Cyclopropyl derivatives reduction

A general type of chemical reaction between two compounds, A and B, such that there is a net reduction in bond multiplicity (e.g., addition of a compound across a carbon-carbon double bond such that the product has lost this 77-bond). An example is the hydration of a double bond, such as that observed in the conversion of fumarate to malate by fumarase. Addition reactions can also occur with strained ring structures that, in some respects, resemble double bonds (e.g., cyclopropyl derivatives or certain epoxides). A special case of a hydro-alkenyl addition is the conversion of 2,3-oxidosqualene to dammara-dienol or in the conversion of squalene to lanosterol. Reactions in which new moieties are linked to adjacent atoms (as is the case in the hydration of fumarate) are often referred to as 1,2-addition reactions. If the atoms that contain newly linked moieties are not adjacent (as is often the case with conjugated reactants), then the reaction is often referred to as a l,n-addition reaction in which n is the numbered atom distant from 1 (e.g., 1,4-addition reaction). In general, addition reactions can take place via electrophilic addition, nucleophilic addition, free-radical addition, or via simultaneous or pericycUc addition. 

Reductive 1,3-elimination reaction of alkyl dihalides constitutes one of the classical methods for the preparation of cyclopropyl derivatives and is particularly useful for the synthesis of highly strained polycyclic hydrocarbons. A new preparation method of [l.l.ljpropellane, more versatile than the original Wiberg s method, has been devised3,4. Thus, treatment of l,l-dibromo-2,2-bis(chloromethyl)cyclopropane with alkyllithium or lithium powder affords [1.1. ljpropellane by two successive 1,3-eliminations of halogens by way of 1 -bromo-2-(chloromethyl)bicyclo[l. 1. Ojbutane (equation 1). This method has been... 

Electron-deficient alkenes, either these with conjugating substituents or of enones, undergo Michael-like additions with regiospecific introductions of the nucleophiles, and this approach has been successful for the formation of cyclopropyl derivatives—notably from some nucleosides. An example involves the addition of the anion of bis(phenylsulfonyl)methane to the phenylselenone 173 which gives the adduct 174 in 35% yield. This reaction presumably occurs by Michael addition to C-2 followed by Sn2 ring-closure reaction at C-3 with displacement of phenylselenic acid. Reductive desulfonylation affords the 2,3,-dideoxy-2,3 -cyclopropayuridine 175.199... 

The ring expansion of the benzoxepinones 134 to benzoxocinones 136 involved a cyclopropanation with diazomethane in the presence of palladium acetate and a catalytic hydrogenation. The cleavage of the more labile internal bond in the cyclopropyl derivatives 135 leads to the eight-membered ketones 136 exclusively in excellent yields (90-95%). Reduction of ketones 136 with sodium borohydride affords the hydroxy derivatives 137 in a stereo-controlled manner (Scheme 34) <2002CC634>. 

An example of an indirect formation of a cyclopropyl ring from an activated olefin was also reported . A Michael addition of thiophenol to an a,j -unsaturated ketone followed by a chemical reduction (e.g. NaBH4) yielded an alcohol which was converted to the methanesulfonate of the y-phenylthioalcohol (8). When the latter is reduced electrochemi-cally a cyclopropyl derivative is obtained. 

In a paper published along with that of Stevens and Wentland20 and in agreement with these authors, Keely and Tahk23 reported the independent synthesis of dl-mesembrine, also from I-methyl-3-(3,4-dimethoxyphenyl)-2-pyrroline and methyl vinyl ketone. In their work the cyclopropyl derivative 3b was prepared from the reaction of the anion of 3,4-dimethoxyphenylacetonitrile (lc) with ethylene dibromide in dimethyl sulfoxide and its sodium salt as solvent and base. Reduction with ethereal diisobutylaluminum hydride gave the aldehyde, which was condensed with excess methylamine in benzene-ether solution with calcium oxide as the dehydrating agent. 

Modhephene, 34, was the first isolated propellane natural product. As such, the Weiss-Cook reaction was the perfect method for its construction. The process began with the condensation of 2 with diketone 27. Standard conditions for decarboxylation produced the core scaffold 28. Hydrogenation of the mono-enol phosphate afforded the monoketone 29. The cyclopropyl derivative 30 was prepared by copper-catalyzed decomposition of a diazoketone. gem-Dimethylation to generate 31 preceded carboxylation and esterification to afford the advanced intermediate 32. Cuprate-induced cyclopropane ring opening and methylation of the 3-ketoester introduced the final carbon atoms giving rise to 33. Lithium iodide induced decarboxylation preceded reduction of the ketone followed by dehydration with Martin s sulfurane, thus producing 34. 

Base treatment of the bromomethylpenam also yielded the cephem 172 (Kamiya et al., 1975), together with the novel tricyclic penam 173. Theorizing that inhibition of the episulfonium ion composition would enhance the formation of the cyclopropyl derivative. Kamiya and co-workers reacted the penam sulfoxide (174) with base to give the tricyclic sulfoxide (175) together with the isothiazolone sulfoxide (176). Reduction of 175... 

The catalytic system based on Cu(0Ac)2-H20 and ligand L8 in combination with PhSiH3 as a hydride source also proved efficient in the reduction of aryl- and heteroaryl cycloaUcyl ketones (Scheme 11) [23]. The substrate scope was probed employing different size cycloalkyl groups along with variation of the aromatic or heteroaromatic fragment. Cyclopropyl derivatives proved particularly difficult ... 

The key cyclization in Step B-2 was followed by a sequence of steps that effected a ring expansion via a carbene addition and cyclopropyl halide solvolysis. The products of Steps E and F are interesting in that the tricyclic structures are largely converted to tetracyclic derivatives by intramolecular aldol reactions. The extraneous bond was broken in Step G. First a diol was formed by NaBH4 reduction and this was converted via the lithium alkoxide to a monomesylate. The resulting (3-hydroxy mesylate is capable of a concerted fragmentation, which occurred on treatment with potassium f-butoxide. 

The cuprate derived from the cis isomer of this reagent undergoes conjugate addition with cyclohexenone with unusually high diastereoselectivity (5 1, Eq. 23)24). In this case, electrophilically initiated ring opening with mercuric acetate chemo-selectively attacks the sterically least hindered cyclopropyl bond to give a branched product 7. Reductive work-up produces 8 in which the stereochemistry of the... 

The cyclopropyl analogs were made from the aminoalcohol 977, prepared from 976 by reaction with 6-chloroisocytosine followed by nitrosation to give the 5-nitroso derivative, which upon reduction in the presence of formic acid gave 979 as a mixture with its formyl derivative 978. Ring closure of... 

The former reduction is thought to occur by two single electron transfers (SET) from the metal surface to the cyclopropane derivative providing a halide and cyclopropyl anion initially. The latter is protonated by the solvent thus leading to the monohalogen derivative which can undergo the reduction process for a second time. 

The rearrangement exhibits some stereochemical preference for c/s-vinyl carbene complex (with respect to the metal) compared to the //ww-isomer. Thus, 2-methyl-2-m-vinyl cyclopropyl (methoxy) carbene chromium pentacarbonyl rearranges to 5-methyl-5-vinyl-2-methoxycyclopentenone approximately 4 times faster (THF, 52 °Q than the trans-isomer, which in turn rearranges faster than phenyl derivatives. This suggests that vinyl complexes undergo initial Cope-type rearrangement to form metallacycloheptadienes, which then rearrange to jt-allyl complexes. Subsequent CO insertion and reductive elimination leads to the vinylcyclopentenones (equation 89)150. 

The silver ion assisted carbon-halogen bond cleavage and the unraveling of the cyclopropane ring by the cyclopropyl-allyl rearrangement was first noted in the formation of 2-bromocyclohexen-l-ol from dibromobicyclo[3.l.0]hexane under solvolytic conditions (equation 86).220 The silver ion assisted solvolysis of the dihalocyclopropane adduct (43), derived from a Birch reduction product, smoothly rearranges to the tropone (equation 87).221 A number of other synthetic applications222-226 have beien reported... 

The unusual structure of cycloclavine as the first known pentacyclic clavine alkaloid was derived from physical data (mass spectrum M+ 238 NMR signals of the cyclopropyl methylene group = 0.46 and 1.60) and some chemical transformations (hydrogenation, reductive ring opening, and quaternization). The remaining details of its constitution were finally determined by an X-ray analysis of the metho-bromide. Thus it was shown that the chirality of 11 is 5B, 8R, 10R. 

A number of side reactions have been reported to occur during Wolff-Kishner reductions in addition to those discussed above. In particular, cleavage of strained rings located adjacent to the carbonyl may accompany reduction to afford saturated and/or alkene products. For example, the pentacyclic diketone (41) afforded the unsaturated tetracyclic compound (42) and saturated derivative (43) in addition to the normal Wolff-Kishner product (44 equation 13). Likewise, the cyclopropyl ring in alkaloid (45) suffered cleavage during reduction to give the alkene (46 65% equation 14). ... 

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