Intramolecular cycloadditions ketone derivation

The photocycloaddition of aliphatic and aromatic aldehydes with 2,4,5-trimethyloxazole (131) gave bicyclic oxetanes 132 in almost quantitative yields hydrolitic cleavage led selectively to erytro a-amino-P-hydroxy methyl ketones 133 <00CC589>. The oxazolium salt 134 was converted to the azomethine ylide 136 via electrocyclic ring opening of the oxazoline 135. Intramolecular cycloaddition afforded 137 in 66% overall yield which was transformed into the aziridinomitosene derivative 138 . 

An intramolecular cycloaddition of the tetradecatrienyl nitroethyl ether 263 was used in the synthesis of the 14-membered bicyclic precursor 265 of crassin acetate 266, a cembrane lactone possessing antibiotic and antineoplastic activity (332). Nitro compound 263 was obtained from farnesyl acetate (262) in several steps and was then treated with phenyl isocyanate and triethylamine to give the tricyclic isoxazoline 264 (Scheme 6.98). Conversion to ketone 265 was accomplished by hydrogenation of the cycloadduct with Raney Ni and boric acid followed by acetylation (332). In this case, the isoxazoline derived from a 3-butenyl nitroethyl ether moiety served to produce a 3-methylenetetrahydropyran moiety (332). 

Intramolecular cycloaddition of a diazo ketone to a cyclopropene. Rhodium) II) acetate is markedly superior to copper or copper(II) sulfate as the catalyst for cyclopropanation of l,4-diacetoxy-2-butyne with /-butyl diazoacetatc. The product (1) was converted by known steps into the diazo ketone 2. In the presence of rhodium(II) acetate, 2 undergoes intramolecular cycloaddition to the cyclopropene double bond to give the highly strained tricyclic pentanone derivative 3 in 30% yield. C oppcr catalysts are less efficient for this conversion. 

Cycloadditions of diene intermediates derived from 3-sulfolenes have been utilized to synthesize a variety of compounds. Diels-Alder reaction of furan 202 with excess DMAD initially gave intermediate 3-sulfolene 203. Extrusion of sulfur dioxide gave diene 204 which further reacted with DMAD to give ester 205 . Similarly, 2-bromopyrrole 206 reacted with excess DMAD to give ester 207 . Finally, an intramolecular cycloaddition of the diene derived from 3-sulfolene 208 gave ketone 209 . 

T. Hoye et al. were understandably surprised when a seemingly trivial oxidation of 7 took an unexpected course (Scheme 7.28). Instead of ketone 8 the tricyclic product 9 was obtained in 53% yield. The course of the events could be rationalized readily and pointed to the unprecedented cyclization of ketone 8 to give the benzyne derivative 10 in a [4-1-2] cycloaddition between a diyne and an yne moiety. In fact, this intramolecular cycloaddition turned out to be a viable route to generate arynes bearing electron-withdrawing substituents, a substitution pattern that is not always amenable to the standard methods for generating arynes. Thus, this surprising reaction broadens the scope of benzyne chemistry. 

Under enyne cross-metathesis conditions, the intermolecular reaction of the a,(D-dienes 153, derived from the MBH reaction, with different terminal alkynes 154 afforded triene intermediates that cyclized spontaneously under the reaction conditions to give substituted cis-hexahydro-l/f-indenes 155 (Scheme 4.45), which can be further transformed into steroid analogues via TBS deprotection and oxidation. However, metathesis reactions starting with 156 only furnished trienes 157 [as EfZ) mixtures] and no spontaneous intramolecular cycloaddition occurred. Even at elevated reaction temperatures, trienes 157 cyclized only slowly to give octahydronaphthalene diastereomers. With deprotection of the TBS and subsequent Dess-Martin oxidation, trienes 157 could be converted exclusively into cw-fused 7-substituted 6,7-dehy-drodealone-l-one-lO-carboxylic esters 158 in 50-60% yields. Moreover, c ross-metathesis of TBS-unprotected MBH adduct 159 with alkynes 154 along with treatment with Dess-Martin periodinane (DMP) in one pot could conveniently produce the corresponding bicyclic ketones 160 in moderate yields. ... 

Another example of a [4S+1C] cycloaddition process is found in the reaction of alkenylcarbene complexes and lithium enolates derived from alkynyl methyl ketones. In Sect. 2.6.4.9 it was described how, in general, lithium enolates react with alkenylcarbene complexes to produce [3C+2S] cycloadducts. However, when the reaction is performed using lithium enolates derived from alkynyl methyl ketones and the temperature is raised to 65 °C, a new formal [4s+lcj cy-clopentenone derivative is formed [79] (Scheme 38). The mechanism proposed for this transformation supposes the formation of the [3C+2S] cycloadducts as depicted in Scheme 32 (see Sect. 2.6.4.9). This intermediate evolves through a retro-aldol-type reaction followed by an intramolecular Michael addition of the allyllithium to the ynone moiety to give the final cyclopentenone derivatives after hydrolysis. The role of the pentacarbonyltungsten fragment seems to be crucial for the outcome of this reaction, as experiments carried out with isolated intermediates in the absence of tungsten complexes do not afford the [4S+1C] cycloadducts (Scheme 38). 

A regioselective [3 + 2]-cycloaddition approach to substituted 5-membered carbo-cycles was made available by the use of allenylsilanes [188]. The reaction involves regioselective attack of an unsaturated ketone by (trimethylsilyl)allene at the 3-position. The resulting vinyl cation undergoes a 1,2-silyl migration. The isomeric vinyl cation is intercepted intramolecularly by the titanium enolate to produce a highly substituted (trimethylsilyl)cyclopentene derivative. 

A further study on six-membered ylide formation examined the use of an aliphatic ester in place of a ketone as the Lewis base donor for carbonyl ylide formation. Although the same keto-substituted system underwent an intramolecular cyclization readily, the ester derivative gave no cycloaddition products. Padwa and co-workers (37,76) points to the major electronic differences between the two carbonyl groups to rationalize the disparity in carbonyl ylide formation. 

The reaction of 1-disilagermirene 22 with ketones is similar to the benzaldehyde case. Thus, reaction with butane-2,3-dione gives a final bicyclic product 41, which also has a norbornane type skeleton (Scheme 15, Figure 13)50. Formation of this compound can be reasonably explained by the initial [2 + 2] cycloaddition of one carbonyl group across the Si=Si bond to form the three- and four-membered ring bicyclic compound 42, followed by the isomerization of disilaoxetane 42 to an enol ether derivative 43. The intramolecular insertion of the second carbonyl group into the endocyclic Si—Ge single bond in 43 completes this reaction sequence to produce the final norbornane 41. In this case, C=0 insertion occurred into the Si—Ge bond rather than the Si—Si bond, which is reasonable due to the weakness of Si—Ge bond. 

In intermolecular PET processes, radical ions are formed either as close pairs or as free species from neutral molecules (Sch. 1) [2,6]. Most commonly, carbonyl compounds or related derivatives as for example enol ethers, cyclopropyl ketones, and siloxycyclopropanes are used for intramolecular cyclization reactions. With the exception of cycloadditions the ring-building key step is always an intramolecular bond formation. In PET... 

While most of the initial studies have involved the transition metal-catalyzed decomposition of a-carbonyl diazo compounds and have been reviewed [3-51], it appears appropriate to highlight again some milestones of these transformations, since polycyclic structures could be nicely assembled from acyclic precursors in a single step. Two main reactivities of metalo carbenoids derived from a-carbonyl diazo precursors, namely addition to a C - C insaturation (olefin or alkyne) and formation of a ylid (carbonyl or onium), have been the source of fruitful cascades. Both of these are illustrated in Scheme 27 [52]. The two diazo ketone functions present in the same substrate 57 and under the action of the same catalyst react in two distinct ways. The initially formed carbenoid adds to a pending olefin to form a bi-cyclop. 1.0] intermediate 58 that subsequently cyclizes to produce a carbonyl ylide 59, that is further trapped intramolecularly in a [3 + 2] cycloaddition. The overall process gives birth to a highly complex pentacyclic structure 60. 

This report covers two topics (1) The generation of 2-thioxo-2,4-dihydro-3fT-imidazol-l-ium-l-imides as intermediates in the course of [3+2] cycloaddition reactions of azoalkenes and thiocyanic acid resulting in the formation of l-aminoimidazole-2-thione derivatives some further reactions of these heterocycles are presented as well. (2) The rhodium-catalyzed intramolecular interaction of co-diazenyl a -diazo ketones giving rise to the formation of mostly two cyclic azomethine imine isomers with an exocyclic terminal nitrogen atom and with all three... 

Chiral Auxiliary for Asymmetric Induction. Numerous derivatives of (—)-8-phenylmenthol have been utilized for asymmetric induction studies. These include inter- and intramolecular Diels-Alder reactions, dihydroxylations, and intramolecular ene reactions of a,p-unsaturated 8-phenylmenthol esters. These reactions usually proceed in moderate to good yield with high diastereofacial selectivity. a-Keto esters of 8-phenylmenthol (see 8-Phenylmenthyl Pyruvate) have been used for asymmetric addition to the keto group, as well as for asymmetric [2 -F 2] photoadditions and nucleophilic alkylation. Ene reactions of a-imino esters of 8-phenylmenthol with alkenes provide a direct route to a-amino acids of high optical purity. Vinyl and butadienyl ethers of 8-phenylmenthol have been prepared and the diastereofacial selectivity of nitrone and Diels-Alder cycloadditions, respectively, have been evaluated. a-Anions of 8-phenylmenthol esters also show significant diastereofacial selectivity in aldol condensations and enantiose-lective alkene formation by reaction of achiral ketones with 8-phenylmenthyl phosphonoacetate gives de up to 90%. ... 

In contrast to intermolecular photoaldols, which can be manipulated with facility, intramolecular cycloadducts undergo retro-[2 + 2] cycloaddition when subjected to hydrolytic conditions. In an alternative protocol, oxymercuration of (229) afforded a-mercurio ketone (230 42%) which was acetylated under standard conditions to provide 1,4-diketone (231) quantitatively. Similarly, epoxidation of (229) provided functionalized photoaldol (232), which was hydrolyzed and acetylated to form a-acetoxy derivative (233). Finally, hydrolysis of (234) (4 1 THF/0.1 N HCl) gave lactol (235) in nearly quantitative yield, illustrating the utility of the intramolecular furan carbonyl photocycloaddition in spirocycle formation. 

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