Spiro epoxides

Isolated carbonyls always give epoxides from the Corey-Chaykovsky reaction. Take the aldehyde substrate as an example. Spiro epoxide 30 was produced from the reaction of trisnorsqualene aldehyde 28 (R20 represents the polyene side-chain with 20 carbons) with substituted sulfur ylide 29, prepared in situ from cyclopropyldiphenylsulfonium tetrafluoroborate and KOH. " For the epoxidation of ketones, the Corey-Chaykovsky reaction works well for diaryl- (31), arylalkyl- (32), ... 

In spite of their intrinsic synthetic potential, addition reactions of metal enolates of non-stabilized esters, amides, and ketones to epoxides are not widely used in the synthesis of complex molecules. Following the seminal work of Danishefsky [64], who introduced the use of Et2AlCl as an efficient catalyst for the reaction, Taylor obtained valuable spiro lactones through the addition reaction of the lithium eno-late of tert-butyl acetate to spiro-epoxides, upon treatment of the corresponding y-... 

Many other reagents for converting alkenes to epoxides,including H2O2 and Oxone , VO(0-isopropyl)3 in liquid C02, ° polymer-supported cobalt (II) acetate and 02, ° and dimethyl dioxirane.This reagent is rather versatile, and converts methylene oxiranes to spiro-epoxides. ° ° One problem with dimethyloxirane is C—H insertion reactions rather than epoxidation. Magnesium monoperoxyphthalate is commercially available, and has been shown to be a good substitute for m-chloroperoxybenzoic acid in a number of reactions. 

DL-Valiolamine (205) was synthesized from the exo-alkene (247) derived from 51 with silver fluoride in pyridine. Compound 247 was treated with a peroxy acid, to give a single spiro epoxide (248, 89%) which was cleaved by way of anchimeric reaction in the presence of acetate ion to give, after acetylation, the tetraacetate 249. The bromo group was directly displaced with azide ion, the product was hydrogenated, and the amine acety-lated, to give the penta-A, 0-acetyl derivative (250,50%). On the other hand. 

They also prepared valienamine derivative (+)-227 from the ditosylate (294) derived from 286. The spiro epoxide (295) obtained from 294 was converted into 296 by treatment with selenoxobenzothiazole-tri-... 

The endo-spiro-OZT could be prepared through a reaction sequence similar to that applied for the exo-epimer, with spiro-aziridine intermediates replacing the key spiro-epoxides (Scheme 18). Cyanohydrin formation from ketones was tried under kinetic or thermodynamic conditions, and only reaction with the d-gluco derived keto sugar offered efficient stereoselectivity, while no selectivity was observed for reaction with the keto sugar obtained from protected D-fructose. The (R) -cyanohydrin was prepared in excellent yield under kinetic conditions (KCN, NaHC03, 0 °C, 10 min) a modified thermodynamic procedure was applied to produce the (S)-epimer in 85% yield (Scheme 18). 

Another route to a methyl-branched derivative makes use of reductive cleavage of spiro epoxides ( ). The realization of this process was tested in the monosaccharide series. Hittig olefination of was used to form the exocyclic methylene compound 48. This sugar contains an inherent allyl alcohol fragmenC the chiral C-4 alcohol function of which should be idealy suited to determine the chirality of the epoxide to be formed by the Sharpless method. With tert-butvl hydroperoxide, titanium tetraisopropoxide and (-)-tartrate (for a "like mode" process) no reaction occured. After a number of attempts, the Sharpless method was abandoned and extended back to the well-established m-chloroperoxybenzoic acid epoxida-tion. The (3 )-epoxide was obtained stereospecifically in excellent yield (83%rT and this could be readily reduced to give the D-ribo compound 50. The exclusive formation of 49 is unexpected and may be associated with a strong ster chemical induction by the chiral centers at C-1, C-4, and C-5. 

Two examples using i-BuLi/(—)-sparteine mixture as base have been reported to promote effective allylic alcohols formation in moderate ee for the spiro epoxide 82 and cyclooctadiene oxide 83 ° (Scheme 33). In the last case, such regioselectivity could be explained by the relatively flat conformation of the medium-sized oxirane which favors the syn base-oxirane complex (see Section n.A). 

Photolysis of spiro epoxide 72 (20) led to formation of carbonyl ylide 73. Although the ylide failed to react with either electron-rich or electron-poor... 

With the spiro-epoxides of branched-chain sugars, the oxirane protons appear somewhat farther upfield, between r 6.8 and 7.5, the two protons showing a variable difference in chemical shift.224,227... 

In the somewhat related reaction of glycopyranosiduloses with diazomethane, spiro-epoxides were the major products, but reaction with diazoethane gave ring-expansion products exclusively.170 The formation of the latter was rationalized in terms of nonbonded interactions in the transition states leading to spiro-epoxides. It was also considered that steric effects determine which of the two ring-expansions possible occur. 

Another total synthesis of sufentanil has been described the cyclization of 2-(2-thienyl)ethylamine with allyl-trimethylsilane and formaldehyde gives 4-hydroxy-1-[2-(2-thienyl)ethyl]piperidine, which is oxidized with oxalyl chloride in DMSO/dichloromethane to 1-[2-(2-thienyl) ethyl]piperidin-4-one. The epoxidation of this compound by means of trimethylsulfonium iodide and the sodium salt of DMSO yields the spiro-epoxide, which is opened with... 

The mild neutral reaction conditions permit to transform allenes to sensitive spiro-epoxides and norbomadiene to exo monoepoxide or exo,exo diepoxide ... 

Branched sugar (A) Spiro-epoxide Alkylldene derlv. Branched nltro sugar... 

Spiro epoxides are also valuable intermediates for the synthesis of type I branched-chain sugars. These spiro epoxides are formed from ketosugars using diazomethane addition or sulfonium chemistry. Further ring opening of the epoxide allows the introduction of various nucleophiles [1], Chloro spiroepoxide 15 (Scheme 9) has been prepared recently from ketosugar 1 dichloromethyllithium [28]. 

Spiro epoxidation of a -enones.1 The conversion of ketones to spiro epoxides is usually carried out with dimethylsulfonium methylide, but this reaction can proceed in low and variable yields when extended to a,p-enones. A generally useful route to these vinyl spiro epoxides involves addition of 1, methylation, and ring closure with base, as illustrated for cyclohexenone. 

The mechanism of reaction 285 proposed previously568 has been reinvestigated567 by synthesizing the [4-2H]exomethylene cephalesporin C, 477b, by electrolysis of 476 in a deuteriated buffer. Incubation of 477b with DAOC/DACS provided 475, and also the spiro-epoxide cepham 478. The ratio of 475 to 478 varied with the overall degree of... 

Equatorially positioned methyl-branched derivatives may be obtained by reductive cleavage of spiro epoxides [94], Thus the Peterson olefination of 188gives the exocyclic 3 -methylene function in 189. By means of a Sharpless epoxidation the allylic 4"-hydroxy group should determine the chirality of the resulting epoxide. However, the Sharpless method does not show any reaction neither in a monosaccharide model system nor in this trisaccharide precursor [95]. Amazingly, the classical epoxidation with m-chloroperbenzoic acid is employed to give exclusively the desired (3"R) epoxide 190 in excellent yield. These results may be associated with a sufficient chiral induction of the stereochemical information at C-l", C-4", and C-5". A subsequent reduction furnishes the original E-D-C trisaccharide sequence 191 of mithramycin [95, 96]. 

Vicinally donor-acceptor-substituted olefins usually are rather unreactive species. Nevertheless cyclopropanation of 2,2-dimethyl-3(2 H)-furanone 70 could be executed with dimethyl oxosulfonium methylide as a methylene source. The bicyclic compound 71 is formed in modest yield accompanied by the spiro epoxide as a second product in almost equal amounts. Carbinols 72 derived from 71 by alkyl lithium addition can be nitrosated and photolyzed to suffer a Barton fragmentation. The resulting y-oxoaldehydes are directly cyclized to afford the 2-substituted cyclopentenones 73 in good yield 41. ... 

Spiro epoxides with phenylsulfonyl substituents are important sources of a,j -unsaturated aldehydes. These may be prepared by displacement of chloride by an adjacent hydroxyl group (in an a-chloro-/ -hydroxysulfoxide) in the presence of base942,943. This procedure has been used in the total synthesis of alkaloids such as ( )-suaveoline944. 

Sequential reaction of the spiro-epoxide (139), derived from 3-ethoxyandrosta-3,5-dien-17-one and Me3S+F, first with chloranil to establish the A4,6-3-oxo-function and then with diethyl malonate, allowed the isolation of the spiro-steroid (140 R = C02Me). Saponification and decarboxylation led to the derivatives (140 R = C02H) and (140 R = H) respectively.54 It has been demonstrated that the... 

Compound 191 was transformed into the exo-alkene 193 via the respective spiro epoxide the enone 192 (11%) was obtained as a side product (Scheme 24).97 Compound 193 was deprotected, and the triol obtained was selectively mesylated at the allylic position to give, after acetylation, compound 194 (68%). Treatment of 194 with sodium acetate resulted in the inversion of configuration at C-l to give the tetra-N,O-acetyl derivative 195. Oxidation of 195 with osmium tetraoxide in aqueous acetone, followed by acetylation, afforded 196 (87%) and 197 (13%), whose acid hydrolysis provided the free bases 5 and 37, respectively. 

Alternatively, synthesis of compound 215 (4-epimer of 208) started by initial inversion of the OH group at C-l of 207 (Scheme 27).35,96,99 101 Acid hydrolysis of 207 gave the triol 209 (100%), which was identified as its tetraacetate 210, whose allylic hydroxyl group was selectively sulfonylated with mesyl chloride to afford 211, which was then converted into the acetate 212 (65%). On treatment with an excess of sodium acetate in DMF, 212 afforded 213 (60%). Oxidation of 213 with osmium tetraoxide gave, after acetylation, 214 and 216. Furthermore, epoxidation of 213 gave a single spiro epoxide 214 (64%), which was transformed exclusively into 216 (83%)... 

The aminocyclitol d-48 was synthesized from l-218 (Scheme 28).103 Since direct peroxyacid oxidation of the exo-methylene group of compound l-218 had been shown to give selectively the undesired /<-spiro epoxide,35 102 it was first converted into l-219, followed by oxidation with m-CPBA to give the desired x-spiro epoxide d-220 (80%). The alcohol d-221 obtained in 73% yield by reductive cleavage of epoxide d-220 with lithium triethylborohydride (LiBHEt3) in THF was formed as a 2 3 mixture of two alcohols. However, hydrolysis of d-221 with hydrochloric acid gave d-48 (94%), which was further characterized by conversion into the pentaacetyl derivative 222 (82%). 

Walker et al prepared lOa-spiro epoxide (42a) and its 7-methoxymethyl (MOM) ether (42b), which exhibited comparable cytotoxicity and tubulin assembly activity with paclitaxel. 

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