Intramolecular reactions stereoselectivity

Chelation control of the intramolecular reaction between an allylsilane and an aldehyde or ketone has been carefully investigated. Excellent stereoselectivity was found for cyclization of B-oxo esters using titanium(IV) chloride as the Lewis acid, less good selectivity for cyclization of /l-diketones70. 

The stereoselectivity of these intermolecular reactions between 1-alkoxyallylstannanes and aldehydes induced by boron trifluoride-diethyl ether complex is consistent with an open-chain, antiperiplanar transition state. However, for intramolecular reactions, this transition state is inaccessible, and either (Z)-.yyn-products are formed, possibly from a synclinal process105, or 1,3-isomerization competes113. Remote substituents can influence the stereoselectivity of the intramolecular reaction114. 

It is evident (see Section A.2.3.5.3.) that intramolecular reactions generally proceed with higher stereoselectivity than the comparable intermolecular reactions. 

Intramolecular cycloadditions of furans are a useful method for creating an oxygenated cyclohexane ring in rigid cycloadducts. Thus, a MeAICI2-catalyzed intramolecular reaction [40] of compounds 34 leads stereoselectively to tricyclic cycloadducts (Equation 3.8). The reaction yield is strongly dependent on the quantity of the catalyst and the type of substituent at the olefmic double bond. Cycloadduct 35 (R = R2 = Me, Ri = R3 = R4 = H) was then converted [40b] into 1,4-epoxycadinane (36). 

Cyclopenta[fc]dioxanes (44) are accessible from the reaction of the dioxenylmolybdenum carbene complex (43) with enynes <96JOC159>, whilst an intramolecular and stereoselective cyclisation of (Ti5-dienyl)tricarbonyliron(l+) cations affords chiral frans-2,3-disubstituted 1,4-dioxanes <96JOC1914>. 2,3-Dimethylidene-2,3-dihydro-1,4-benzodioxin is a precursor of the 3,8-dioxa-lff-cyclopropa[i]anthracene, which readily dimerises to dihydrotetraoxaheptacene (45) and the analogous heptaphene <96AJC533>. 

Intramolecular reactions can also occur between carbonyl groups and allylic silanes. These reactions frequently show good stereoselectivity. For example, 7 cyclizes primarily to 8 with 4% of 9 as a by-product. The two other possible stereoisomers are not observed.98 The stereoselectivity is attributed to a preference for TS 7A over TS 7B. These are both synclinal structures but differ stereoelectronically. In 7A, the electron flow is approximately anti parallel, whereas in 7B it is skewed. It was suggested that this difference may be the origin of the stereoselectivity. 

According to the stepwise electrophilic reaction mechanism, the differences in the stereochemistries of the products from the reactions of alkenes with cyclic 49 and acyclic 51 disulfonium dications can be explained by the larger rates of the intramolecular reactions. In the case of a cyclic dication, the carbocationic center in intermediate 94, which is formed as the result of initial attack by a S-S dication on a double C=C bond reacts with nucleophile intramolecularly, thus conserving the configuration of the substituents at the double bond. On the other hand, an acyclic dication undergoes transformation to two separate particles (95 and dimethylsulfide) with a consequent loss of stereoselectivity. Additional experiments with deuteretad alkenes confirm that reaction is not stereoselective, lending further support to the stepwise mechanism (Scheme 36).106... 

Intermolecular Cycloaddition at the C=C Double Bond Addition at the C=C double bond is the main type of 1,3-cycloaddition reactions of nitrile oxides. The topic was treated in detail in Reference 157. Several reviews appeared, which are devoted to problems of regio- and stereoselectivity of cycloaddition reactions of nitrile oxides with alkenes. Two of them deal with both inter- and intramolecular reactions (158, 159). Important information on regio-and stereochemistry of intermolecular 1,3-dipolar cycloaddition of nitrile oxides to alkenes was summarized in Reference 160. 

This catalyst system was the first to utilize both terminal alkynes and olefins in the intramolecular reaction. Although a mechanistic rationale for the observed stereoselectivity was not offered, the formation of the single stereoisomer 26 may be rationalized through the diastereotopic binding of the rhodium complex to the diene moiety (Scheme 12.3). This facial selective binding of the initial ene-diene would then lead to the formation the metallacycle III, which ultimately isomerizes and reductively eliminates to afford the product [14]. 

The convergence of the nitronate and nitrile oxide cycloadditions has allowed for the direct comparisons of yields and stereoselectivities of the two processes. For intramolecular reactions, the nitronate dipole typically required longer reaction times and/or elevated temperatures (22,98,135), however, the nitronate cycloaddition shows considerably higher diastereoselectivity (Table 2.42). Interestingly, the diastereoselectivity is dependent on the placement of a substituent on the tether. In the case of the silyl nitronate derived from 172, the diastereoselectivity is controlled by the substituent at C(l), while cyclization of the analogous nitrile oxide is governed by the substituent at C(l ) (Scheme 2.10) (124). 

Modern synthetic chemistry has taken up the challenge of acyclic substrate-induced stereoselection302, including auxiliary-directed stereoselectivity. The main principles are 1,2-in-duction, the formation of cyclic intermediates, and intramolecular reactions. Many aspects, rules , and examples of diastereoface-differentiating reactions, both in cyclic and in acyclic systems, are summarized in Section 2.3.5.2. 

The well-known and widespread phenolic oxidations3 and the related nonphenolic oxidations4-6 for the formation of biaryl linkages are not restricted to the classic cases ofintermolec-ular coupling reactions. There are also examples of intramolecular coupling reactions with the option of performing the reaction stereoselectively, provided that some electronic requirements are fulfilled ... 

Intramolecular reactions are obliged to obey the powerful rules that govern which cycloadditions are allowed and which forbidden, but they can override the weaker forces controlling regio- and stereoselectivity, and it is important to remember this opportunity for synthetic design, when the trends outlined above are in conflict with the aims of the synthesis. 

Photocycloaddition reactions have been used as key transformations in many organic syntheses to construct organic compounds having unique structures that are hardly accessible by other methods. However, their stereoselectivity is not necessarily high, and many efforts have been done to attain the highly regioselective and stereoselective photocycloadditions. They are discussed in terms of the electronic nature of substrates, the steric repulsions between substituents, and the conformational restrictions of intramolecular reactions. 

Aryl borates such as catechol butylborate and triphenyl borate undergo a syn -stereoselective reaction with arylazirines.41 The syn-stereoselectivity was attributed to a transition state where the phenoxide tethered to the boron is transferred intramolec-ularly to the most substituted carbon. The reaction is completed when the phenoxide anion tethered to the boron reacts with the most substituted carbon of the substrate in an intramolecular reaction. 

In summary, the C-H insertion chemistry of rhodium carbenoids is a very powerful method for transformation of C-H bonds. Highly regioselective and stereoselective reactions are possible and several classes of chiral catalyst are capable of very high asymmetric induction. The chemoselectivity in this chemistry is exceptional, as illustrated by the numerous intermolecular and intramolecular reactions described in this overview. Most notably, this chemistry offers new and practical strategies for enantioselective synthesis of a variety of natural products and pharmaceutical agents. 

Once a chiral silane is synthesized, intramolecular reaction such as the Heck reaction and the radical cyclization reaction with transfer of chirality from the silicon center can be pursued. Other reactions of interest include the stereoselective hydrosilylation of aldehydes and ketones. Our method could be used to tether chiral silanes to solid support for uses in solid support... 

Norbornene structures can be linked by long chain diesters. The copper catalyzed photocycloaddition of these alkenes gives rise to the cyclobutane shown in Sch. 26 [38]. The intramolecular reaction is stereoselective. 

Krief has applied selenium chemistry to some anionic cascade cyclisations.128 For example, 293 can be cyclised in two successive 5-exo reactions to give a mixture of the stereoisomers of 297. If 294 is warmed to 0 °C, an alternative sort of tandem process occurs after cyclisation onto the alkene, the organolithium 295 undergoes an intramolecular displacement, stereoselectively generating the 5,3-fused system of 296. Similar intramolecular cyclopropanations (of a-bromo organolithiums) have been described by Hoffmann151 but are probably mediated by carbenes rather than a sequential cyclisation-substitution sequence. 

Other terminal olefins were transformed to the corresponding cyclopropane esters with Z-menthyl and d-menthyl diazoacetates with high stereoselectivity up to 98% ee (Scheme 3). Intramolecular reaction of the phenyl-allyl ester 9 was carried out to give the bicyclic compound 10 with 86% ee and 93% yield. The enantioselectivity for intramolecular cyclopropanation of the 3-methylbutenyl ester 11 was compared with chiral Cu(I), Rh(II), and Ru Pybox catalysts Rh>Ru>Cu [26]. 

Electrophilic substitutions of alkenyl-, aryl-, and alkynylsilanes with heteroatom-stabilized cationic carbon species generated by the action of a Lewis or Brpnsted acid (acyl cation, oxocarbenium ion, etc.) provide powerful methods for carbon-carbon bond formation. Particularly, intramolecular reactions of alkenylsilanes with oxocarbenium and iminium ions are very valuable for stereoselective construction of cyclic ether and amine units.21-23 For example, the BFj OEt -promoted reaction of (E)- and (Z)-alkenylsilanes bearing an acetal moiety in the alkenyl ligand gives 2,6-disubstituted dihydropyrans in a stereospecific manner (Scheme l).23 Arylsilanes also can be utilized for a similar cyclization.24... 

Just as the stereoselectivity may be compromised in intramolecular reactions, so may the regioselec-... 

In 1996, our research group observed an activity of triazolium salts, for example (S,. S )-97 as precatalysts in this intramolecular reaction. The stereoselective synthesis of various 4-chromanones (f )-138 via the first asymmetric intramolecular Stetter reaction was performed with enantiomeric excesses of 41%-74% and yields of 22%-73% (Scheme 38) (Enders etal. 1996c). 

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