Cycloadducts diastereomeric

SCHEME 18.26 Effect of R and Ar groups on cycloadduct diastereomeric excess. 

Ni(C104)2 6H2O showed a litde better enantioselectivity than the anhydrous complex. Although the uncatalyzed reaction was highly exo selective (cis/trans=i 97), the catalyzed reactions were very poor in diastereoselectivity, a mixture of endo and exo cycloadducts being formed. We expected that this poor diastereoselectivity would not be a serious problem since the same enantioface should be involved at the 2-position of the diastereomeric cycloadducts (Scheme 7.27). The best enantioselectivity (cis > 99% ee, trans 94% ee) was observed when the reaction was catalyzed by l ,J -DBFOX/Ph-Ni(SbF6)2 (50 mol%). With the decreased amount of catalyst (10 mol%) still a satisfactory level of enantioselectivity was observed for the cis cycloadduct (94% ee). 

The intramolecular cycloaddition has proven to be the method of choice for the preparation of steroids. A diastereomeric mixture of 204, prepared from 191 and tosylate 203 has been cleanly converted to dl-estra-1,3,5(10)-trien-17-one (205) in 85% yield (equation 130). A second example of the intramolecular cycloaddition reaction is the formation of the cycloadduct (209), the key intermediate in a synthesis of the As-pidosperma alkaloid aspidospermine, upon heating 208 at 600 °C (equation 131)124. The sulfone 208 can be prepared by reaction of 3-ethyl-3,4,5,6-tetrahydropyridine (206) with the acid chloride 207. 

Substituted 3,4-dihydropyranes were also prepared by Diels-Alder reactions between (E)-4-oxobutenoate 80 and vinylethers [80] under iron(III) 2-ethylhex-aonate, a mild and economical catalyst (Equation 3.26). Diastereomeric excess as high as 98 % was observed. Cycloadducts with a 2,4-cw-configuration were preferred. 

The inverse electron demand Diels-Alder reaction of 3-substituted indoles with 1,2,4-triazines and 1,2,4,5-tetrazines proceeds in excellent yields both inter- and intramolecularly. The cycloaddition of tryptophan 124 with a tethered 1,2,4-triazine produced a diastereomerically pure cycloadduct 125 <96TL5061>. 

A dipolarophile bearing an ionic group and an associated counterion provides enhanced selectivity as has been recently demonstrated by Raposo and Wilcox [14]. Cycloaddition of benzonitrile 4 and the uncharged amine 5 a (a chiral phenylmaleimide derivative) in THE or chloroform provides a mixture of cycloadducts 6-9a in 1 4 4 4 diastereomeric ratio (i.e., 8 5 in favor of the methyl face approach of the dipolarophile. The ortho-substituents of the... 

In 2005, another class of chiral ligands, bis(thiazolines) derivatives, was prepared by Nishio et al. from chiral bis-(A-acylamino alcohols) by using Lawesson s reagent. These new compounds have proved to be useful chiral ligands for the Zn-catalysed Diels-Alder reaction of 3-acryloyloxazolidine-2-one with cyclopentadiene, giving the corresponding cycloadducts as a 94 6 diastereomeric mixture, where the major diastereomer was formed with 92% ee (Scheme 5.14). 

Giomi s group developed a domino process for the synthesis of spiro tricyclic nitroso acetals using a, 3-unsaturated nitro compounds 4-163 and ethyl vinyl ether to give the nitrone 4-164, which underwent a second 1,3-dipolar cycloaddition with the enol ether (Scheme 4.35) [56]. The diastereomeric cycloadducts formed, 4-165 and 4-166 can be isolated in high yield. However, if R is hydrogen, an elimination process follows to give the acetals 4-167 in 56% yield. 

Dipolar cycloaddition of betaines 492 gave cycloadducts 493, which produced tricyclic compounds 494 on further thermolysis (Scheme 48) <1995H(41)1631>. Heating 9,9-disubstituted yr/ra-(4-hydroxy-2-oxo-2//-pyrido-[2. -//][ 1.3]thiazinium) hydroxides 495 afforded tricyclic compounds 497 as diastereomeric mixtures (Scheme 49) <1995S973>. In the case of the lower homolog (n = 0), a cycloadduct 496 could be also isolated at lower temperature. 

Cycloadduct 30a underwent an easy cleavage of the sulfur-carbon bond by attack of alcohols to give ring-opening products 31 and 32, the latter as inseparable diastereomeric mixtures (see Equation (6) and Table 3) <1997T4611>. A completely regioselective reaction was observed with bulky alcohols resulting in the exclusive formation of 31 (see entries 3 and 4). 

Reaction mixtures of isomeric cycloadducts from furans 87d and 87e gave, after purification by column chromatography on both silica gel and neutral alumina, mixtures of diastereomeric hydrolysed products 90 and 91 (Scheme 17) [16]. 

Under similar reaction conditions the D-threose derived nitrone (480) is converted in high regioselectivity to diastereomeric cycloadducts (485-488) in an overall yield of 84% (Scheme 2.238). 

Several SENAs derived from primary AN were involved in the reaction with ceptem (282) (Scheme 3.177, Eq. 1) (434) to prepare the diastereomeric pure cycloadducts, which were then transformed into isoxazolines (283). However, the configurations of the new stereocenters in products (283) were not determined. 

By chance, the existence of the borane complex 330 of 329 was discovered. The liberation of 330 occurred with the best efficiency with sodium bis(trimethylsilyl)-amide from the borane complex 327 of 326. When styrene or furan was used as the solvent, three diastereomeric [2 + 2]-cycloadducts 328 and [4 + 2]-cycloadducts 331, respectively, were obtained in 30and 20% yield (Scheme 6.70) [156]. With no lone pair on the nitrogen atom, 330 cannot be polarized towards a zwitterionic structure, which is why its allene subunit, apart from the inductive effect of the nitrogen atom, resembles that of 1,2-cydohexadiene (6) and hence undergoes cycloaddition with activated alkenes. It is noted that the carbacephalosporin derivative 323 (Scheme 6.69) also does not have a lone pair on the nitrogen atom next to the allene system because of the amide resonance. 

Dimers with a 1,2-bismethylenecyclobutane structure were obtained from 585 [240], 590 [238], 591 [241], 592 [242], 593 [243] and from the pinene derivative 597 [244]. The interception of 592 by 1,3-diphenylisobenzofuran (DPIBF) afforded two diastereomeric [4+ 2]-cycloadducts [245], Bicyclo[5.1.0]octa-3,4-diene (594) was generated by /3-elimination and trapped by sodium pyrrolidide because of the question of the extent to which the corresponding bicyclooctyne is formed in addition to 594 [184], Liberated by /3-elimination from ll,ll-dichloro-l,6-methano[10]annulene in... 

Tetra-rt-propylammonium periodate oxidation of the hydroxamic acids 215 (R = CH2OH, CH20Me, CH2NHPI1 or CC Me), derived from L-proline, generates nitroso compounds 216, which, in the presence of cyclohexadiene, give mixtures of diastereomeric cycloadducts 217 in 79-89% yields and 26-68% de values (equation 115)109. 

Chiral dienes or chiral dienophiles or chiral Lewis acid catalysts may be involved in cycloaddition reactions. When any two of these are combined double asymmetric induction operates111. Thus the chiral diene 223 and the optically active dienophile 224 (from D-mandelic acid) gave 225 in high de values, whereas the same diene and the enantiomeric dienophile 226 (from L-mandelic acid) — a mismatched pair—formed the diastereomeric cycloadduct 227 in only 4% de (equation 121)112. 

Mechanistic analysis of the reaction of substituted cyclopropanes reveals that each re-gioisomeric cycloadduct correlates uniquely with a metal-n -system complex (Scheme 13.11, A and A ). Metal coordination to either of the two vinyl rc-system faces of 122 followed by oxidative coupling leads to diastereomeric metaUacyclopentenes B or B ... 

The thermolytic preparation by De Shong et al. (74) of azomethine ylides from aziridines and their intermolecular reactions are the first examples of singly stabilized ylides of this type. However, the protocol has been further extended to include intramolecular processes. Aziridines tethered to both activated and unactivated alkenes were subjected to flash vacuum thermolysis generating cycloadducts in moderate-to-excellent yields. While previously singly activated alkenes had furnished low material yields via an intermolecular process, the intramolecular analogue represents a major improvement. Typically, treatment of 222 under standard conditions led to the formation of 223 in 80% yield as a single cis isomer. Similarly, the cis precursor furnished adduct 224 in 52% yield, although as a 1 1 diastereomeric mixture (Scheme 3.77). 

The first diastereoselective synthesis of a tetrahydrothiophene derivative was reported by Karlsson and Hdgberg (32,95). The parent ylide la was added to a variety of C,C-dipolarophiles (79) bearing (—)-(15)-2,10-camphorsultam as the chiral auxiliary group to exclusively give trans-cycloadducts 80a,b with high diastereoselectivity [diastereomeric ratio (dr) 9 1], (Scheme 5.28). 

In a related case, the use of dioxazaborocines as the chiral auxiliary with benzonitrile oxide gave dipolar cycloadducts with a poor diastereomeric ratio dr 68 32) (195). Similarly, the cycloaddition of benzonitrile oxide to vinyl ethers with a chiral appendage also proceeded with poor stereoselectivity (dr of 65 35) (196). 

A new dipolarophile bearing a chirality-controlling heterocyclic auxiliary at the p-position is readily accessible from (5)-A -benzylvalinol and methyl ( )-4-oxo-2-propenoate. However, the dipolarophile is available only as an 86 14 equilibrium mixture of trans and cis stereoisomers (Scheme 11.20) (84). When this is used without separation in the reaction with the Al-hthiated azomethine ylide derived from methyl (benzylideneamino)acetate in THE at 78 °C for 3.5 h, a mixture of two diastereomeric cycloadducts (75 25) was obtained in 82% yield. These two cycloadducts are derived from the trans and cis isomers of acceptor, indicating that both cycloadditions were highly diastereoselective. 

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