Directed openings of 2,3-epoxy alcohols via reactions with isocyanates: synthesis of (+)-erythro-dihydrosphingosine

Roush, William; Adam, Michael A.

doi:10.1021/jo00220a015

Cited by 145 publications

(46 citation statements)

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“…Ammazzalorso et al [77] described preliminary structural modification of both initial reactants (epoxide and amine) in the synthesis of compound 29 (Scheme 15). These data are consistent with the results of other studies [72,78,79] on the synthesis of oxazolidin-2-ones 30 via reactions of aryl glycidyl ethers 31 and their analogs (Scheme 16). Epoxide 32 was used as starting compound to obtain potent (+)-L-733 060 neurokinin-1 receptor antagonist [80] (Scheme 17).…”

Section: Heterocyclization Of Epoxy Carbamatessupporting

confidence: 92%

“…The structure of heterocyclization products depends on the catalyst nature [72] Transformation of epoxy substrate into 1,3-oxazolidin-2-one requires that a group capable of rear intramolecular nucleophilic attack on electrophilic carbon atoms be present in the neighborhood to the oxirane ring. Aryloxiranes were reported to react with tertbutyl alkylcarbamates in the presence of a catalytic amount of potassium tert-butoxide to give 5-aryl-1,3-oxazolidin-2-ones 28 (Ar = Ph, 4-ClC 6 H 4 , 1-naphthyl, R = Bu, Hex, All, Bzl) [76] (Scheme 14).…”

Section: Heterocyclization Of Epoxy Carbamatesmentioning

confidence: 99%

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Five-membered oxaza heterocyclic compounds on the basis of epoxides and aziridines

2011

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Section: Heterocyclization Of Epoxy Carbamatessupporting

confidence: 92%

Section: Heterocyclization Of Epoxy Carbamatesmentioning

confidence: 99%

Five-membered oxaza heterocyclic compounds on the basis of epoxides and aziridines

2011

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“…[8] We reasoned that its hydroboration at the less hindered face of the terminal double bond would generate an unsymmetrical Z allylborane, which could be stereoselectively added to an aldehyde to generate the amino diols 6 that are protected at the quaternary center. [11] One-dimensional nuclear Overhauser enhancement experiments on 7 a enabled us to determine its relative configuration, which is shown in Scheme 3. [9,10] Interestingly, in the presence of a catalytic amount of DBU in CH 2 Cl 2 at room temperature, 6 a exhibited an equilibrium largely shifted towards its regioisomer 7 a, which was readily isolated in 85 % yield after column chromatography.…”

Section: In Memory Of Xavier Solansmentioning

confidence: 99%

Stereocontrolled Synthesis of Highly Functionalized Quaternary Carbon Centers: A Route to α‐Substituted Serines

et al. 2009

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The development of efficient stereoselective methods for the formation of CÀC bonds involving the construction of a quaternary carbon centre has attracted much attention. [1] These processes become more useful and challenging if additional neighboring stereogenic centers and polar functionalities are also formed stereoselectively. In this context, our research group is interested in developing methodologies for the construction of substructures bearing a densely functionalized quaternary center; like those found in asubstituted threonines 1 or serines 2, [2] as well as in more complex natural products of biological relevance such as the proteasome inhibitor lactacystin (3) [3] or the immunosuppressant myriocin (4). [4] We envisaged that quaternary amino acids such as 1 or 4 could arise from a homoallylic alcohol I which, in turn, could be obtained by the stereoselective addition of a substituted allylic organoborane II to an aldehyde (Scheme 1). Despite the extensive use of various terpene-and tartrate-based chiral allylborane as well as crotylborane reagents, [5] the required stereoselective addition of g,g-disubstituted allylboranes to aldehydes has been much less explored. [6] Examples of the stereoselective creation of quaternary carbon centers by addition of g-heteroatom allylboranes such as II are still scarce. [7] The limited use of such g,g-disubstituted allylboranes in organic synthesis is probably due to the difficulty involved in their stereoselective preparation. To overcome this drawback, we anticipated that II could be prepared in a straightforward manner by hydroboration of allene III.Our initial proposal for III was allene 5, since it can be easily obtained in two steps from but-2-yn-1,4-diol (Scheme 2). [8] We reasoned that its hydroboration at the less hindered face of the terminal double bond would generate an unsymmetrical Z allylborane, which could be stereoselectively added to an aldehyde to generate the amino diols 6 that are protected at the quaternary center. To our delight, we found that the treatment of 5 with dicyclohexylborane in Scheme 1. Retrosynthetic analysis of I.Scheme 2. Synthesis of 6 a by addition of 5 to isobutyraldehyde. Cy = cyclohexyl, Ts = 4-toluenesulfonyl.

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“…1,2 Some of the synthetic utility of chiral epoxides are as follows; conversion of chiral epoxides into hydroxy compounds through ring opening reactions, 3 carbon-carbon bond formation and formylation, 4 ringopening reactions of chiral epoxides with isocyanates to yield chiral amino alcohols, 5 Payne rearrangement of converting chiral epoxy alcohols to chiral diols, 6 meso epoxide ring opening with dithiols to form chiral disulfides, 7 rearrangement of chiral epoxides, 8 utilization of terminal epoxides in the synthesis of γ-lactones, 9 in the synthesis of 2,5-disubstituted piperdine alkaloids, 10 and in the synthesis of norlignan currculigine, which is an in vivo anti-arrhythmic active compound. 1,2 Some of the synthetic utility of chiral epoxides are as follows; conversion of chiral epoxides into hydroxy compounds through ring opening reactions, 3 carbon-carbon bond formation and formylation, 4 ringopening reactions of chiral epoxides with isocyanates to yield chiral amino alcohols, 5 Payne rearrangement of converting chiral epoxy alcohols to chiral diols, 6 meso epoxide ring opening with dithiols to form chiral disulfides, 7 rearrangement of chiral epoxides, 8 utilization of terminal epoxides in the synthesis of γ-lactones, 9 in the synthesis of 2,5-disubstituted piperdine alkaloids, 10 and in the synthesis of norlignan currculigine, which is an in vivo anti-arrhythmic active compound.…”

Section: Introductionmentioning

confidence: 99%

Chiral porphyrin imine manganese complex as catalyst for asymmetric epoxidation of styrene derivatives

Ananthi

Enoch

2019

Chirality

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New chiral porphyrin imine was synthesized from (S)-3-benzyl-2-methyl-4phenylbutanal according to dipyrromethane method using trifluoroacetic acid, BF 3 etherate, and p-chloranil. Manganese complex of this chiral porphyrin imine ligand was used as catalyst in the asymmetric epoxidation of styrene derivatives possessing different substituents. Styrene derivatives possessing electron withdrawing groups gave the corresponding chiral epoxides in high yield up to 98% and ee up to 99%. The mechanism for the catalytic asymmetric epoxidation was also discussed based on transfer of oxygen.KEYWORDS asymmetric epoxidation, asymmetric synthesis, chiral epoxides, chiral porphyrin manganese complexes, epoxidation of styrene

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Directed openings of 2,3-epoxy alcohols via reactions with isocyanates: synthesis of (+)-erythro-dihydrosphingosine

Cited by 145 publications

References 0 publications

Five-membered oxaza heterocyclic compounds on the basis of epoxides and aziridines

Five-membered oxaza heterocyclic compounds on the basis of epoxides and aziridines

Stereocontrolled Synthesis of Highly Functionalized Quaternary Carbon Centers: A Route to α‐Substituted Serines

Chiral porphyrin imine manganese complex as catalyst for asymmetric epoxidation of styrene derivatives

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