Simmons-Smith cyclopropanation reaction

Diiodomethane, CH2I2 Reacts with alkenes in the presence of zinc-copper couple to yield cyclopropanes (Simmons-Smith reaction Section 7.6). 

In contrast to the polar nature of C-Li and C-MgX bonds, the C-Zn bond is highly covalent and hence less reactive, allowing the preparation of functionalized derivatives. Utilization of organozinc reagents in organic synthesis has mainly centered around the preparation and utilization of functional organozinc compounds in organic syntheses (Reformatsky reaction), cyclopropanation (Simmons-Smith reaction), and transmetalations with transition metals. 

Wolfgang Oppolzer s muscone synthesis is the first enantioselective macrocycli-sation. [195] It starts with pentadec-14-ynal, which is converted by hydro-boration and transmetaUation into the corresponding organozinc compound. The ring closure takes place in the presence of catalytic amounts of a diethylzinc/ (-)ejco-3-(diethylamino)bomeol adduct. After work-up, the cyclic allyl alcohol is obtained in 75 % yield and with an ee of 92 %. The hydroxy-group directs the diastereoselective cyclopropanation (Simmons-Smith reaction). The final steps are a Swern oxidation and selective ring-opening of the cyclopropane under Birch conditions. 

This reaction is called the Smmons-Smith reaction and is one of the few methods avail able for the synthesis of cyclopropanes Mechanistically the Simmons-Smith reaction seems to proceed by a single step cycloaddition of a methylene (CH2) unit from lodomethylzmc iodide to the alkene... 

Yields m Simmons-Smith reactions are sometimes low Nevertheless because it often provides the only feasible route to a particular cyclopropane derivative it is a valu able addition to the organic chemist s store of synthetic methods... 

Simmons-Smith reaction (Section 14 12) Reaction of an alkene with lodomethylzmc iodide to form a cyclopropane denvative... 

It is clear that free CH2 is not involved in the Simmons-Smith reaction, but there is substantial evidence to indicate that caibenes aie formed as intermediates in certain other reactions that convert alkenes to cyclopropanes. The most studied exanples of these reactions involve dichlorocaibene and dibromocaibene. 

Without question, the most powerful method for cyclopropane formation by methylene transfer is the well-known Simmons-Smith reaction [6]. In 1958, Simmons and Smith reported that the action of a zinc-copper couple on diiodomethane generates a species that can transform a wide variety of alkenes into the corresponding cyclopropanes (Scheme 3.3) [7]. 

By application of the Simmons-Smith reaction it is possible to synthesize a cyclopropane from an alkene by formal addition of carbene to the carbon-carbon double bond, without a free carbene being present in the reaction mixture the... 

The Simmons-Smith reaction is well suited for the synthesis of spirocyclic compounds. It has for example been applied for the construction of the fifth cyclopropane ring in the last step of a synthesis of the rotane 8 ... 

A carbene, R2C , is a neutral molecule containing a divalent carbon with only six valence electrons. Carbenes are highly reactive toward alkenes, adding to give cyclopropanes. Nonlialogenated cyclopropanes are best prepared by treatment of the alkene with CH212 and zinc-copper, a process called the Simmons-Smith reaction. 

Simmons-Smith reaction of cyclohexene with diiodomethane gives a single cyclopropane product, but the analogous reaction of cyclohexene with 1,1-diiodoethane gives (in low yield) a mixture of two isomeric methyl-cyclopropane products. What are the two products, and how do they differ ... 

Simmons-Smith reaction (Section 7.6) The reaction of an alkene with CH2l2 and Zn—Cu to yield a cyclopropane. 

The Simmons-Smith reaction has been used as the basis of a method for the indirect a methylation of a ketone. The ketone (illustrated for cyclohexanone) is first converted to an enol ether, an enamine (16-12) or silyl enol ether (12-22) and cyclopropanation via the Simmons-Smith reaction is followed by hydrolysis to give a methylated ketone. A related procedure using diethylzinc and diiodomethane allows ketones to be chain extended by one carbon. In another variation, phenols can be ortho methylated in one laboratory step, by treatment with Et2Zn and... 

The cyclopropanation of 1-trimethylsilyloxycyclohexene in the present procedure is accomplished by reaction with diiodomethane and diethylzinc in ethyl ether." This modification of the usual Simmons-Smith reaction in which diiodomethane and activated zinc are used has the advantage of being homogeneous and is often more effective for the cyclopropanation of olefins such as enol ethers which polymerize readily. However, in the case of trimethylsilyl enol ethers, the heterogeneous procedures with either zinc-copper couple or zinc-silver couple are also successful. Attempts by the checkers to carry out Part B in benzene or toluene at reflux instead of ethyl ether afforded the trimethylsilyl ether of 2-methylenecyclohexanol, evidently owing to zinc iodide-catalyzed isomerization of the initially formed cyclopropyl ether. The preparation of l-trimethylsilyloxybicyclo[4.1.0]heptane by cyclopropanation with diethylzinc and chloroiodomethane in the presence of oxygen has been reported. "... 

Chemo- and stereoselective reduction of (56) to (55) is achieved In highest yield by sodium borohydride in ethanol. The isolated ketone is reduced more rapidly than the enone and (55) is the equatorial alcohol. Protection moves the double bond out of conjugation and even the distant OH group in (54) successfully controls the stereochemistry of the Simmons-Smith reaction. No cyclopropanation occurred unless the OH group was there. Synthesis ... 

Addition of TCS 14 to CH2l2/Zn, which contains up to 0.04 mol% of lead impurity, improves the Simmons-Smith reaction of olefins such as cyclooctene to give up to 96% of the cyclopropane 2103 [36] (Scheme 13.12). 

Zinc promoted reactions are responsive to ultrasonic waves. The classic Simmons-Smith reaction was among our first successes(21). Using zinc powder and diiodomethane we obtained good yields of cyclopropanes from styrene and acenaphthene. However, we could not... 

Two examples of substituted cyclopropane formation are shown below. This reactive zinc should dramatically increase the utility of the Simmons-Smith reaction. 

Bernardi and co-workers investigated the mechanism of the Simmons-Smith reaction theoretically at the DFT (B3LYP) level of theory, using ClCH2ZnCl as a model system.95 Of the two available reaction channels (addition and insertion), the former process was found to have the lower activation energy (107.7 vs. 150.7 kj moP1), and this result correlates well with the exclusive cyclopropanation over the competing insertion reaction. 

Furthermore, cyclopropane structures have often served as intermediates in organic synthesis. For these reasons, olefin cyclopropanation has proved to be a useful tool for synthetic organic chemists. This has led to the development of several methods for cyclopropanation reactions,91 including the metal-catalyzed reactions of diazo compounds with olefins, as well as the Simmons-Smith reaction. 

Taking 1,2-disubstituted cyclopropane as an example, retro synthesis analysis shows that there are three possible ways to disconnect the three-membered ring—a, b, and c as shown in Figure 5-11. Route a involves the addition of methylene across a double bond, and this is often a stereospecific conversion or Simmons-Smith reaction.92 One can clearly see that route b or c will encounter the issue of cis/trans-product formation. 

Among methods of preparing optically active cyclopropane compounds, the Simmons-Smith reaction, first reported in 1958, is of significance. This reaction refers to the cyclopropanation of alkene with a reagent prepared in situ from a zinc-copper alloy and diiodomethane. The reaction is stereospecific with respect to the geometry of the alkene and is generally free from side reactions in contrast to reactions involving free carbenes. 

The Simmons-Smith reaction " and its variants are widely used for the stereospecific synthesis of cyclopropane compounds. The methodology involves the use of copper-treated zinc metal (the zinc-copper couple) with diiodomethane to add methylene to a carbon-carbon double bond. Alternative use of diazomethane in catalytic reactions does not offer the same synthetic advantages and is usually avoided because of safety considerations. As significant as is the Simmons-Smith reaction for cyclopropane formation, its employment for organic synthesis was markedly advanced by the discovery that allylic and homoallylic hydroxyl groups accelerate and exert stereochemical control over cyclopropanation of alkenes (e.g, Eq. 21), and this acceleration has been explained by a transition state model... 

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