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Cycloaddition ether

Nine substituted hydroxybenzaldehydes were coupled to a Wang resin with a Mitsu-nobu coupling (Scheme 11.4). Treatment of the aldehydes with amino acid methyl esters produced resin-bound azomethine ylides that reacted with maleimide in a 1,3-dipolar cycloaddition. Ether-linked cycloadducts were cleaved from the resin as phenols with 50% trifluoroacetic acid. The compounds were retained as a mixture and were not isolated. [Pg.357]

Dramatic rate accelerations of [4 + 2]cycloadditions were observed in an inert, extremely polar solvent, namely in5 M solutions oflithium perchlorate in diethyl ether(s 532 g LiC104 per litre ). Diels-Alder additions requiring several days, 10—20 kbar of pressure, and/ or elevated temperatures in apolar solvents are achieved in high yields in some hours at ambient pressure and temperature in this solvent (P.A. Grieco, 1990). Also several other reactions, e.g, allylic rearrangements and Michael additions, can be drastically accelerated by this magic solvent. The diastereoselectivities of the reactions in apolar solvents and in LiClO EtjO are often different or even complementary and become thus steerable. [Pg.86]

Endo adducts are usually favored by iateractions between the double bonds of the diene and the carbonyl groups of the dienophile. As was mentioned ia the section on alkylation, the reaction of pyrrole compounds and maleic anhydride results ia a substitution at the 2-position of the pyrrole ring (34,44). Thiophene [110-02-1] forms a cycloaddition adduct with maleic anhydride but only under severe pressures and around 100°C (45). Addition of electron-withdrawiag substituents about the double bond of maleic anhydride increases rates of cycloaddition. Both a-(carbomethoxy)maleic anhydride [69327-00-0] and a-(phenylsulfonyl) maleic anhydride [120789-76-6] react with 1,3-dienes, styrenes, and vinyl ethers much faster than tetracyanoethylene [670-54-2] (46). [Pg.450]

In 1959 Carboni and Lindsay first reported the cycloaddition reaction between 1,2,4,5-tetrazines and alkynes or alkenes (59JA4342) and this reaction type has become a useful synthetic approach to pyridazines. In general, the reaction proceeds between 1,2,4,5-tetrazines with strongly electrophilic substituents at positions 3 and 6 (alkoxycarbonyl, carboxamido, trifluoromethyl, aryl, heteroaryl, etc.) and a variety of alkenes and alkynes, enol ethers, ketene acetals, enol esters, enamines (78HC(33)1073) or even with aldehydes and ketones (79JOC629). With alkenes 1,4-dihydropyridazines (172) are first formed, which in most cases are not isolated but are oxidized further to pyridazines (173). These are obtained directly from alkynes which are, however, less reactive in these cycloaddition reactions. In general, the overall reaction which is presented in Scheme 96 is strongly... [Pg.50]

The only recorded synthesis of this type from a pyridazine involves the [4 + 2] cycloaddition of the lactim ether (374) with l,2,4,5-tetrazine-3,6-dicarboxylic ester, which proceeds with loss of nitrogen and methanol from the intermediate adduct to give the pyrido[2,3-t/]pyridazine (375) (77AP936). [Pg.247]

In the case of vinylfurans and vinylpyrroles there is the possibility of cycloaddition involving either the cyclic diene system or the diene system including the double bond. 2-Vinylfuran reacts in high yield with maleic anhydride in ether at room temperature to form the adduct involving the exocyclic double bond. Similarly, 2- and 3-vinylpyrroles react with 7T-electron-deficient alkenes and alkynes under relatively mild conditions to give the corresponding tetrahydro- and dihydro-indoles (Scheme 51) (80JOC4515). [Pg.66]

Bravo et al. studied the reaction of various ylides with monooximes of biacetyl and benzil. Dimethylsulfonium methylide and triphenylarsonium methylide gave 2-isoxazolin-5-ol and isoxazoles, with the former being the major product. Triphenylphosphonium methylide and dimethyloxosulfonium methylide gave open-chain products (Scheme 135) (70TL3223, 72G395). The cycloaddition of benzonitrile oxide to enolic compounds produced 5-ethers which could be cleaved or dehydrated (Scheme 136) (70CJC467, 72NKK1452). [Pg.101]

Intermolecular reactions with typical cycloaddition components are also possible. Phenyl isocyanate in ether converts triisopropyldiaziridinimine (182) to the 1,2,4-triazolidine under mild conditions. Labeling with a deuterated isopropyl group revealed that cycloaddition is not preceded by N—N cleavage, which should have resulted in deuterium randomization (77AG(E)109). [Pg.219]

The regioselectivity of 1,3-dipolar cycloadditions can also be analyzed by MO calculations on transition-state models. For example, there are two possible regioisomers from the reaction of diazomethane and methyl vinyl ether, but only the 3-methoxy isomer is formed. [Pg.648]

The regio- and stereoselectivities of cycloadditions of trifluoroacetonitrile oxide, which is generated m situ by treatment of the tnfluoroacetohydroxamyl bromide etherate with tnethylamine in toluene (equation 31), have been determined in a senes of studies by Tanaka [55, 36, 37, 5 ]. The highly reactive nitnle oxide reacts regioselectively with a variety of activated terminal alkenes and alkynes (equations 32 and 33)... [Pg.808]

Covalent fluondes of group 3 and group 5 elements (boron, tin, phosphorus, antimony, etc ) are widely used m organic synthesis as strong Lewis acids Boron trifluoride etherate is one of the most common reagents used to catalyze many organic reactions. A representative example is its recent application as a catalyst in the cycloadditions of 2-aza-l,3-dienes with different dienophiles [14] Boron trifluoride etherate and other fluonnated Lewis acids are effective activators of the... [Pg.944]

It has been reported that perfluoroisobutylene and perfluorocyclobutene undergo 1,2 cycloaddition with l-(N-morpholino)isobutylene in ether at room temperature to give the corresponding perfluorocyclobutane derivatives ]20a). Enamines of cyclic ketones produce only simple alkylation products when treated with these perfluoroolefins. [Pg.234]

Vinyl ethers undergo many cycloaddition reactions similar to those which take place with enamines. In general, however, these cycloaddition reactions with vinyl ethers take place less readily than those with enamines. These reactions include cycloaddition of vinyl ethers with ketene (200-205), phenyl isocyanate (206), sulfene (207,208), methyl acrylate (209), diethyl acetylenedicarboxylate (210), and diphenylnitrilimine (183). [Pg.245]

The 2,7-naphthyridine system 53 (Scheme 8.4.18) was combined with 2,4-dinitrochlorobenzene and 2-amino glycerol for in situ reaction of the resulting Zincke salt. The resulting naphthyridinium 54 was trapped by Bradsher cycloaddition with (Z)-vinyl ether 55, providing tetracycle 56 (X-ray) upon internal addition of one of the diastereotopic hydroxymethyl groups to the resulting iminium. This approach was also extended to the use of chiral 2,7-naphthyridinium salts, prepared via the analogous Zincke process. ... [Pg.363]

Stereocontrolled synthesis of oxabicyclic (3-lactam antibiotics via [2- -2] cycloaddition of isocyanates to sugar vinyl ethers 96CC2689. [Pg.229]

The hetero Diels-Alder [4+2] cycloaddition (HDA reaction) is a very efficient methodology to perform pyrimidine-to-pyridine transformations. Normal (NHDA) and Inverse (IHDA) cycloaddition reactions, intramolecular as well as intermolecular, are reported, although the IHDA cycloadditions are more frequently observed. The NHDA reactions require an electron-rich heterocycle, which reacts with an electron-poor dienophile, while in the IHDA cycloadditions a n-electron-deficient heterocycle reacts with electron-rich dienophiles, such as 0,0- and 0,S-ketene acetals, S,S-ketene thioacetals, N,N-ketene acetals, enamines, enol ethers, ynamines, etc. [Pg.51]

On the other hand, the corresponding tin precursor (63) undergoes smooth cycloaddition with a wide variety of aldehydes to produce the desired methylene-tetrahydrofnran in good yields [32, 33]. Thus prenylaldehyde reacts with (63) to give cleanly the cycloadduct (64), whereas the reaction with the silyl precursor (1) yields only decomposition products (Scheme 2.20) [31]. This smooth cycloaddition is attributed to the improved reactivity of the stannyl ether (65) towards the 7t-allyl ligand. Although the reactions of (63) with aldehydes are quite robust, the use of a tin reagent as precursor for TMM presents drawbacks such as cost, stability, toxicity, and difficult purification of products. [Pg.71]

The stereochemistry of the product formed in the cycloaddition reaction depends on the approach of the substrate. There are two different approaches by which the reaction can proceed - endo and exo. For the reaction of e.g., a / , y-un-saturated a-keto ester with an ethyl vinyl ether there are four possible approaches... [Pg.153]

A chiral titanium(IV) complex has also been used by Wada et al. for the intermole-cular cycloaddition of ( )-2-oxo-l-phenylsulfonyl-3-alkenes 45 with enol ethers 46 using the TADDOL-TiX2 (X=C1, Br) complexes 48 as catalysts in an enantioselective reaction giving the dihydropyrans 47 as shown in Scheme 4.32 [47]. The reaction depends on the anion of the catalyst and the best yield and enantioselectivity were found for the TADDOL-TiBr2 up to 97% ee of the dihydropyrans 47 was obtained. [Pg.178]

The chiral BOX-copper(ll) complexes, (S)-21a and (l )-21b (X=OTf, SbFg), were found by Evans et al. to catalyze the enantioselective cycloaddition reactions of the a,/ -unsaturated acyl phosphonates 49 with ethyl vinyl ether 46a and the cyclic enol ethers 50 giving the cycloaddition products 51 and 52, respectively, in very high yields and ee as outlined in Scheme 4.33 [38b]. It is notable that the acyclic and cyclic enol ethers react highly stereoselectively and that the same enantiomer is formed using (S)-21a and (J )-21b as the catalyst. It is, furthermore, of practical importance that the cycloaddition reaction can proceed in the presence of only 0.2 mol% (J )-21a (X=SbF6) with minimal reduction in the yield of the cycloaddition product and no loss of enantioselectivity (93% ee). [Pg.179]

More recently, further developments have shown that the reaction outlined in Scheme 4.33 can also proceed for other alkenes, such as silyl-enol ethers of acetophenone [48 b], which gives the endo diastereomer in up to 99% ee. It was also shown that / -ethyl-/ -methyl-substituted acyl phosphonate also can undergo a dia-stereo- and enantioselective cycloaddition reaction with ethyl vinyl ether catalyzed by the chiral Ph-BOX-copper(ll) catalyst. The preparative use of the cycloaddition reaction was demonstrated by performing reactions on the gram scale and showing that no special measures are required for the reaction and that the dihydro-pyrans can be obtained in high yield and with very high diastereo- and enantioselective excess. [Pg.179]

Our development of the catalytic enantioselective inverse electron-demand cycloaddition reaction [49], which was followed by related papers by Evans et al. [38, 48], focused in the initial phase on the reaction of mainly / , y-unsaturated a-keto esters 53 with ethyl vinyl ether 46a and 2,3-dihydrofuran 50a (Scheme 4.34). [Pg.179]

In a more recent work the same research group has applied cyclic and acyclic vinyl ethers in the oxazaborolidinone-catalyzed 1,3-dipolar cycloaddition reaction with nitrones [30]. The reaction between nitrone 5 and 2,3-dihydrofuran 6 with 20 mol% of the phenyl glycine-derived catalyst 3c, gave the product 7 in 56% yield as the sole diastereomer, however, with a low ee of 38% (Scheme 6.9). [Pg.219]

In an analogous study by Meske, the impact of various oxazaborolidinone catalysts for the 1,3-dipolar cycloaddition reactions between acyclic nitrones and vinyl ethers was studied [31]. Both the diastereo- and the enantioselectivities obtained in this work were low. The highest enantioselectivity was obtained by the application of 100 mol% of the tert-butyl-substituted oxazaborolidinone catalyst 3d [27, 32] in the 1,3-dipolar cycloaddition reaction between nitrone la and ethyl vinyl ether 8a giving endo-9a and exo-9a in 42% and 27% isolated yield, respectively, with up to 20% ee for endo-9a as the best result (Scheme 6.10). [Pg.219]

The above described reaction has been extended to the application of the AlMe-BINOL catalyst to reactions of acyclic nitrones. A series chiral AlMe-3,3 -diaryl-BINOL complexes llb-f was investigated as catalysts for the 1,3-dipolar cycloaddition reaction between the cyclic nitrone 14a and ethyl vinyl ether 8a [34], Surprisingly, these catalysts were not sufficiently selective for the reactions of cyclic nitrones with ethyl vinyl ether. Use of the tetramethoxy-substituted derivative llg as the catalyst for the reaction significantly improved the results (Scheme 6.14). In the presence of 10 mol% llg the reaction proceeded in a mixture of CH2CI2 and petroleum ether to give the product 15a in 79% isolated yield. The diastereoselectiv-ity was the same as in the acyclic case giving an excellent ratio of exo-15a and endo-15a of >95 <5, and exo-15a was obtained with up to 82% ee. [Pg.222]

Furukawa et al. also applied the above described palladium catalyst to the inverse electron-demand 1,3-dipolar cycloaddition of nitrones with vinyl ethers. However, all products obtained in this manner were racemic [81]. [Pg.238]

The reactions of nitrones constitute the absolute majority of metal-catalyzed asymmetric 1,3-dipolar cycloaddition reactions. Boron, aluminum, titanium, copper and palladium catalysts have been tested for the inverse electron-demand 1,3-dipolar cycloaddition reaction of nitrones with electron-rich alkenes. Fair enantioselectivities of up to 79% ee were obtained with oxazaborolidinone catalysts. However, the AlMe-3,3 -Ar-BINOL complexes proved to be superior for reactions of both acyclic and cyclic nitrones and more than >99% ee was obtained in some reactions. The Cu(OTf)2-BOX catalyst was efficient for reactions of the glyoxylate-derived nitrones with vinyl ethers and enantioselectivities of up to 93% ee were obtained. [Pg.244]


See other pages where Cycloaddition ether is mentioned: [Pg.157]    [Pg.439]    [Pg.70]    [Pg.70]    [Pg.86]    [Pg.89]    [Pg.575]    [Pg.537]    [Pg.872]    [Pg.17]    [Pg.211]    [Pg.245]    [Pg.9]    [Pg.142]    [Pg.157]    [Pg.214]    [Pg.224]    [Pg.233]   
See also in sourсe #XX -- [ Pg.324 ]




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1,3-Dipolar cycloadditions ethyl vinyl ether

1,3-butadienyl ethers, cycloaddition

Acetylenic ethers cycloadditions

Allyl silyl ethers cycloadditions

Benzyl ethers cycloaddition reactions

Butyl vinyl ether, cycloaddition with

Cycloaddition /reactions ethyl vinyl ether

Cycloaddition reactions phenol ethers

Cycloaddition to vinyl ether

Cycloadditions boron trifluoride etherate

Dienylic ethers, cycloaddition

Enol ethers cycloaddition reactions

Enol ethers cycloadditions

Enol ethers from Diels-Alder cycloadditions

Enol ethers photochemical cycloaddition

Ether compounds cycloadditions

Ether, ethyl propenyl 2 + 2] cycloaddition reactions

Ethers intramolecular cycloaddition reactions

Ethers, allyl cycloaddition reactions

Ethers, methyl 2 + 2] cycloaddition reactions

Ethers, vinyl cycloaddition reactions

Ethoxy vinyl ether cycloaddition

Ethyl vinyl ether, cycloaddition

Ethyl vinyl ether, cycloaddition with

Nitrones, 1,3-dipolar cycloadditions ethyl vinyl ether

Silyl enol ethers 2+2]-cycloaddition reactions

Silyl enol ethers photochemical cycloaddition

Silyl ethers, cycloaddition

Vinyl ethers, cycloaddition

Vinyl ethers, cycloadditions with

Vinyl ethers, cycloadditions with 3-substituted 2-pyrones

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