Intramolecular cycloadditions ester derivatives

Intramolecular cycloadditions of 4/f-pyrido[l,2-n]pyrimidin-4-ones 235 (R = H, Me Ph) and MeNHOH HCl gave tetracyclic isoxazolo derivatives 237. In the case of 235 (R = Me) a minor epimer 238 was also isolated (00JCR(S)414). Similar reaction of 235 (R = H, Me, Ph) and sarcosine ethyl ester HCl afforded an isomeric mixture of epimeric tetracyclic pyrrolo derivatives 239 and 240. In the reaction of 235 (R = H) and PhCHjNHCHjCOOEt only one product 241 was obtained. 

In a similar study to that outlined by Grigg, Kanemasa et al. (68) has demonstrated the intramolecular cycloaddition of azomethine ylides derived from either amino acids or esters. Treatment of the amino methyl ester 302 with... 

Intramolecular ylide formation with the lactone carbonyl oxygen (53) in 145 provided a carbonyl ylide 146 that was trapped with Al-phenyl maleimide to give cycloadduct 147. Likewise (54), carbonyl yhde 149, derived from ester 148, suffers intramolecular cycloaddition with the tethered alkene to deliver acetal 150 in 87% yield. An enantioselective version of this process has also been described (Scheme 4.33). 

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 unstable pyrrolotriazolines, derived from cis-cis and trans-cis-3-substituted 6-azidohexa-2,4-dienoate esters by intramolecular cycloaddition, decompose to 2-substituted pyrroles at rates that are both substituent and... 

One intramolecular Diels-Alder cycloaddition which does not involve a ring as a starting point has been described. The sequence commences with allylic / -keto ester derivatives (201) and ends with the formation of the highly reduced furopyridazine (202 R = 2,4-dinitrophenyl or benzoyl) (Equation (70)) <89JCS(P1)353>. 

A simple procedure to prepare 5-aryl- and 5-pyridyl-2-furaldehydes from inexpensive, commercially available 2-furaldehyde diethyl acetal was reported. The reaction proceeded in a four-step, one-pot procedure and the yield of coupling step was usually between 58-91% <02OL375>. A facile route to 3,4-furandicarboxylic acids was developed. DDQ-oxidation of 2,5-dihydrofuran derivatives, which were produced from dimethyl maleic anhydride, furnished the desired esters of furan-3,4-dicarboxylic acid <02S1010>. The furan-fused tetracyclic core of halenaquinol and halenaquinone possessing antibiotic, cardiotonic, and protein tyrosine kinase inhibitory activities was synthesized. Intramolecular cycloaddition of an o-quinodimethane with furan gave the adduct as a single isomer via an enrfo-transition state, which was converted to trisubstituted furan by oxidation-elimination reactions <02T6097>. 

An intramolecular cycloaddition reaction is also a vital feature of Oppolzer s synthesis (Scheme 5).336 Here the cycloaddition reaction occurs on an unsaturated nitrone ester (39) (not isolated). Again, the aldehyde derived from oxidation of the diol (40) gave entirely the ( )-olefin on reaction with crystalline a-methoxy-carbonylethylidenetriphenylphosphorane, which allowed the synthesis of (+)-chanoclavine I (34) to be completed in an overall yield of 14% from indole-4-aldehyde. In contrast, the Horner-Emmons reaction on the aldehyde from... 

Styryl derivatives of 2-aminofurans, as well as alkenyl compounds, also undergo intramolecular cycloaddition and the alkene function can be introduced by Stille coupling of a suitably functionalised aryl iodide. This approach is illustrated by the tetrahydroquinoline synthesis summarised in Scheme 26 (99JOC3595). The iodo derivative 143 is readily prepared from the carbamate ester 142 (67% yield) and Stille coupling with vinyltributyltin gives the styrene 144 (72% yield). Intramolecular cycloaddition and dehydration is then achieved simply by heating compound 144 in toluene under reflux (24 h) to give the tetrahydroquinoline 145 in 79% yield. 

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 . 

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. ... 

After examining a number of model systems, Pearlman found that substrates related to the substituted cyclohexenol 33 to be best for this cycloaddition-reteroaldolization sequence (Scheme 3.6) (20). For example, photoinduced intramolecular cycloaddition of the pseudo ester 33 afforded the tetracyclic cyclobutane derivative 34. Hydrolysis of this substance produced the ketoester 35 which underwent Baeyer-Villager oxidation to generate the retroaldol substrate 36. Treatment of 36 with acid effected the desired retroaldolization and gave the lactol methyl ether 37 which has the acetic acid, aldehyde and alcohol functionality cis-oriented on the cyclohexane skeleton. 

Carbenes and carbenoids constitute a class of reactive intermediates traditionally intimately associated with the synthesis of cyclopropanes, and more recently with products derived from C-H insertion processes. The reactions of diazoacetic acid esters with aromatic hydrocarbons such as toluene to give cyclopropanes with the liberation of N2, date back to the seminal experiments by Buchner and Curtius reported in 1885 [11]. Much later, in 1942, Meerwein reported that carbenes generated from diazomethane undergo insertion into C-H bonds [12], Seminal experiments that had significant impact for the utilization of such reactions in synthesis were performed by Stork, who demonstrated that carbenes prepared by photolysis of diazoketones participated in stereospecific intramolecular cycloadditions with al-kenes to form bicyclic cyclopropanes (Equations 1 and 2) [13]. Julia reported that intramolecular C-H insertion reactions of a chiral substrate 5 including a stereogenic methine center proceeded stereospecifically with retention of configuration (Equation 3) [14]. 

Some straightforward, efficient cyclopentanellation procedures were developed recently. Addition of a malonic ester anion to a cyclopropane-1,1-dicarboxylic ester followed by a Dieckmann condensation (S. Danishefsky, 1974) or addition of iJ-ketoester anions to a (l-phenylthiocyclopropyl)phosphonium cation followed by intramolecular Wittig reaction (J.P, Marino. 1975) produced cyclopentanones. Another procedure starts with a (2 + 21-cycloaddition of dichloroketene to alkenes followed by regioselective ring expansion with diazomethane. The resulting 2,2-dichlorocyclopentanones can be converted to a large variety of cyclopentane derivatives (A.E. Greene. 1979 J.-P. Deprds, 1980). 

In the presence of a double bond at a suitable position, the CO insertion is followed by alkene insertion. In the intramolecular reaction of 552, different products, 553 and 554, are obtained by the use of diflerent catalytic spe-cies[408,409]. Pd(dba)2 in the absence of Ph,P affords 554. PdCl2(Ph3P)3 affords the spiro p-keto ester 553. The carbonylation of o-methallylbenzyl chloride (555) produced the benzoannulated enol lactone 556 by CO, alkene. and CO insertions. In addition, the cyclobutanone derivative 558 was obtained as a byproduct via the cycloaddition of the ketene intermediate 557[4I0]. Another type of intramolecular enone formation is used for the formation of the heterocyclic compounds 559[4l I]. The carbonylation of the I-iodo-1,4-diene 560 produces the cyclopentenone 561 by CO. alkene. and CO insertions[409,4l2]. 

Carbonyl ylides possess versatile reactivities, among which the 1,3-dipolar cycloaddition is the most common and important reaction. The reaction sequence of ylide formation and then 1,3-dipolar cycloaddition can occur in either inter- or intramolecular manner. When the reaction occurs intermolecularly, the overall reaction is a one-pot three-eomponent process leading to oxygen-containing five-membered cyclic compounds, as demonstrated by the example shown in Scheme 8. A mixture of diazo ester 64, benzaldehyde, and dimethyl maleate, upon heating to reflux in CH2CI2 in the presence of 1 mol% rhodium(ii) perfluorobutyrate [Rh2(pfb)4], yields tetrahedrofuran derivative 65 in 49% yield as single diastereomer. " ... 

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