Electron-rich double bond

Cyclo ddltion. Ketenes are ideal components ia [2 + 2] cycloadditions for additions to the opposite sides of a TT-system as shown ia the cyclobutane product (2) ia Figure 1. Electron-rich double bonds react readily with ketenes, even at room temperature and without catalysts. In conjugated systems, ketenes add ia a [2 + 2] fashion. This is illustrated ia the reaction foUowiag, where the preferential orientation of L (large substituent) and S (small substituent) is seen (40). This reaction has been used ia the synthesis of tropolone [533-75-5]. 

The product from fluonnation of sodium acetate is acetyl hypofluorite [64], which IS isolated and characterized [65] The value of this reagent lies in its relative mildness, because it reacts cleanly with most olefins adding the elements of acetoxyl and fluorine [66] Tnfluoroacetyl hypofluorite adds cleanly only to benzylic or electron-rich double bonds... 

Active carbonyl compounds such as benzaldehyde attack the electron-rich double bond in DTDAFs to give a dipolar adduct, which immediately undergoes dissociation with formation of two molecules of 146 (64BSF2857 67LA155).Tlie existence of by-products such as benzoin led to the synthetic application of thiazolium salts in the acyloin condensation. For example, replacement of the classic cyanide ion by 3-benzyl-4-methyl-5(/3-hydroxyethyl) thiazolium salts allowed the benzoin-type condensation to take place in nonaqueous solvents (76AGE639) (Scheme 57). 

The more electron-rich double bond was found to react more rapidly, which allowed for good regioselectivity. The regioselectivity could be further increased by... 

Intramolecular Mannich reactions of iminium 1 and acyliminium ions (see Section D.1.4.5.) with electron-rich double bonds are important reactions in the synthesis of naturally occurring alkaloids. In general, the iminium ions are not isolated but produced as intermediates. 

In accordance with this, the reaction of the electron-donor-substituted butadienes 170 (R=Ph, OMe) with the arylcarbene complexes 163 yields divinylcyclopropane intermediates 168 with high chemoselectivity for the electron-rich double bond in 170, which readily undergo a [3,3]-sigmatropic rearrangement to give the as-6,7-disubstituted 1,4-cycloheptadiene derivatives... 

Electronically rich 1,3-butadienes such as Danishefsky s diene react with chromium alkenylcarbene complexes affording seven-membered rings in a formal [4S+3C] cycloaddition process [73a, 95a]. It is important to remark on the role played by the metal in this reaction as the analogous tungsten carbene complexes lead to [4S+2C] cycloadducts (see Sect. 2.9.1.1). Formation of the seven-membered ring is explained by an initial cyclopropanation of the most electron-rich double bond of the diene followed by a Cope rearrangement of the formed divinylcyclopropane (Scheme 65). Amino-substituted 1,3-butadienes also react with chromium alkenylcarbene complexes to produce the corre-... 

The chemoselectivity of the ozonolysis is all right because ozone attacks the most electron-rich double bond, that is the one furthest from the carbonyl group in (17, R=H). Reductive work-up is again needed after the ozonolysis,... 

Peracids would attack the other, more electron-rich, double bond. We need a nucleophilic epoxidising agent... 

Cyc1oadditiORE between chloroketcnes and electron-rich double bonds occur very easily. The microbial toxin moniliformin (10) has been made using this reaction,... 

Several other examples of regioselective cyclopropanation of 1- and 2-substituted butadienes in the presence of copper catalysts are known (Scheme 5). 2-Trimethyl-siloxy-1,3-butadiene parallels the behavior of other 2-substituted butadienes (see Table 9) in that the electron-rich double bond is cyclopropanated 60. With the 1-methoxy-, acetoxy- or trimethylsilyloxy-substituted butadienes 17, 18 and 19, both double bonds are cyclopropanated, thus giving rise to sometimes unseparable mixtures of regio- and stereoisomers 79). Perhaps, the yields of separated and isolated regioisomers in some cases do not reflect the true regioselectivity as considerable... 

Exclusive O/H insertion takes place in the Rh2(OAc)4-catalyzed reaction of diethyl diazomalonate with a,(J-unsaturated y-hydroxyesters 167 a-c163). This is not surprising in view of the reluctance of electrophilic metal carbenes to add to electron-poor double bonds (see Sect. 2.3.2). However, the more electron-rich double bond of p-methoxybenzyl clavulanate 168 also cannot compete with the O—H function for the same carbenoid 164). The steric situation at the trisubstituted double bonds of 167 and 168 may be reason enough to render an attack there highly unfavorable as compared to the easily accessible O—H function, no matter how nucleophilic the double bond is. 

Phomactin A is the most challenging family member architecturally. The fragments that are most challenging are highlighted in Fig. 8.4. In Box-A, the highly sensitive hydrated furan is prone to dehydration under acidic or basic conditions, and any total synthesis almost certainly must save introduction of this fragment until the end game. Box-B relates to the strained and somewhat twisted electron-rich double bond. This trisubstituted olefin is extremely reactive toward electrophilic oxidants. 

The various transitions of triafulvenes to pentafulvenes achieved by addition of electron-rich double bonds is complemented by the reaction of triafulvenes with ynamines and yndiamines299, which gives rise to 3-amino fulvenes 539. This penta-fulvene type deserves some interest for its merocyanine-like inverse polarization of the fulvene system and its formation is reasonably rationalized by (2 + 2) cycloaddition of the electron-rich triple bond to the triafulvene C /C2 bond (probably via the dipolar intermediate 538) ... 

On heating, dihydrooxazines (548) undergo the known [4 +2]-cycloreversion to give the previously unknown conjugated en-imines CH2=C(C02Me)CH=N—E as intermediates. The latter can be trapped in a Diels—Alder reaction at the terminal or internal electron-rich double bond. 

In the synthetic procedure, verbenone 118, the air oxidation product of pinene, is first treated with t-BuOK. followed by the addition of prenyl bromide to give a C-ll alkylated product. Selective ozonolysis of the more electron-rich double bond provides the aldehyde 119 with 85% yield. The A ring of taxane is then created through photorearrangement of the aldehyde 119, yielding the chrysanthenone derivative 120 (85% yield, over 94% ee). 

J(P1)427>. The regioselectivity of the second radical cyclization depends on the electronic nature of the homoallylic double bond pyrrolizinones 240 which result from a final 5-o -cyclization mode are preferred in the case of electron-poor carbon-carbon double bonds, such as enones or enoates electron-rich double bonds lead to indolizinones via a final 6-f db-cyclization. The best yields of pyrrolizinones were observed with iodide precursors. The cir-isomers of 240 predominate in this 5-f rf6i-5-f3co-cyclization. 

It is noteworthy that similar products are also obtained from oxidation of enol silyl ethers with two equivalents of tris(p-bromo-phenyl)aminium hexa-chloroantimonate which is known to oxidize electron-rich double bonds to... 

The hydrogen ion of the acid catalyst is an electrophile and attacks the electron-rich double bond in the propene molecule to form a carbocatlon. 

The first route relies on the ROP of cyclic ketene acetals [1-3]. The electron-rich double bond is prone to react with radicals and electrophiles. Therefore, this class of monomers undergoes cationic and radical polymerization. For example, radical initiators react with the double bond to provide a new tertiary radical (Fig. 2). Two distinct mechanisms of polymerization can then take place direct vinyl polymerization or indirect ring opening of the cycle accompanied by the formation of a new radical, which is the propagating species (Fig. 2). The ester function is formed... 

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