amounts of Cu(acac)2 [143]. The carbenoid reactions of iodonium ylides can also be effectively catalyzed by rhodium(II) complexes [144, 145]. The product composition in the rhodium(II) catalyzed reactions of iodonium ylides was found to be identical to that of the corresponding diazo compounds, which indicates that the mechanism of both processes is similar and involves metallocarbenes as key intermediates as it has been unequivocally established for the diazo decomposition [144]. 

Rhodium acetate-catalyzed diazo decomposition has been used in a synthesis of the pyrrole 51, illustrating a route to several similar 3-oxypyrrole systems (Equation 11) <2002SL1913>. Similar annulations of some related fluorine containing substrates resulted in various unusual fluoropyrrole derivatives <20030L745>. 

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