Nucleophilic addition salt effects

The attack of the nucleophile on the acceptor-substituted allene usually happens at the central sp-hybridized carbon atom. This holds true also if no nucleophilic addition but a nucleophilic substitution in terms of an SN2 reaction such as 181 — 182 occurs (Scheme 7.30) [245]. The addition of ethanol to the allene 183 is an exception [157]. In this case, the allene not only bears an acceptor but shows also the substructure of a vinyl ether. A change in the regioselectivity of the addition of nucleophilic compounds NuH to allenic esters can be effected by temporary introduction of a triphenylphosphonium group [246]. For instance, the ester 185 yields the phos-phonium salt 186, which may be converted further to the ether 187. Evidently, the triphenylphosphonium group induces an electrophilic character at the terminal carbon atom of 186 and this is used to produce 187, which is formally an abnormal product of the addition of methanol to the allene 185. This method of umpolung is also applicable to nucleophilic addition reactions to allenyl ketones in a modified procedure [246, 247]. 

Nucleophilic addition readily takes place with pyridinium salts attack is normally easier at the C-2(6) position, since the inductive effect of the positively charged nitrogen atom is greatest here (Scheme 2.28). When the sites adjacent to the nitrogen are blocked, however, attack occurs at C-4. The products are dihydropyridines. 

Nucleophilic addition takes place at C-1, and this is considerably enhanced if the reaction is carried out upon an isoquinolinium salt. Reduction with lithium aluminium hydride [tetrahydroaluminate(III)] in THF (tetrahydrofuran), for example, gives a 1,2-dihydroisoquinoline (Scheme 3.15). These products behave as cyclic enamines and if isoquinolinium salts are reacted with sodium borohydride [tetrahy-droboronate(III)] in aqueous ethanol, further reduction to 1,2,3,4-tetrahydroisoquinolines is effected through protonation at C-4 and then hydride transfer from the reagent to C-3. 

The Lewis acid-catalyzed three-component reaction of dihydropyridines, aldehydes, and />-substituted anilines efficiently yields highly substituted tetrahydroquinolines in a stereoselective manner, through a mechanism believed to be imine formation followed by formal [4-1-2] cycloaddition (Scheme 41). The 1,4-dihydropyridine starting materials were also prepared in situ by the nucleophilic addition of cyanide to pyridinium salts, creating in effect a one-pot four-component reaction <20030L717>. 

The development of methods to effect nucleophilic addition to carbon-carbon double bonds by prior activation with metal cations has been applied, at least in a preliminary way, as a method of pyrrole ring closure. The conversion of butadienes to N-substituted pyrroles can be accomplished in two stages. In acetic add, 1,4-dienes react with PdnCl2 to give tr-allyl complexes with introduction of acetate at C-4. The ir-allyl complexes then react with amines to give a l-amino-4-acetoxy-2-butene (equation 70). When the addition of the amine is carried out in the presence of a silver salt and triphenylphosphine, a pyrrole is isolated, probably by cyclization of the amino-substituted allyl-Pd complex (equation 71) (81CC59). Although this procedure is attractive in terms of the simplicity of the... 

Intramolecularity was the next issue to be probed within the context of alkynyliodonium salt/nucleophile addition reactions.53 1 No prior history was available to guide us, and so the prospects for success remained uncertain. Of primary concern was the potential for iodonium salt/base destructive interactions in competition with the desired N-H deprotonation reaction. A substrate that bore some resemblance to key portions of the agelastatin precursor 33 was prepared (Scheme 6), compound 39. This species duplicated the alkynyliodonium/"amide" pairing of the real system, but it lacked the complex piperazine carbene trap of 33. The tosylimide (pre)nucleophile was proposed as a compromise between what we really wanted (an N-methyl amide) and what would likely work (a tosylamide). Simple treatment of 39 with mild base effected the desired bicyclization to afford the tosylimide product 41 in decent yield. A transition state model 40 for C-H insertion that features an equatorial phenyl unit might rationalize the observed sense of diastereoselectivity. So, at least for 39, no evidence for possible interference by iodonium/base reactions was detected. 

It is important to differentiate between the effects of a non-nucleophilic salt, such as Mg(C104)2, on the one hand, and a weak nucleophilic salt, such as EtjNOAc, on the other. The effect of non-nucleophilic salts on photo-oxygenation via electron transfer can be understood as the stabilization of ion radicals by coulombic interaction, resulting in the suppression of an electron back-transfer between ion radicals. The weak nucleophilic salts cause unusual effects. Nucleophilic addition to the cation radical and complexation with the ion radicals bring these effects about. 

Although dimeric Sharpless ligands as catalysts showed impressive results in related organocatalytic transformations, they provided only limited success in asymmetric MBH reactions (Scheme 5.12) [70]. These compounds are bifunctional catalysts in the presence of acid additives one of the two amine function of the dimers forms a salt and serves as an effective Bronsted acid, while another tertiary amine of the catalyst acts as a nucleophile. Whereas salts derived from (DHQD)2PYR, or (DHQD)2PHAL afforded trace amounts of products in the addition of methyl acrylate 8a and electron-deficient aromatic aldehydes such as 27, (DHQD)2AQN, 56, mediated the same transformation in ee up to 77%, albeit in low yield. It should be noted that, without acid, the reaction afforded the opposite enantiomer in a slow conversion. 

These salt effects are schematically depicted in Scheme 8. As we will discuss later more in detail (Sections Vl.B.3 and VII.E.3), mechanistically, salts may act in two different ways. In polar solvents they will suppress the free ions and considerably reduce their lifetime. This often converts bimodal MWD to monomodal MWD and provides controlled polymers. However, in polymerization of vinyl ethers initiated by strong Lewis acids such as SnCl4, where only ion pairs are present after addition of a few percent of salts or in nonpolar toluene, control is still very poor (Fig. 17B). Controlled polymers can be obtained only after addition of a more than equimolar amount of tetra-n-butylammonium halides. This implies that the salts change the weakly nucleophilic counterion SnCIs-to the more nucleophilic SnCl62 , which faster converts growing carbo-cations to covalent species. Another effect of added salts is related to... 

This review article deals with addition and cycloaddition reactions of organic compounds via photoinduced electron transfer. Various reactive species such as exdplex, triplex, radical ion pair and free radical ions are generated via photoinduced electron transfer reactions. These reactive species have their characteristic reactivities and discrimination among these species provides selective photoreactions. The solvent and salt effects and also the effects of electron transfer sensitizers on photoinduced electron transfer reactions can be applied to the selective generation of the reactive species. Examples and mechanistic features of photoaddition and photocycloaddition reactions that proceed via the following steps are given reactions of radical cations with nucleophiles reactions of radical anions with electrophiles reactions of radical cations and radical anions with neutral radicals radical-radical coupling reactions addition and cycloaddition reactions via triplexes three-component addition reactions. 

This seemingly simple result may have far reaching consequences. For example, it may help to explain the effect of added lithium salts in nucleophilic additions to cyclohexanones as discussed earlier in this chapter. Thus, model (63) shown in Figure 472.135-137 explain the enhancement of rate and may also be relevant to the origins of stereoselectivity in this reaction. Of course, the exact location of the lithium atom and the aggregation state of the adding nucleophile are subject to speculation, since for lithium these parameters seem to be highly variable. 

Chen, Y.-T., Barletta, G. L., Haghjoo, K., Cheng, J. T., Jordan, F. Reactions of Benzaldehyde with Thiazolium Salts in Me2SO Evidence for Initial Formation of 2-( -Hydroxybenzyl)thiazolium by Nucleophilic Addition, and for Dramatic Solvent Effects on Benzoin Formation. J. Org. Chem. 1994, 59, 7714-7722. 

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