Methyl 2-acetamidoacrylate hydrogenation

Complex 33, containing a partially reduced 1,10-phenantroline-based monodentate NHC ligand led to 97% yield and 81% ee in the hydrogenation of methyl acetamidoacrylate (Figure 13.4). A bidentate NHC bearing a PPh2 unit with a chiral pseudo-o-[2.2]paracyclophane linker (34) was found to be a selective catalysts for non-functionalized trisubstituted alkenes, although functionalized alkenes were found to be sensitive to the H2 pressure. Also, the... 

Complex 7-AI2O3/PTA/ (/< ./< )-(Mc-DuPHOS)Rh(COD) 1 (1) was prepared and tested in the hydrogenation of the prochiral substrate methyl-2-acetamidoacrylate (MAA). After full conversion, the products were separated from the catalyst and analyzed for Rh and W content and product selectivity. The catalyst was re-used three times. Analytical results show no rhodium leaching is observed. Complex 1 maintains its activity and selectivity in each successive run. The first three runs show tungsten (W) leaching but after that no more W is detectable. The leached W comes from the excess of PTA on alumina. The selectivity of both tethered and non-tethered forms gave the product in 94% ee. 

Using unmodified Ru-BINAP and Rh-Et-DUPHOS catalysts Jacobs et al. performed hydrogenation reactions of dimethylitaconate (DMI) and methyl-2-acetamidoacrylate (MAA), respectively. [11,47] The continuous hydrogenation reaction was performed in a 100 mL stirred autoclave containing an MPF-60 membrane at the bottom, which also acts as a dead-end membrane reactor. The hydrogenation reactions will be discussed in paragraph 4.6.1. 

Zhang reported two new (S)-BINOL based ligands phosphine-phosphite (S,R)-o-BINAPHOS 163 and phosphine-phosphinite (S)-o-BIPNITE 164 [128]. Applications of these ligands in the Rh-catalyzed hydrogenation of methyl N-2-acetamido-cinnamate and methyl N-2-acetamidoacrylate induced very high enantioselectiv-ities (>99% ee), and with a wide range of substrates. 

Salzer et al. prepared a set of planar-chiral diphosphine ligands based on the arene chromium tricarbonyl backbone (Fig. 36.3) [21]. The straightforward four-step synthetic route allowed the preparation of 20 ligands of this family. These ligands were tested in Ru- and Rh-catalyzed enantioselective hydrogenation of various substrates, including the standard C=C substrates (dimethyl itaconate, methyl-2-acetamidocinnamate, methyl-2-acetamidoacrylate) as well as MEA-imine (l-(methoxymethyl)ethylidene-methylethylaniline) and ethyl pyruvate. Moderate conversions and ee-values were obtained. 

When the peptide synthesis was complete, the phosphines were deprotected by sequential treatment with MeOTf and HMPT (Scheme 36.9). Addition of the rhodium precursor then created the catalyst library, which was screened, on the pin in the enantioselective hydrogenation of methyl-2-acetamidoacrylate (see Scheme 36.10). Unfortunately, this beautiful concept was poorly rewarded with rather low enantioselectivities. 

The preparation of this type of catalyst is quite simple. HPAs such as phos-photungstic acid were adsorbed onto inorganic supports such as clays, alumina, and active carbon. Subsequently, the metal complex was added to form the immobilized catalyst. If necessary, the catalyst can be pre-reduced. These types of catalysts were developed mainly for enantioselective hydrogenations. For instance, a supported chiral catalyst that was based on a cationic Rh(DIPAMP) complex, phosphotungstic acid and alumina showed an ee-value of 93% with a TOF of about 100 IT1 in the hydrogenation of 2-acetamidoacrylic acid methyl ester (Fig. 42.4 Table 42.2). 

Fig. 42.4 Enantioselective hydrogenation of 2-acetamidoacrylic acid methyl ester.

Table 42.2 Enantioselective hydrogenation of methyl-2-acetamidoacrylate with [RhL COD ]+ SHB catalyst at 298 K in ethanol.

Furanoside diphosphinite ligands 10 and 11 (Fig. 11) were applied in the Ir-catalyzed asymmetric hydrogenation of several dehydroaminoacid derivatives [25]. The best enantioselectivities (ee s up to 78%) were obtained in the reduction of methyl W-acetamidoacrylate with ligand 10. These results using the lr/10-11 catalysts precursor show that enantiomeric excesses are strongly dependent on the absolute configuration of the C-3 stereocenter of the carbohydrate backbone. The best enantioselectivity were therefore obtained with ligand 10 with an... 

In asymmetric hydrogenation of olefins, the overwhelming majority of the papers and patents deal with hydrogenation of enamides or other appropriately substituted prochiral olefins. The reason is very simple hydrogenation of olefins with no coordination ability other than provided by the C=C double bond, usually gives racemic products. This is a common observation both in non-aqueous and aqueous systems. The most frequently used substrates are shown in Scheme 3.6. These are the same compounds which are used for similar studies in organic solvents salts and esters of Z-a-acetamido-cinnamic, a-acetamidoacrylic and itaconic (methylenesuccinic) acids, and related prochiral substrates. The free acids and the methyl esters usually show appreciable solubility in water only at higher temperatures, while in most cases the alkali metal salts are well soluble. 

As enantioselective hydrogenations of prochiral substrates are undoubtedly the most common applications of chiral diphosphine ligands, a broad screening of our ligands was undertaken with some commonly used standard substrates. As substrates for the hydrogenation of C=C double bonds dimethyl itaconate (DlMl), methyl 2-acetamidoacrylate (MAA), methyl acetamidocinnamate (MAC) as an a-amino acid precursor, and ethyl (Z)-3-acetamidobutenoate ( 3-ENAM1DE) as a p-amino acid precursor were chosen (see Eig. 1.4.5). 

Several diphosphine ligands have been applied and the corresponding complexes have been tested for the immobilization (Fig. 2.1.6.3). The activity of different free and immobilized complexes in the enantioselective hydrogenation of dimethyl itaconate and methyl a-acetamidoacrylate was investigated. In blank reactions over pure mesoporous materials no reaction took place. When rhodium supported on carriers was used as catalyst, no enantiomeric excess was observed. 

For the hydrogenation of methyl a-acetamidoacrylate, the best results were again obtained with the (S,S)-Me-Duphos ligand. The complex showed complete conversion with 94% or 93% ee in homogeneous and heterogeneous media, respectively. When methyl a-acetamidoacrylate was used as a probe molecule for enantioselective hydrogenations over RhDuphos immobilized on M41S-type materials, 99% ee and a TON of 2000 were obtained over RhDuphos/Al-MCM-41 (S/Rh = 2000 1), whereas RhDuphos/Al-MCM-48 resulted in 97% ee and a TON of 2900 (S/Rh = 3000 1). 

The new ligands were evaluated in the Rh-catalyzed asymmetric hydrogenation of benchmark substrates methyl a-N-acetamidoacrylate (7), methyl a-(2)-N-acetamidocinnamate (8) and dimethyl itaconate (9) (Table 2.3). For all three substrates, catalyst performance was superior in CH2CI2. Differences of up to 83% ee compared to otherwise identical reactions conducted in MeOH could be noted, giving... 

Figure 8.12 U rea functionalized phosphate ligands for asymmetric hydrogenation of dimethyl itaconate (DMI), N-(3,4-dihydronaphthalen-2-yl)acetamide (DNA) and methyl 2-acetamidoacrylate (MAA).

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