Ring-closing olefin metatheses 16- member

Metathesis is the most useful reaction in recent synthetic organic chemistry.In this reaction, bond fission of two double bonds occurs and two new double bonds are simultaneously formed after exchange (Equation (1)). Ring-closing olefin metathesis is now used for the synthesis of five-membered to macrocyclic ring compounds. 

For the cyclization to the 16-membered macrolactone structure of epothilones C and D (= desoxyepothilones A and B, resp. [26]), three different strategies have been used successfully so far (1) Ring-closing olefin metathesis (RCM) between C12 and Cl3. RCM is a comparably new method in total synthesis and underwent enor-... 

The epothilones comprise an important set of natural products that were discovered at a time contemporary with the development of ring-closing olefin metathesis. These materials are 16-membered ring compounds containing an alkene in the macrocycle or an epoxide that can be generated from the alkene. A conventional retrosyntlietic analysis... 

A systematic investigation of the ring-closing metathesis of 138 in the synthesis of a range of fourteen-membered ring lactams 139 and lactones has been reported by Weiler. The geometry of the resulting double bond was determined, the position of the olefin was broadly varied. The ratios obtained were compared to that derived from molecular mechanics calculations, Eq. (15), Table 4 [34]. 

A variety of cyclic olefins (5-, 6-, and 7-membered) that contain nitrogen have been prepared via ring-closing metathesis, for example as shown in Eq. 33 [209]. Other examples are shown in Eqs. 34 [210] and 35 [211]. A variety of pyrrolizi-dines, indolizidines, quinolizidines, pyrrolidinoazocines, piperidinoazocines, and other fused nitrogen heterocycles have also been prepared via ROM (e.g., Eq.36 [212,213]). 

Ring-closing metathesis seems particularly well suited to be combined with Passerini and Ugi reactions, due to the low reactivity of the needed additional olefin functions, which avoid any interference with the MCR reaction. However, some limitations are present. First of all, it is not easy to embed diversity into the two olefinic components, because this leads in most cases to chiral substrates whose obtainment in enantiomerically pure form may not be trivial. Second, some unsaturated substrates, such as enamines, acrolein and p,y-unsaturated aldehydes cannot be used as component for the IMCR, whereas a,p-unsaturated amides are not ideal for RCM processes. Finally, the introduction of the double bond into the isocyanide component is possible only if 9-membered or larger rings are to be synthesized (see below). The smallest ring that has been synthesized to date is the 6-membered one represented by dihydropyridones 167, obtained starting with allylamine and bute-noic acid [133] (Fig. 33). Note that, for the reasons explained earlier, compounds... 

Ring-closing metathesis methodology has been used to access 7-membered ring sultones (e.g. 278, n = 1, m = 1) efficiently from the acyclic diene precursor 277, which could readily be made in turn fom the appropriate olefinic sulfonyl chloride and alcohol [02SL2019]. 

Olefin-containing esters of pyridine-3,5-dicarboxylic acid are able to form macrocycles using a ring-closing metathesis reaction if the pyridine was protected with complexing Pt. The method was applied to 69- and 75-membered macrocycles <03ZOR449>. An example of a 17-membered ring formation is shown below. 

A.B. Smith and co-workers have devised an efficient strategy for the synthesis of the cylindrocyclophane family of natural products. Olefin ring-closing metathesis was used for the assembly of the [7,7]-paracyclophane skeleton. During their investigations they discovered a remarkably efficient CM dimerization process, that culminated in the total synthesis of both (-)-cylindrocyclophane A and (-)-cylindrocyclophane F. They established that the cross metathesis dimerization process selectively led to the thermodynamically most stable member of a set of structurally related isomers. Out of three commonly used ROM catalysts, Schrock s catalyst proved to be the most efficient for this transformation. 

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