Esters chelation effects

The benzoic acid derivative 457 is formed by the carbonylation of iodoben-zene in aqueous DMF (1 1) without using a phosphine ligand at room temperature and 1 atm[311]. As optimum conditions for the technical synthesis of the anthranilic acid derivative 458, it has been found that A-acetyl protection, which has a chelating effect, is important[312]. Phase-transfer catalysis is combined with the Pd-catalyzed carbonylation of halides[3l3]. Carbonylation of 1,1-dibromoalkenes in the presence of a phase-transfer catalyst gives the gem-inal dicarboxylic acid 459. Use of a polar solvent is important[314]. Interestingly, addition of trimethylsilyl chloride (2 equiv.) increased yield of the lactone 460 remarkabiy[3l5]. Formate esters as a CO source and NaOR are used for the carbonylation of aryl iodides under a nitrogen atmosphere without using CO[316]. Chlorobenzene coordinated by Cr(CO)j is carbonylated with ethyl formate[3l7]. 

Several important classes of polar monomers have so far eluded copolymerization by the Pd(II) system. Vinyl chloride insertion, for example, leads to catalyst deactivation following P-halide elimination to form inert chloride species such as 1.32, as shown by Jordan [90], Similarly, attempted vinyl acetate copolymerization results in deactivation by an analogous acetate elimination process, although the ester chelate intermediate that forms after insertion also effectively shuts down the reaction [90], Therefore, -elimination of polar groups represents a significant and unresolved problem for late transition metal polymerization systems unless access of the metal to it is restricted. 

Scheme 11.16 Diastereocontrol via chelate effect stereoselective 5-exo-trig cyclization on to a cumulated Jt-bond of a chelated ester-substituted ketyl radical anion 50 [74]. a 94 6 mixture of diastereomers.

In summary, of the many chiral auxiliaries used in the asymmetric synthesis of carbonyl compounds via imines, those able to form a methoxymethyl-chclated azaenolate show the best enantioselectivities (see Tabic 7). The same is true for valine and im-leucine derivatives which form rigid chelates via their carboxyl groups. In particular, quaternary centers (see Table 6) and a-alkvl-/i-oxo esters arc effectively prepared using these chiral auxiliaries. 

In the case of inert cobalt(m) complexes it is possible to isolate the chelated products of the reaction. Let us return to the hydrolysis of the complex cations [Co(en)2(H2NCH2C02R)Cl]2+ (3.1), which contain a monodentate iV-bonded amino acid ester, that we encountered in Fig. 3-8. The chelate effect would be expected to favour the conversion of this to the chelated didentate AO-bonded ligand. However, the cobalt(iu) centre is kinetically inert and the chloride ligand is non-labile. When silver(i)... 

If optically active sulfoxides such as methyl p-tolyl sulfoxide give a poor diastereoselecdvity when such an a-sidfinyl carbanion is added to a carbonyl, " the presence of another function such as ester, sulfide or amide, which has a chelating effect in the transition state, makes optically active a-sulfinyl esters, sulfides or amides very useful in asymmetric aldol-type condensation (Scheme 4i).97.io6-i09... 

A polymer (P-DHB) (XI) based on catechol, the active functional group of enterobactin, was recently synthesised by the reaction of polyvinyl amine with the ethyl ester of 2,3-dihy-droxybenzoic acid (DHB). Only about one third of the amine groups was found to be substituted with DHB units. The formation constant of the iron(III) complex (log K = 40) is the same as that reported for the simple dimethyl amide of DHB and so there does not appear to be any appreciable chelate effect. 

The extent of PHP adsorption is too low to be measured by loss from bulk solution. The catalysis of PHP hydrolysis by various metal oxides must come from their ability to chelate the ester and polarize the carbonyl C-O bond. Apparently Ti oxides and Fe oxides are capable of doing this, while Al oxides are not. Ionic strength effects on PHP surface-catalyzed hydrolysis are small electrostatics apparently have a minor role in ester chelation and subsequent attack by OH (Torrents and Stone, 1991). 

The Sharpless asymmetric epoxidation (sec. 3.4.D.i) exploits this chelation effect because its selectivity arises from coordination of the allylic alcohol to a titanium complex in the presence of a chiral agent. The most effective additive was a tartaric acid ester (tartrate), and its presence led to high enantioselectivity in the epoxidation.23 An example is the conversion of allylic alcohol 40 to epoxy-alcohol 41, in Miyashita s synthesis of the Cg-Ci5 segment of (-t-)-discodermolide.24 in this reaction, the tartrate, the alkenyl alcohol, and the peroxide bind to titanium and provide facial selectivity for the transfer of oxygen from the peroxide to the alkene. Binding of the allylic alcohol to the metal is important for delivery of the electrophilic oxygen and... 

Chelation effects in general override the usual preferences in the formation of lithium ester enolates, and the (Z)-configured enolates are obtained nearly exclusively. Therefore the stereochemical outcome of the rearrangement should only be controlled by the olefin geometry in the allyl moiety and by the transition state (chair vs. boat). If substituted allyUc esters of glycolic add or related a-hydroxy-acids are subjected to rearrangement, synthetically valuable unsaturated a-hydroxyadds are obtained, albeit the yield and stereoselectivity strongly depends on the substrate and the reaction conditions used. 

The cyclopalladation of allylic or homoallylic amines and sulfides proceeds due to the chelating effect of N and S atoms, and has been used for functionalization of alkenes. For example, i-propyl 3-butenyl sulfide is carbopalladated with methyl cy-clopentanecarboxylate and Li2PdCl4. Reduction of the chelated complex with sodium cyanoborohydride affords the alkylated keto ester in 96% yield (eq 24). Functionalization of 3-N,N-dimethylaminocyclopentene for the synthesis of a prostaglandin skeleton has been carried out via a IV-chelated palladium complex as an intermediate. In the first step, malonate was introduced regio- and stereoselectively by carbopalladation (eq 25). Elimination of a /3-hydrogen generated a new cyclopentene, and its oxypalladation with 2-chloroethanol, followed by insertion of 1-octen-3-one and /3-elimination, afforded the final product. 

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