Enantioselective hydrogenation of levulinic acid esters in the presence of the RuII-BINAP-HCl catalytic system

Starodubtseva, E. V.; Turova, O. V.; Vinogradov, M. G.; Gorshkova, L. S.; Ferapontov, V. A.

doi:10.1007/s11172-006-0125-2

Cited by 54 publications

(29 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Catalytic hydrogenation of oxo ester 1 and analysis of the reaction products were carried out as described in the pre ceding paper. 1 Here the catalyst for the asymmetric hydrogena tion and deuteration of oxo ester 1 was prepared in situ without isolating the intermediate complex [((S) BINAP)RuCl 2 ].…”

Section: Methodsmentioning

confidence: 99%

The role of protic solvent in asymmetric hydrogenation of methyl levulinate in the presence of a ruthenium-containing catalyst

et al. 2007

Self Cite

View full text Add to dashboard Cite

A comparative study of asymmetric hydrogenation and deuteration of methyl levulinate catalyzed by the Ru II -(S) BINAP-HCl system (BINAP is 2,2´ bis(diphenylphosphino) 1,1´ binaphthyl) in MeOH and MeOD was carried out. The results obtained suggest an impor tant role of the protic solvent in the formation of catalytically active ruthenium complexes.Key words: asymmetric catalytic hydrogenation, deuteration, hydrogen heterolysis, H/D ex change, ruthenium complexes, 2,2´ bis(diphenylphosphino) 1,1´ binaphthyl (BINAP), levulinic acid ester, chiral γ valerolactone.Earlier, 1 we have investigated asymmetric hydroge nation of levulinic acid esters catalyzed by the Ru II -(S) BINAP-HCl system (BINAP is 2,2´ bis(di phenylphosphino) 1,1´ binaphthyl). The resulting (S) γ hydroxy esters underwent in situ transformation into (S) γ valerolactone with up to 99% ee.Here we studied the role of solvent in the aforemen tioned reactions with methyl levulinate (1) as a model substrate (Scheme 1). Scheme 1 R = H (a), D (b) ExperimentalCommercial (S) BINAP, (COD)Ru(H 2 C(Me)C=CH 2 ) 2 (COD is cycloocta 1,5 diene) (Acros), and D 2 and MeOD (pi lot plant Prikladnaya Khimiya, St. Petersburg) were used. Methyl levulinate was prepared from levulinic acid (Acros) ac cording to a standard procedure. 2 Gaseous H 2 and D 2 were purified by passing through columns with a nickel-chromium catalyst and molecular sieves. All solvents were dehydrated be fore use. Catalytic hydrogenation of oxo ester 1 and analysis of the reaction products were carried out as described in the pre ceding paper. 1 Here the catalyst for the asymmetric hydrogena tion and deuteration of oxo ester 1 was prepared in situ without isolating the intermediate complex [((S) BINAP)RuCl 2 ].

show abstract

Section: Methodsmentioning

confidence: 99%

The role of protic solvent in asymmetric hydrogenation of methyl levulinate in the presence of a ruthenium-containing catalyst

et al. 2007

Self Cite

View full text Add to dashboard Cite

show abstract

“…[28][29][30][31] In early pioneering studies Osakada et al, [32] showed the activation of C-O bonds of five membered cyclic anhydride, aldehydic and keto acids using two different ruthenium ( [10] demonstrated the use of an in situ generated Ru catalyst using a combination of Ru(acac) 3 and the strongly electron donating phosphine P n Bu 3 in the presence of NH 4 PF 6 for LA hydrogenation to GVL ( [33] reported the effect of the mondentate and chelating phosphines: trioctylphosphine (P n Oct 3 ), 1,4-diphenylphosphinobutane (DPPB) and triphos ( fig. 2) and various acidic additives for the transformation of LA.…”

Section: Hydrogenation Of Levulinic Acid (La) To γ-Valerolactone (Gvl)mentioning

confidence: 99%

“…[35,36,53,54] Ru and Ir phosphine complexes have provent ob ee ffective catalysts for CÀOb ond activation in carboxylic acids derivatives. [30][31][32][33] In early pioneering studies, Osakada et al [34] [10] demonstrated the use of an in situ-generated Ru catalyst using ac ombination of [Ru(acac) 3 ]( acac = acetylacetonate) and the strongly electron-donating phosphine PnBu 3 in the presence of NH 4 PF 6 for LA hydrogenation to GVL ( Table 1, entry 3). The reaction demonstrated quantitative conversion of LA to GVL.…”

Section: Hydrogenation Of Levulinic Acid To G-valerolactonementioning

confidence: 99%

“…In recent studies by Starodubtseva et al [30,50] the conversion of LA, EL ando ther levuinate esters to enantiopure lactones was investigated using Ru-BINAP catalysts prepared in situ and activated with HCl. LA could be converted to (S)-GVL in moderate yields of 66 %a nd with 98.5 % ee at 60 8Ca nd 60 bar H 2 in EtOH using ac atalyst system generated in situ from [Ru(Me-allyl) 2 (COD)] (COD = 1,5-cyclooctadiene);M e = methyl, (S)-BINAP and HCl.…”

Section: Hydrogenation Of Levulinic Acid To G-valerolactonementioning

confidence: 99%

See 1 more Smart Citation

Homogeneous Catalyzed Reactions of Levulinic Acid: To γ‐Valerolactone and Beyond

et al. 2016

View full text Add to dashboard Cite

Platform chemicals derived from lignocellulousic plant biomass are viewed as a sustainable replacement for crude oil based feed-stocks. Levulinic acid (LA) is one such biomass derived chemical that has been widely studied for further catalytic transformation to γ-valerolactone (GVL), an important 'green' fuel additive, solvent and fine chemical intermediate. Although the transformation of LA to GVL can be achieved using heterogeneous catalysis, homogeneous catalytic systems that operate under milder reactions, give high seletivities and can be recycled continue to attract much attention. A range of new homogeneous catalysts have now been demonstrated to efficiently convert LA to GVL, and to transform LA directly to other value added chemicals such as 1,4-pentanediol (1,4-PDO) and 2-methyltetrahydrofuran (2-MTHF). This mini review covers recent advances in the area of homogeneous catalysis for the conversion of levulinic acid and levulinic ester derivatives to GVL and chemicals beyond GVL.

show abstract

“…12 Earlier, we have studied asymmetric catalytic hydro genation of prochiral substrates containing a keto group. [13][14][15][16] In the present work, we made an attempt to use similar approach to the synthesis of chiral δ amino acids starting from available δ keto acids. 5 Oxo 5 phenylpentanoic acid (1) has been chosen as the starting compound (Scheme 1), which gave rise to two model sub strates, viz., ω enamides 4 and 9.…”

mentioning

confidence: 99%

Stereocontrolled approach to δ-amino acids by asymmetric hydrogenation of 5-acetylaminopent-4-enoic acid derivatives

et al. 2010

Self Cite

View full text Add to dashboard Cite

Asymmetric hydrogenation of the C=C bond in 5 acetylamino 5 phenylpent 4 enoic acid methyl ester or N,N dimethylamide catalyzed by rhodium complexes with chiral bisphosphine ligands (1 mol.% of the catalyst, 20 atm. of H 2 , MeOH, 50 °C) gives the corresponding saturat ed derivatives with enantioselectivity up to 40% ee.Key words: asymmetric hydrogenation, rhodium complexes, bisphosphine chiral ligands, nonracemic 5 acetylamino 5 phenylpentanoic acid.Amino acids and their derivatives are important natu ral objects and are widely used in the synthesis of various pharmacologically active compounds and ligands for asymmetric catalysis. 1-3 Widespread methods for the syn thesis of chiral amino acids, including asymmetric hydro genation of unsaturated precursors intensively developed in the last years, 4-6 in fact are mainly used for obtaining acids with the amino group in α or β position. Amino acids with more remote amino group, viz., chiral γ and δ amino acids, are significantly less available. It is note worthy that the absolute configuration of one of the sim plest chiral δ amino acids, i.e., levorotating δ aminoca prylic acid, was unambiguously established 7 only in 1965. As a rule, laborious multi step schemes involving stoichi ometric amounts of inconvenient in handling organome tallic reagents and expensive chiral inductors are required for the synthesis of chiral γ and δ amino acids. 8-11 There are also known separate examples of solving the same prob lem by asymmetric hydrogenation of the C=N bond in imino carboxylic acid derivatives with the use of complex catalytic systems. 12 Earlier, we have studied asymmetric catalytic hydro genation of prochiral substrates containing a keto group. 13-16 In the present work, we made an attempt to use similar approach to the synthesis of chiral δ amino acids starting from available δ keto acids. 5 Oxo 5 phenylpentanoic acid (1) has been chosen as the starting compound (Scheme 1), which gave rise to two model sub strates, viz., ω enamides 4 and 9.Reductive N acetylation of the corresponding keto oximes 3 and 8 with finely dispersed iron metal in the presence of Ac 2 O and AcOH is the key step in the synthe sis of both enamides. Earlier, only simple keto oximes containing no other functional groups have been used in this reaction 17-21 with just rare exceptions. 19,21 In the present work, reductive N acetylation, as far as we known, was for the first time accomplished for oximes with an ester and amide functional groups, and the earlier unde scribed enamide 4 was isolated in the crystalline form as an individual E isomer. Its two dimensional 1 H NMR spectrum (500 MHz, the NOESY procedure) contains an intensive cross signal, corresponding to the spatial inter action of the phenyl protons (δ 7.3) with the protons of the methylene group (a broad singlet at δ 2.35). At the same time, the spectrum contains no cross signal responsible for the spatial interaction of the phenyl group with the olefin proton (δ 6.3). Unlike enamide 4, enamide 9 was not isolated in the isomerically ...

show abstract

Enantioselective hydrogenation of levulinic acid esters in the presence of the RuII-BINAP-HCl catalytic system

Cited by 54 publications

References 21 publications

The role of protic solvent in asymmetric hydrogenation of methyl levulinate in the presence of a ruthenium-containing catalyst

The role of protic solvent in asymmetric hydrogenation of methyl levulinate in the presence of a ruthenium-containing catalyst

Homogeneous Catalyzed Reactions of Levulinic Acid: To γ‐Valerolactone and Beyond

Stereocontrolled approach to δ-amino acids by asymmetric hydrogenation of 5-acetylaminopent-4-enoic acid derivatives

Contact Info

Product

Resources

About