Cross-metathesis-effected

For a discussion on the beneficial effect of using homodimers of one CM substrate in cross metathesis reactions, see Blackwell HE, O Leary DJ, Chatterjee AK, Washenfelder RA, Bussmann DA, Grubbs RH (2000) J Am Chem Soc 122 58... 

Attacking the problem of cross-metathesis selectivity from a different angle, Crowe and co-workers explored the reactivity of a more nucleophilic partner for the Ji-substituted alkenes. They chose to use allyltrimethylsilane since they proposed that the CH2SiMe3 substituent should have a negligible effect on alkyli-dene stability, but enhance the nucleophilicity of the alkene via the silicon P-ef-fect (Fig. 1). 

As expected, there was no formation of stilbenes or a dinitrile product and, more surprisingly, in all of the reactions reported only 5-7% of the allyltrimeth-ylsilane self-metathesis product was observed. It was proposed that this lack of allylsilane self-metathesis was due to the steric bulk of the TMS group reducing the reactivity of the Me3SiCH2 substituted alkylidene. In a more recent report by Blechert and co-workers it was noted that allyltrimethylsilane and its hydrocarbon equivalent (4,4-dimethylpent-l-ene) had comparable reactivities in the cross-metathesis reaction [28], further suggesting that the selectivity arises from steric rather than electronic effects. 

We have also studied the effect that moving the double bond closer to the amino acid moiety has upon the reactivity of unsaturated a-amino acids [43]. To this end, the cross-metathesis reactions of similarly protected homoallyl-, allyl-and vinylglycine with oct-l-ene were investigated under identical conditions (Eq. 25) (Table 3). 

In general, electronically mismatched systems undergo cross metathesis more effectively, see New Approaches to Olefin Cross-Metathesis, H.E. Blackwell, D.J. O Leary, A.K. Chatterjee, et al, J. Am. 

McNaughton, B. R. Bucholtz, K. M. Camaano-Moure, A. Miller, B. L. Self-selection in olefin cross metathesis The effect of remote functionality. Org. Lett. 2005, 7, 733-736. 

Figure 3.14 Toluene (a) and ethane (b) pressure effect on their TON during their crossed metathesis reaction at 250°C (=SiO)2TaH (3) (400mg) ethane/toluene (bar/Torr) A 10/28 B 25/28 C 10/310 D 25/540.

Cross-metathesis enables the efficient preparation of acyclic alkenes and 1,3-dienes on insoluble supports (Figure 5.16). Unfortunately, some types of substrate show a high tendency to yield products of self-metathesis, i.e. symmetrical internal alkenes produced by dimerization of the resin-bound alkene. This is the case, for instance, with allylglycine and homoallylglycine derivatives. Dimerization of the resin-bound alkene can, however, be effectively suppressed by reducing the loading of the support [127]. 

The results of some cross-metathesis experiments for a series of nitriles CH2=CH(CH2) CN reacting with c -hept-3-ene are summarized in Table 4. No crossmetathesis occurs with acrylonitrile (n = 0). For n = 1, 2, 5, 8, 9 cross-metathesis products are formed in substantial amount, but for n = 3, 4 very little reaction occurs, an effect which is attributed to intramolecular coordination of the nitrile group to the metal centre in [Mt]=CH(CH2) CN (n = 3, 4), thereby reducing its metathesis activity or causing its destruction. With n > 5 the nitrile group has little influence on the reaction and its self-metathesis is preferred over that of hept-3-ene, whereas the reverse is true for n = 1,2. 

N-Dienv11richIoroacetamide 174 (11 = 0, R=H) was, however, subsequently also subject to tandem RCM/ATRC catalyzed by the Grubbs II catalyst 175 (Fig. 43) [254]. The yield of 177 in this reaction was reported to be 82-91%, showing that catalyst 175 is also effective in such tandem processes. Tandem cross-metathesis/ ATRC reactions of N- a 11 v 11 ri c h I o ro acetamides with styrenes catalyzed by 175 produced rather low yields of trichlorinated lactams [254]. Almost at the same time Schmidt and Pohler reported similar tandem RCM/ATRC sequences of 1,6-dienyl trichloroacetates with 5 mol% of 175 and of 1,7-dienyl trichloroacetates... 

RCM and CM provide convenient access to a range of intricate products of relevance to the pharmaceutical, agrochemical and fragrance industries. While RCM can effectively create the functionalized carbo- and hetero-cyclic structures common in many such products, cross metathesis is a simple way of introducing often difficult combinations of functional groups. 

It was recognized early that efficient olefin cross metathesis could provide new methods for the synthesis of complex molecules. However, neither (la) nor (2a) were very effective at intermolecular cross metathesis owing to poor reaction selectivity (cross vs. intramolecular metathesis) and low E. Z ratios see (E) (Z) Isomers) The advent of more active and functional group tolerant olefin metathesis catalysts recently made cross metathesis a viable route for constructing a large variety of fimctionalized acyclic alkenes. 

Cross-metathesis of trialkoxy- and trisiloxy-substituted vinylsilanes [21] as well as octavinylsilsesquioxane [15] with vinyl sulfides proceeds efficiently but only in the presence of the 2nd generation Grubbs catalysts (IV) to offer a new and very attractive route for syntheses of [alkyl(aiyl)]sulfide-substituted vinylsilanes and vinyl-silsesquioxane with high preference for the -isomer, as illustrated by exclusive isolation of such isomers. The Fischer-type ruthenium carbene complex Ru(=CHSPh)Cl2(PCy3)2 has recently been reported as an effective catalyst in the ring opening/cross-metathesis of norbomene derivatives with vinyl sulfide [22], suggesting that these carbenes can be reactive in the cross-metathesis. 

The reaction of vinyl-substituted silanes and octavinylsilsesquioxane with vinyl-substituted amides, amines (carbazole) as welt as boronates catalyzed by I proceeds effectively to yield under optimum conditions stereo- and/or regio-selectively l-silyl-2-/V- and 1,1-silylboryl-substituted ethenes. 1-silylvinyl carbazole can also be obtained via cross-metathesis of vinylsilane with vinylcarbazole, but only in the presence of the 2nd generation Grubbs catalyst (IV). 

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