Dienophiles stereochemistry

In some cases, a stepwise mechanism is indicated by randomization of the dienophile stereochemistry. For example, addition of cw-anethole radical cation (100 +) to cyclopentadiene produces comparable yields of four possible diastereoi-someric adducts (102) clearly supporting a distonic radical cation intermediate (lOl ). Only products supporting the stepwise mechanim, that is, trans,endo-and trans,exo-lQ2, are shown. " ... 

However, only limited experimental evidence is available concerning the key step of the dimerization, i,e. the addition of the radical cation to the parent olefin. Does this addition occur stepwise or in concerted fashion Does the radical cation serve as a the diene component ([3 + 2]cycloaddition) or as dienophile ([4+ l]cy-cloaddition) The observed retention of dienophile stereochemistry and orbital symmetry arguments (Fig. 7) favor the [4 + l]cycloaddition type. Although it is difficult to distinguish the [3 + 2] from the [4 + l]addition type, a stepwise component for the cycloaddition and the complementary cycloreversion has been established in at least one system, viz., spiro[2.4]heptadiene. 

The search by the Parke-Davis company for drugs to treat strokes provided an interesting application of dienophile stereochemistry. The kinds of compound they wanted were tricylic amines. They don t look like Diels-Alder products at all. But if we insert a double bond in the right place in the six-membered ring, Diels-Alder (D-A) disconnection becomes possible. 

In the selected instances of the observation of ring-opened products, copolymerization reactions, and the loss of dienophile stereochemistry in the [4 + 2] reactions of a,/3-unsaturated esters bearing an additional C-3 electron-withdrawing group as well as the lack of an observed rate dependency on the solvent polarity have led Hall and co-workers to conclude that such cycloadditions may proceed with the generation of biradical intermediates. However, such conclusions have been further cautioned by the detailed investigations of Hall and his co-workers in which they... 

Until recently, the reaction of a,/3-unsaturated esters with electron-rich olefins has been reported to afford cyclobutane [2 + 2] cycloaddition products. Amice and Conia first proposed the intermediacy of [4 + 2] cycloadducts in the reaction of ketene acetals with methyl acrylate, and the first documented example of the 47t participation of an a,)3-unsatu-rated ester in a Diels-Alder reaction appears to be the report of Snider and co-workers of the reversible, intramolecular cycloaddition of 1-allyIic-2,2-dimethyl ethylenetricarboxylates. Subsequent efforts have recognized that substitution of the a,/8-unsaturated ester with a C-3 electron withdrawing substituent permits the 4 tt participation of such oxabutadiene systems in inverse electron demand Diels-Alder reactions with electron-rich olefins. In the instances studied, the rate of the [4 + 2] cycloaddition showed little dependence on solvent polarity [Aracetommie/ cycio-hexane 3, Eq. (15),ATj,ceionitnie/ ioiuene — lUi Eq. (20)], and reactions generally proceed with a maintenance of the dienophile stereochemistry consistent with a concerted [4 + 2] cycloaddition. 

Quantitative Distribution of Adducts as a Function of Dienophile Stereochemistry. For accurate quantitation of the isomer distribution in the products of cycloaddition to each of the dienophiles 5—8, the entire mixtures of the four stereoisomeric products in each instance were first subjected to sequential Q-deacetylation and periodate oxidation to afford a mixture of two aldehydo esters 29 and 30, which upon reduction with LiAlH afforded trans-2-norbornene-5,6-dimethanol as an unequal mixture of the two enantiomers (only the 5S,6g enantiomer is shown). NMR analysis of the mixture of 29 and 30 showed distinctive resonances for the CH3O and CHO groups in exo and endo orientations, permitting accurate determination of the endo/exo ratio of the products in the mixture. The observed specific rotation of the diol, in comparison with that (+23 ) determined for the enantiomerically pure 5S,6S diol 26 (and its enantiomer), provided a quantitative measure of the si.re diastereofacial selectivity. 

Various trifluoromethyl containing a, -unsaturated acids, esters, ketones, and nitriles have been used as dienophiles Details regarding regiochermstry and stereochemistry have been reported [2S, 98, 99] (equations 82-84)... 

One of the most useful features of the Diels-Alder reaction is that it isstaeo-specific, meaning that a single product stereoisomer is formed. Furthermore, the stereochemistry of the reactant is maintained. If we carry out the cycloaddition with a cis dienophile, such as methyl ds-2-butenoate, only the cis-substituted cyclohexene product is formed. With methyl tmtts-2-butenoate, only thetrans-substituted cyclohexene product is formed. 

Another stereochemical feature of the Diels-Alder reaction is that the diene and dienophile partners orient so that the endo product, rather than the alternative exo product, is formed. The words endo and exo are used to indicate relative stereochemistry when referring to bicyclic structures like substituted norbornanes (Section 4.9). A substituent on one bridge is said to be exo if it is anti (trans) to the larger of the other two bridges and is said to be endo if it is syn (cis) to the larger of the other two bridges. 

Thermal and photochemical cycloaddition reactions always take place with opposite stereochemistry. As with electrocyclic reactions, we can categorize cycloadditions according to the total number of electron pairs (double bonds) involved in the rearrangement. Thus, a thermal Diels-Alder [4 + 2] reaction between a diene and a dienophile involves an odd number (three) of electron pairs and takes place by a suprafacial pathway. A thermal [2 + 2] reaction between two alkenes involves an even number (two) of electron pairs and must take place by an antarafacial pathway. For photochemical cyclizations, these selectivities are reversed. The general rules are given in Table 30.2. 

Diels-Alder reaction, 492 characteristics of, 492-497 dienes in, 496-497 dienophiles in. 493-494 electrostatic potential map of. 493 endo stereochemistry of, 495 HOMO in. 1188-1189 LUMO in. 1188-1189 mechanism of. 493 s-cis diene conformation in, 496-497... 

Most Diels-Alder reactions, particularly the thermal ones and those involving apolar dienes and dienophiles, are described by a concerted mechanism [17]. The reaction between 1,3-butadiene and ethene is a prototype of concerted synchronous reactions that have been investigated both experimentally and theoretically [18]. A concerted unsymmetrical transition state has been invoked to justify the stereochemistry of AICI3-catalyzed cycloadditions of alkylcyclohexenones with methyl-butadienes [12]. The high syn stereospecificity of the reaction, the low solvent effect on the reaction rate, and the large negative values of both activation entropy and activation volume comprise the chemical evidence usually given in favor of a pericyclic Diels-Alder reaction. 

Pericyclic Diels-Alder reactions are suprafacial reactions and this manner of bond formation preserves in the cycloadduct the relative stereochemistry of the substituents at Ci and C4 and at Ci and C2 of the parents diene and dienophile, respectively (Scheme 1.7). The relative stereochemistry of the substituents in the... 

The stereochemistry of substituents at C-1 and C-4 of the diene and that of substituents at C-1 and C-2 of the dienophile are preserved in the cycloadduct because the Diels-Alder is a concerted reaction that takes place suprafacially on both components. 

The non-preservation of cis stereochemistry of dienophiles 24 and 26 in the adducts 25 and 27 is due to a cis-trans photoisomerization of the double bond and to the concerted suprafacial Diels-Alder cycloaddition of diene to the ground state of trans dienophiles. 

The cycloadditions of the C-2 vinyl glicals with maleic anhydride are an interesting example of facial stereocontrol. The allylic methoxy group in dienes 55a and 55b exerts an nnh -stereodirecting effect as shown by the stereochemistry of the endo-cycloadducts 56 and 57 obtained as the sole products from 55a and 55b, respectively, and by the fact that 55c produces [51] a mixture of the diastereoisomers 56c and 57c (Scheme 2.22). When linear acetylenic dienophiles were used, the degree of facial diastereoselectivity decreased, which indicates its dependence on steric effects. 

The transition state assembly 55 (Figure 3.8), that rationalizes the stereochemistry of the cycloadduct, is consistent with the structure of the chiral catalyst determined by an X-ray diffraction study. Interestingly it has been shown [58] that in the cycloadditions of maleimides 56 with 2-methoxy-l,3-butadiene, the enantioselection depends on the bulkiness of Ar and Ari groups of catalyst 54 and dienophile 56, respectively (Scheme 3.13). The importance of the bulky Ari... 

The more reactive furan (139a) undergoes thermal Diels-Alder reaction [52] with reactive dienophiles such as maleic anhydride and maleimide (Scheme 5.21). Whereas the cycloaddition with the maleic anhydride afforded the exoadduct at room temperature, the stereochemistry of the reaction of maleimide depends on the reaction temperature. 

Diels-Alder reaction is one of the most fundamental reactions for organic synthesis. Its synthetic utility is unquestioned. The stereochemistry of the reactions has attracted much attention. The retention of stereochemistry in the diene and the dienophile, the predominant formation of endo-attack products in the reactions of cyclic dienes, and highly controlled regioselectivity in the reactions of substimted dienes and... 

Answer Diels-Alder disconnection (7a) reveals a diene (9), with no stereochemistry, and a dienophile (10) which must be trans to give trans groups in (7). The one-step synthesis is successful. ... 

The cyclohexene is easy to see so that the Diels-Alder disconnection follows. The stereochemistry of the double bonds comes from two separate arguments the dienophile (a in 5) must be trarjs as the two substituents it produces in (4) are also trans. The diene must be all ain or all trann since the two substituents it produces in (4) are ois (both down). The all tvan, is needed because endo approach (6) is preferred. 

Some examples of IMDA reactions are given in Scheme 6.5. In Entry 1 the dienophilic portion bears a carbonyl substituent and cycloaddition occurs easily. Two stereoisomeric products are formed, but both have the cis ring fusion, which is the stereochemistry expected for an endo TS, with the major diastereomer being formed from the TS with an equatorial isopropyl group. 

Diels-Alder reactions are attractive for synthetic application because of the predictable regio- and stereochemistry. There are, however, limitations on the types of compounds that can serve as dienophiles or dienes. As a result, the idea of synthetic equivalence has been exploited by development of dienophiles and dienes that meet the reactivity requirements of the Diels-Alder reaction and can then be converted to the desired structure. For each of the dienophiles and dienes given below, suggest a Diels-Alder reaction and subsequent transformation(s) that would give a product not directly attainable by a Diels-Alder reaction. Give the structure of the diene or dienophile synthetic equivalent and indicate why the direct Diels-Alder reaction is not possible. 

Note Added in Proof. The stereochemistry of the Diels-Alder addition reactions shown in Scheme 1 to give products 20-22 has been examined by 400 MHz lH-NMR. These data indicate that the cycloadditions occur with a high degree of stereoselectivity (having diastereoselectivities of greater than 94 6). The chiral Fe environment of the dienophile 17 strongly influences the direction of the facial attack of the diene reactants. 

The cycloaddition of ketone 54 could be effected in a sealed glass tube in a modified microwave oven to afford the tricyclic system stereoselectively. This major adduct arose via the preferred transition state, in which the nonbonded interactions were minimized, because of the alignment of the dienophile beneath the triene unit furthest from the MOM substituent. This pattern of n-facial selectivity implies that, with the natural C2 stereoselectivity, the preferred geometry should provide the relative stereochemistry required for taxol itself. 

Helmchen and co-worker investigated the use of phosphinooxazolines as ligands for copper(II) catalyzed Diels-Alder reactions (Scheme 19) (214). Optimal selectivities are found for a-naphthyl-substituted phosphinooxazoline (299). These catalysts require 2.5 h to induce complete conversion to cycloadduct, compared to 18 h using the triflate complex 269c under identical conditions. Helmchen invokes a square-planar metal geometry to explain the stereochemistry of the adducts, similar to the model proposed by Evans. He suggests that the bulky phosphine substituents are required to orient binding of the dienophile in such a way as to place the olefin directly below the terf-butyl substituent on the oxazoline. 

A normal Diels-Alder reaction is a (n4s + n2s) cycloaddtion and the stereochemistry of both the diene and alkene is retained in the cyclization process. The diene and alkene approach each other in parallel planes. The bonding ineraction involves between Cj and C4 of the diene and carbon atoms of the dienophilic double bond are in a six center arrangement as illustrated below ... 

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