Allyl esters palladium catalysis

Synthesis of isomeric chiral protected (63 )-6-amino-hexahydro-2,7-dioxopyrazolo[l,2- ]pyrazole-l-carboxylic acid 280 is shown in Scheme 36. Crude vinyl phosphonate 275, obtained by treatment of diethyl allyloxycarbonylmethyl-phosphonate with acetic anhydride and tetramethyl diaminomethane as a formaldehyde equivalent, was used in the Michael addition to chiral 4-(f-butoxycarbonylamino)pyrazolidin-3-one 272. The Michael addition is run in dichloro-methane followed by addition of f-butyl oxalyl chloride and 2 equiv of Huning s base in the same pot to provide 276 in 58% yield. The allyl ester is deprotected using palladium catalysis to give the corresponding acid 277, which is... 

Alkylation and deprotection of N-protected aminomethylphosphonate esters 6 are shown in Scheme 6. The nitrogen is protected as the imine derived from benzophenone or a benz-aldehyde, and a variety of conditions are used for deprotonation and alkylation (Table 2). The benzaldehyde imine of aminomethylphosphonate can be deprotonated with LDA and alkylated with electrophilic halides (entries 1 and 2). For the best yields, saturated alkyl bromides require an equivalent of HMPA as an additive. 36 Allylic esters can be added to the carbanion with palladium catalysis (entries 3-7). 37,38 For large-scale production, phase-transfer catalysis appears to be effective and inexpensive (entries 8-12). 39,40 ... 

The reactions of this section use stabilized carbanions formed from C—H-addic compounds by deprotonation. As phosphines are the only successful ligands known up to now, these reactions have been discussed in detail in Chapter 2, and we will again restrict this section to a few highlights. Carbanions derived from 1,3-diketones react with allylic esters enantioselectively under palladium catalysis with more than 80% ee [175]. Benzylamine is allylated by the same catalytic system, leading to substituted allyl-benzylamines with up to 97% ee (Fig. 4-32c) [176]. 

Another synthetic method for the production of pseudoionone, which starts from myrcene [94a], [94b], has never been commercialized for the production of fragrance materials (see also p. 45, geranylacetone). The process consists of a rhodium-catalyzed addition of methyl acetoacetate to myrcene, transesterification of the resulting ester with allyl alcohol, and an oxidative decarboxylation of the allyl ester under palladium catalysis to obtain pseudoionone. 

B.vi.a. Deprotection ofAllyl Esters. The deprotection of allyl esters under palladium catalysis has frequently been employed in various syntheses of pharmaceutically... 

Palladium is a useful catalyst in several reactions which lead to keto-esters. p-Keto-esters react with allylic carbonates, with catalysis by palladium, in a decarboxylative allylation reaction. y-Keto-esters are prepared, in reasonable yield, by the palladium-catalysed regioselective oxidation of Py-unsaturated esters. y-Keto-esters are obtained in good yield by the palladium-catalysed Reformatsky reaction of ethyl bromoacetate and acid chlorides. Derivatives of y-ketopimelic acid are formed by the rhodium-carbonyl-catalysed reaction of derivatives of acrylic acid with carbon monoxide. A mild method for the conversion of propiolic esters into P-keto-esters via thiol addition has been reported (Scheme 63) it has been used in a formal synthesis of ( )-thienamycin. 

The synthesis of quaternary amino acids 86 have been shown using azlac-tones 85 as nucleophiles and the Trost ligand 39 under palladium [179] or molybdenum catalysis (Scheme 8) [180]. The allylic alkylation of glycine imino esters under biphasic conditions has also been achieved using a chiral phase-transfer catalyst in combination with an achiral Pd catalyst producing the unnatural amino acid derivatives [181]. 

Three research groups discovered almost at the same time that non-C2-symmetrical oxazolines of the type 32 can be even more effective ligands for asymmetric catalysis than type 4 ligands (Fig. 11). For the palladium-catalyzed allylic substitutions on 62, record selectivities could be reached using 32 (X = PPhj) [30]. It seems that not only steric but also electronic factors, which cause different donor/acceptor qualities at the coordination centers of the ligand, seem to play a role here [31]. The reaction products can subsequently be converted to interesting molecules, for example 63 (Nu = N-phthalyl) can be oxidized to the amino acid ester 64 [32]. 

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