Cycloaddition, 1,3-dipolar diazo oxides

Diazomethylene)phosphoranes 33 (Scheme 8.10), which represent another type of diazocumulenes (12) are easily obtained by the oxidative ylidation of the corresponding phosphanyl(trimethylsilyl)diazomethane with CCI4. The increased stability of these compounds as compared with diazocumulenes (R2C=C=N2) is probably due to the ylidic character of the P=C bond. These diazo compounds exhibit the expected dipolar reactivity toward electron-deficient alkenes, alkynes, phosphaalkenes, and heterocumulenes (12). Thus, 33 reacts with TCNE to form A -pyrazoline 35 (60). Furthermore, 33 could be converted into the phosphonio-borate-substituted diazo compound 34, which underwent subsequent cycloaddition with electron-deficient alkenes (e.g., 34 36) (61). 

To use 1,3 dipolar cycloadditions in a retrosynthetic sense, it is necessary to know what 1,3 dipoles are available. The list on pages 319-320 is representative of die more common and useful examples, although many others have been reported. Azides, diazo compounds, and nitrones are normally isolable compounds which can be added to a solution of an olefin. Other 1,3 dipolar species such as nitrile oxides and azomethine ylides are not stable molecules they must be generated in the reaction mixture in the presence of the olefin. As might be expected, many different ways to generate 1,3 dipoles have been developed. 

Similarly small rate factors were obtained for 1,3-dipolar cycloadditions between diphenyl diazomethane and dimethyl fumarate [131], 2,4,6-trimethylbenzenecarbonitrile oxide and tetracyanoethene or acrylonitrile [811], phenyl azide and enamines [133], diazomethane and aromatic anils [134], azomethine imines and dimethyl acetylenedi-carboxylate [134a], diazo dimethyl malonate and diethylaminopropyne [544] or N-(l-cyclohexenyl)pyrrolidine [545], and A-methyl-C-phenylnitrone and thioketones [812]. Huisgen has written comprehensive reviews on solvent polarity and rates of 1,3-dipolar cycloaddition reactions [541, 542]. The observed small solvent effects can be easily explained by the fact that the concerted, but non-synchronous, bond formation in the activated complex may lead to the destruction or creation of partial charges, connected... 

It also participates in dipolar cycloaddition reactions, for example with diazo-compounds [221], nitrile oxides [222], nitril-imines [223] and sulphenes [224]. A mixture of products may be isolated including rearrangement products from the original adducts. 

Unlike the situation with the asterriquinones, a modular synthesis of illudins had already been developed through the efforts of Padwaand Kinder. The dipolar cycloaddition of a carbonyl yhde derived from a diazo-p-diketone with a cyclopentenone forms two C-C bonds and establishes the ring skeleton (Figure 9.7) in the key intermediate. The final carbon was added by a methyl Grignard addition to the more reactive ketone. Oxidation states and functional groups were adjusted to provide dehydroiUudin M, and it was converted to illudin M. 

The 1,3-dipolar systems involved in the cycloaddition reaction with cumulenes include azides, nitrile oxides, nitrile imines, nitrones, azomethine imines and diazo compounds. However, some 1,3-dipolar systems are also generated in the reaction of precursors with catalysts. Examples include the reaction of alkylene oxides, alkylene sulfldes and alkylene carbonates with heterocumulenes. Carbon cumulenes also participate as 1,3-dipols in [3+2] cycloaddifion reactions. Examples include thiocarbonyl sulfides, R2C=S=S, and l-aza-2-azoniaallenes. 

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