Z-Olefins

With "non-stabilized" ylides the Wittig Reaction gives predominantly Z-olefins. Seebach et al... 

CF3CF420- groups make the betaine less stable, giving more Z-olefin. 

Subsequent dehydrohalogenation afforded exclusively the desired (Z)-olefin of the PGI2 methyl ester. Conversion to the sodium salt was achieved by treatment with sodium hydroxide. The sodium salt is crystalline and, when protected from atmospheric moisture and carbon dioxide, is indefinitely stable. A variation of this synthesis started with a C-5 acetylenic PGF derivative and used a mercury salt cataly2ed cyclization reaction (219). Although natural PGI has not been identified, the syntheses of both (6R)- and (65)-PGl2, [62777-90-6] and [62770-60-7], respectively, have been described, as has that of PGI3 (104,216). 

The mechanism is supported by findings from the decomposition reaction of the amine oxides derived from threo- and cryt/zro-2-amino-3-phenylbutane. The t/zrco-amine oxide 6 yields -2-phenylbut-2-ene 7 with a selectivity of 400 1, and the cryt/zro-derivative 8 yields the Z-olefin 9 with a selectivity of 20 1 ... 

Wide variations in stereoselectivity are possible between the and Z isomers (79). In hydrogenation of several ( )- and (Z)-a-acylaminocinnamic acid derivatives, the Z isomers gave greater enantiomeric excesses at 15-100 times the rate of reduction of the isomer, but in all cases the 5 enantiomer was formed in greater excess (//7). The greater effectiveness of Z-olefins is general If8). 

The key intermediate 25 was prepared efficiently from aldehyde 23, obtained by reduction of nitrile 22 with Dibal-H. Treatment of 23 with the lithium salt of frans-diethyl cinnamylphosphonate furnishes compound 24 in 75 % yield and with a 20 1 ratio of E Z olefin stereoisomers. The stage is now set for the final and crucial operations to complete the molecular skeletons of endiandric acids A and B. 

Simple diastereoselection in the reactions of 2-butenylboron compounds and aldehydes is critically dependent on the configurational stability of the reagentslb. As a general rule, most 2-bulenylorganometallics arc sensitive to sequential 1,3-metal shifts (1,3-metallotropic rearrangements) that result in E- to Z-olefin isomerization via the l-methyl-2-propenylmetal isomer. 

Bulcnyl)-9-borabicyclo[3.3.1]nonanc is configurationally unstable and consists of a rapidly interconverting mixture of E- and Z-olefin isomers. 

The reactions of allylboronates 1 (R = H or CH3) may proceed either by way of transition state 3, in which the a-substituent X adopts an axial position, or 4 in which X occupies an equatorial position. These two pathways are easily distinguished since 3 provides 7 with a Z-olefin, whereas 4 provides 8 with an E-olefinic linkage. There is also a second fundamental stereochemical difference between these two transition states 7 and 8 are heterochirally related from reactions in which 1 is not racemic. That is, 7 and 8 arc enantiomers once the stereochemistry-associated with the double bond is destroyed. Thus, the selectivity for reaction by way of 3 in preference to 4, or via 6 in preference to 5 in reactions of a-subsliluted (Z)-2-butenylboronate 2, is an important factor that determines the suitability of these reagents for applications in enantioselective or acyclic diastereoselective synthesis. 

Lithium dimethyl and diphenylcuprates add to (phenylsulfonyl)acetylene with complete syn-stereoselectivity leading to -olefins 121. In the case of di-n-butyl and di-s-butylcuprates, 5-20% of Z-olefins 122 are also formed (equation 96)80. 

On one hand, /z-alkanes of the molecular range C10-C16 are important starting materials for the synthesis of anionic surfactants. It is possible to dehydrogenate these hydrocarbons to isomeric /z-olefins with internal double bonds olefins) [4], which are also important initial products for the synthesis of an-... 

Apart from the UOP Pacol process, today s only other meaningful economic process is the Shell higher olefin process (SHOP) in which /z-olefins are produced by ethylene oligomerization. Until 1992 Hiils AG used its own technology to produce -60,000 t/year of /z-olefins by the chlorination of /z-paraffins (from Molex plant) and subsequent dehydrochlorination [13]. In the past, the wax cracking process (Shell, Chevron) played a certain role. In the Pacol and Hiils processes, olefins are obtained as diluted solutions in paraffin (Pacol to max. 20%, Hiils about 30%) without further processing these are then used for alkylation. In contrast, the SHOP process produces pure olefins. 

The LAB production process (process 1) is mainly developed and licensed by UOP. The N-paraffins are partially converted to internal /z-olefins by a catalytic dehydrogenation. The resulting mixture of /z-paraffins and n-olefins is selectively hydrogenated to reduce diolefins and then fed into an alkylation reactor, together with an excess benzene and with concentrated hydrofluoric acid (HF) which acts as the catalyst in a Friedel-Crafts reaction. In successive sections of the plant the HF, benzene, and unconverted /z-paraffins are recovered and recycled to the previous reaction stages. In the final stage of distillation, the LAB is separated from the heavy alkylates. 

It also explains the /Z selectivity of products at low conversions (kinetic ratio. Scheme 19). In the case of propene, a terminal olefin, E 2-butene is usually favoured (E/Z - 2.5 Scheme 19), while Z 3-heptene is transformed into 3-hexene and 4-octene with EjZ ratios of 0.75 and 0.6, respectively, which shows that in this case Z-olefins are favoured (Scheme 20). At full conversion, the thermodynamic equilibriums are reached to give the -olefins as the major isomers in both cases. For terminal olefins, the E olefin is the kinetic product because the favoured pathway involved intermediates in which the [ 1,2]-interactions are minimized, that is when both substituents (methyls) are least interacting. In the metathesis of Z-olefins, the metallacyclobutanes are trisubstituted, and Z-olefins are the kinetic products because they invoke reaction intermediates in which [1,2] and especially [1,3] interactions are minimized. 

Figure 9 Table comparing the activity of the E and Z olefin and butyne analogues of WIN54954.

The difference in activity of the E and Z olefins against HRV-14 was explained by examining the relatively low energy virus-bound conformations. The result of an overlay of WIN-54954 (based on x-ray crystallography data), minimize E- and Z-olefinic structures and the butyne analogue, suggested that the E isomer showed a reasonable fit while the Z isomer did not. Furthermore, when the Z isomer was inserted into the HRV-14 pocket, unfavorable interactions occurred. 

Olefins analogous to 158 and 159 were also isolated from the CuS04-catalyzed decomposition of ethyl diazoacetate in the presence of 2-isopropenyl-2-methyl-1,3-dithiane (total yield 56%, E Z — 4 1) a butadiene was absent from the reaction mixture 161). With dimethyl diazomalonate instead of ethyl diazoacetate, only the Z-olefin resulting from a [2,3]-sigmatropic rearrangement of the corresponding sulfur ylide was obtained in 36 % yield 161). When the same procedure was applied to... 

Pd(PPh3)4 and N,N -dimethyl-NfNf-propylene urea (DMPU). The product of this reaction 315 was a key intermediate in the synthesis of (Z)-olefinic RNA containing adenine and thymine as bases. 

Two di-tritiated isocarbacyclin methyl esters 116 and 117 in the title have been synthesized95 from (Z)-olefinic precursors 118 and 119 at the >-side chain by catalytic hydrogenation with tritium gas (equations 44 and 45). The therapeutic candidates for cardiovascular deseases96, 116 and 117, were required for preclinical studies and for use in RIA analysis. 

Palladium-catalyzed cyclization of alkenes and alkynes were reported by Balme and co-workers.143 144 Intramolecular carbopalladation occurs to give polycyclic compounds. It has been shown that the nucleophile type has a large influence on the cyclization process. Both 5-exo- and 6-endo-cyclization are observed for substrates with nitrile (116 and 118) and ester (120, 122, and 124) substituents, respectively (Scheme 36). When a mixed nucleophile (CN and C02Me) is used, a mixture of 5-exo and 6-endo products is obtained. The chemoselectivity is controlled by the size of the nucleophile used. The stereochemistry of the initial double bond plays an important role on the stereoselectivity of the cyclization. (Z)-olefins (118 and 120) and (/. )-olefins (116 and 124) afford as- (119 and 121) and trans-cyclization products (117 and 123), respectively. 

Zhang54 published the first and only account of a non-asymmetric rhodium-catalyzed Alder-ene cycloisomerization of 1,6-enynes.55 The conditions developed by Zhang and co-workers are advantageous in that, similar to the ruthenium conditions developed by Trost, selectivity for 1,4-diene products is exhibited. The rhodium conditions are dissimilar from many other transition metal conditions in that only (Z)-olefins give cycloisomerization products. 

The total synthesis of rifamycin S was one of Kishi s many achievements in organic synthesis.6 Kishi recognized that a certain type of (Z)-olefin such as 51 tends to take a conformation in which C-l, C-2, C-3, and H-3 are nearly co-... 

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