Ring rearrangement

Strained or bridged cycles substituted by at least one halide could be rearranged on treatment with silver salts. On the other hand, strained a bonds directly interact with silver ions, leading to bond breakage and thus initiating rearrangement. 

Further studies revealed that the participation of both J and Jt electrons played an important role in controlling the stereochemistry of such rearrangements.16,17 

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We will focus on the development of ruthenium-based metathesis precatalysts with enhanced activity and applications to the metathesis of alkenes with nonstandard electronic properties. In the class of molybdenum complexes [7a,g,h] recent research was mainly directed to the development of homochi-ral precatalysts for enantioselective olefin metathesis. This aspect has recently been covered by Schrock and Hoveyda in a short review and will not be discussed here [8h]. In addition, several important special topics have recently been addressed by excellent reviews, e.g., the synthesis of medium-sized rings by RCM [8a], applications of olefin metathesis to carbohydrate chemistry [8b], cross metathesis [8c,d],enyne metathesis [8e,f], ring-rearrangement metathesis [8g], enantioselective metathesis [8h], and applications of metathesis in polymer chemistry (ADMET,ROMP) [8i,j]. Application of olefin metathesis to the total synthesis of complex natural products is covered in the contribution by Mulzer et al. in this volume. 

Fig. la—d Typical alkene metathesis reactions ring-closing (RCM) and ring-opening (ROM) metathesis (a), diene cross metathesis (CM, b), ROM-RCM (c), and ROM-double RCM (d) sequences (ring-rearrangement reactions, RRM)... 

Blechert s synthesis of the piperidine alkaloid (-)-halosaline (387) by Ru-catalyzed RRM is outlined in Scheme 76 [160]. In the presence of 5 mol% of catalyst A, the ring rearrangement of metathesis precursor 385 proceeded cleanly with formation of both heterocyclic rings in 386. In situ deprotection of the cyclic silyl ether in 386, followed by selective reduction and removal of the to-syl group led to 387. 

A vinyl cation is probably an intermediate in the acetolysis of 6-phenyl-5-hexynyl brosylate, 86. At 80°, despite the inductive effect of the triple bond, the rate of acetolysis of 86 is comparable to that of the saturated analog and yields, besides the acyclic acetate 87, 36% of the rearranged acetate 88 (83). The exclusive formation of the five-membered ring rearranged product with none of... 

One exception to the above general fragmentation pattern is the formation of the ring-rearranged sulfenate (249) in the gas-phase thermolysis of thietane oxide (247a) at elevated temperatures . Although the temperature of this thermolysis is considerably higher than those used in the other studies, it is difficult to account for the (not totally unprecedented ) difference in the results. 

Intramolecular radical cyclization of methylenecyclopropanes accompanies ring rearrangement [115]. In the case of (methylenecyclopropyl)propyl radicals, 5-exo-cyclization is observed as illustrated in Scheme 83, but 6-exo- and 1-endo-cyclizations occur with (methyleneeyelopropyl)butyl radicals, depending on the substituent. (Scheme 83)... 

The rearrangement mechanisms of 5-perfluoroalkyl-l,2,4-oxadiazoles such as the five-to-six membered ring-rearrangements by hydrazinolysis and the photoinduced competitive rearrangements have been investigated <06JOC8106 06JOC2740>. 

Another form of olefin metathesis widely used for piperidine formation is ring-rearrangement metathesis (RRM), as shown below. The versatility of this reaction can be seen in its ability... 

The side products of the reaction between benzoylnitromethane 279 and dipolarophiles (norbornene, styrene, and phenylacetylene) in the presence of l,4-diazabicyclo[2.2.2]octane (DABCO) were identified as furazan derivatives (Scheme 72). The evidence reported indicates that benzoylnitromethane gives the dibenzoylfuroxan as a key intermediate, which is the dimerization product of the nitrile oxide. The furoxan then undergoes addition to the dipolarophile, hydrolysis, and ring rearrangement to the final products (furazans and benzoic acid) <2006EJ03016>. 

Table II also lists several isomerizations and skeletal rearrangements (examples 4-7) which are related to butadiene-ethylene dimerization. Protonation of phosphorus-containing nickel(O) complexes is sufficient to achieve skeletal rearrangement of 1,4-dienes in a few seconds at room temperature, probably via cyclopropane intermediates (example 6, Table II). For small ring rearrangements see Bishop (69).

The ring rearrangement of 8a-(l-hydroxy-alkyl)-hexahydro-oxazolo[3,4- ]pyridin-3-ones 163 upon treatment with sulfuryl chloride was reported in 2004 activation of the alcohol and ring extension produces 5,6-dihydro-l//-oxazolo[3,4-tf]azepin-3-ones 164 in excellent yields (Scheme 48) <2004H(63)17>. 

A further enantioselective synthesis of (+)-T-4 (125), T-6 (128), T-7 (129) and T-8 (126) has been reported by Stragies and Blechert [198]. Key steps are a Pd-catalyzed domino allylation and a Ru-catalyzed metathesis ring rearrangement. Their strategy represents a general approach towards all naturally occurring tetraponerines and will be illustrated here by the description of the syntheses of (+)-T-4 (125) and (+)-T-8 (126) (Scheme 9). 

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