Investigations on the Iron‐Catalyzed Asymmetric Sulfide Oxidation

Legros, Julien; Bolm, Carsten

doi:10.1002/chem.200400857

Cited by 228 publications

(96 citation statements)

References 76 publications

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“…[23] Thus, several methods have been developed for the asymmetric oxidation of prochiral sulfides with chiral metal complex catalysts, such as titanium-, [2,[24][25][26][27][28][29][30][31][32][33][34][35][36] manganese-, [37][38][39] vanadium-, [40][41][42][43][44][45][46] iron-, [47][48][49] and aluminium-based [50] systems. Despite the above-mentioned practical importance of the asymmetric sulfoxidation reactions, the basic mechanistic features of the titanium tartrate-based process used for the synthesis of esomeprazole ( Figure 1) remained mainly unexplored.…”

Section: Full Papersmentioning

confidence: 99%

Mechanism of the Asymmetric Sulfoxidation in the Esomeprazole Process: Effects of the Imidazole Backbone for the Enantioselection

2009

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Abstract:The asymmetric sulfoxidation reaction of imidazole-based prochiral sulfides was studied to explore the mechanistic details of the highly efficient esomeprazole process, which is one of the few industrial scale catalytic asymmetric procedures. The synthetic studies revealed that the smallest subunit governing the selectivity in the esomeprazole process is an imidazole ring. Thus, by using the esomeprazole procedure methyl imidazole sulfide could be oxidized as efficiently as its several functionalized derivatives, including pyrmetazol. However, alkylation of the imidazole nitrogen led to a major drop of the enantioselectivity. Our atmospheric pressure chemical ionization-mass spectrometry (APCI/MS) studies indicate that addition of small amounts of water to the reaction mixture facilitates the formation of mononuclear titanium species, which are the active catalytic intermediates of the selective oxidation reaction. One of the most important features of the esomeprazole procedure is that amine additives increase the enantioselectivity of the oxidation process. The NMR studies of the presumed reaction intermediates show that under catalytic conditions the amines are able to coordinate to titanium and dissociate the coordinated imidazole substrate. The density functional theory (DFT) modelling studies provided new insights in the mechanism of the asymmetric induction. It was found that the oxidation requires a lower activation energy if the imidazole sulfide precursor does not coordinate to titanium. Two possible reaction paths were explored for this out of sphere oxidation mechanism. The most important interaction governing the enantioselection is hydrogen bonding between the N À H of the imidazole ring and the chiral tartrate ligand on titanium. Furthermore, the oxidation reaction imposes an important structural constraint to the TS structure involving a linear arrangement of the peroxide oxygens and the sulfur atom. This constraint and the N coordination of imidazole leads to a very strained structure for the inner sphere mechanism of the oxidation, which leads to a much higher activation barrier than the corresponding out of sphere process, and therefore it is unlikely.

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Section: Full Papersmentioning

confidence: 99%

Mechanism of the Asymmetric Sulfoxidation in the Esomeprazole Process: Effects of the Imidazole Backbone for the Enantioselection

2009

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“…In particular,acleana nd efficient late stage C À Hf unctionalization woulda void the unproductive manipulations necessary for interconverting, protecting andd eprotecting functional groups throughout the synthetic sequence.A lsoo ther oxidative processes,s uch as olefin epoxidation and sulfide oxidation, have received considerable attention for the relevance of epoxides and sulfoxides in synthetic organic procedures. [6][7][8][9][10] Although several methodsf or the preparation of such functionalities have alreadyb een developed, the quest for more general catalytic systems which use more abundant and sustainable reagents is still ongoing.…”

Section: Introductionmentioning

confidence: 99%

Non‐Heme Imine‐Based Iron Complexes as Catalysts for Oxidative Processes

2016

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Non-heme iron complexes are emerging as powerful and versatile catalysts in several oxidative transformations. Them ost investigated iron complex structures are based on aminopyridine ligands,b ut an umber of imine-based ligands have been also tested. In this review ac ollection of recent results obtained in oxidation catalysisw ith non-heme iminebased iron complexes is presented. Theirc atalytic performances in C À H, C=Ca nd À S À oxidation are spread over aw ide range of efficiency,g oing from very low to quite high.S uch performances are discussed, whenever possible,i nl ight of the operating reactionm echanismsa nd of catalyst stability.I n order to facilitate the discussion,a ni nitial survey of the most useful mechanistic tools widelya pplied to distinguish am etal-based oxidation from ar adicalchain process is also reported. Imine-basedc atalysts are divided into twoc lasses:( i) salen-Fec omplexes, and (ii)i mine-Fe complexes.I ns ome cases clues for free-radical oxidation mechanisms have been reported whilei no ther casese vidence for metal-based mechanisms has been collected. Thep referredm echanisticp athway is shown to be af unction of catalyst structure and features

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“…The enantioselectivity obtained with these iron catalysts did not surpass 55% ee. However, very good selectivities up to 96% ee were reported recently by Bolm et al combining either Fe(acac) 3 or vanadium salts with Schiff base ligands in the presence of H 2 O 2 [44].…”

Section: Sulfide Oxidationmentioning

confidence: 81%

“…Jacobsen et al have found that the presence of an excess of acetic acid (ratio of catalyst:additive = 1:10) could improve the efficiency of alkene epoxidation with H 2 O 2 and an iron catalyst [4a]. Recently, Bolm et al reported enhanced reactivities and selectivities in sulfide oxidation using benzoic acids as additives in sub-stoichiometric amounts (ratio catalyst:additive = 1:0.5) [44]. Following these findings we chose to test two additives, acetic acid and p-anisic acid, for an investigation of their effect on the oxidation of phenyl methyl sulfide (entries 9 and 10).…”

Section: Sulfide Oxidationmentioning

confidence: 99%

Mononuclear diastereopure non-heme Fe(II) complexes of pentadentate ligands with pyrrolidinyl moieties: Structural studies, and alkene and sulfide oxidation

Gosiewska

Lutz

Spek

et al. 2007

Inorganica Chimica Acta

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Mononuclear iron(II) complexes of enantiopure Py(ProOH) 2 (2) and Py(ProPh 2 OH) 2 (3) ligands have been prepared with FeCl 2 and Fe(OTf) 2 AE 2MeCN. Both ligands coordinate to the metal in a pentadentate fashion. Next to the meridional N,N 0 ,N-coordination of the ligand, additional coordination of the oxygen atoms of both hydroxyl groups to the metal is found in complexes 4-7. Complex [FeCl(2)](Cl) (4) shows an octahedral geometry as determined by X-ray diffraction and is formed as a single diastereoisomer. The solution structures of complexes 4-7 were characterized by means of UV-Vis, IR, ESI-MS, conductivity and CD measurements. The catalytic potential of these complexes in the oxidation of alkenes and sulfides in the presence of H 2 O 2 is presented.

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Investigations on the Iron‐Catalyzed Asymmetric Sulfide Oxidation

Cited by 228 publications

References 76 publications

Mechanism of the Asymmetric Sulfoxidation in the Esomeprazole Process: Effects of the Imidazole Backbone for the Enantioselection

Mechanism of the Asymmetric Sulfoxidation in the Esomeprazole Process: Effects of the Imidazole Backbone for the Enantioselection

Non‐Heme Imine‐Based Iron Complexes as Catalysts for Oxidative Processes

Mononuclear diastereopure non-heme Fe(II) complexes of pentadentate ligands with pyrrolidinyl moieties: Structural studies, and alkene and sulfide oxidation

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