Stereospecific and highly stereoselective cyclopropanation reactions promoted by samarium

Concellón, José M.; Rodríguez‐Solla, Humberto; Concellón, Carmen; Amo, Vicente del

doi:10.1039/b915662c

Cited by 77 publications

(33 citation statements)

References 63 publications

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“…This H-bond interaction likely inhibits coordination of HMPA to Sm(II). With this mechanistic insight one can rationalize the unsuccessful reduction of 4butylbenzamide (5) with Sm(II)-HMPA system (Table 3). It is interesting that the differences between TFE and isopropanol in activating TMSCl through H-bond interactions is reflected only in the case of HMPA.…”

Section: Role Of Proton Donors and H-bonding In Smi 2 Catalysismentioning

confidence: 99%

“…Samarium diiodide (SmI 2 ) and related Sm(II)-based reductants are important reagents in the arsenal of synthetic chemists. [1][2][3][4][5][6][7][8][9] First introduced by Kagan and coworkers, SmI 2 is a versatile single electron reductant capable of reducing a range of functional groups under mild reaction conditions. 10 The majority of SmI 2 -based reactions are carried out in THF since the reagent is stable in this medium and is soluble up to 0.1 M. Initially considered a "specialized" reagent, a range of studies have shown that SmI 2 is capable of efficiently reducing a wide range of functional groups.…”

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confidence: 99%

“…10 The majority of SmI 2 -based reactions are carried out in THF since the reagent is stable in this medium and is soluble up to 0.1 M. Initially considered a "specialized" reagent, a range of studies have shown that SmI 2 is capable of efficiently reducing a wide range of functional groups. [1][2][3][4][5][6][7][8][9] The rate by which SmI 2 reduces different functional groups varies significantly. 11,12 As a result, SmI 2 can be used to selectively reduce a particular functional group in a multifunctional substrate for follow-up bondforming reactions and is exceptionally effective in reductive couplings, [13][14][15][16][17][18][19][20][21][22] and cascade reactions.…”

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confidence: 99%

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Mechanistic Study and Development of Catalytic Reactions of Sm(II)

Maity

Flowers

2019

J. Am. Chem. Soc.

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Despite the broad utility and application of SmI 2 in synthesis, the reagent is used in stoichiometric amounts and has a high molecular weight, resulting in a large amount of material being used for reactions requiring one or more equivalents of electrons. We report mechanistic studies on catalytic reactions of Sm(II) employing a terminal magnesium reductant and trimethyl silyl chloride in concert with a non-coordinating proton donor source. Reactions using this approach permitted reductions with as little as 1 mol% Sm. The mechanistic approach enabled catalysis employing HMPA as a ligand, facilitating the development of catalytic Sm(II) 5-exo-trig ketyl olefin cyclization reactions. File list (3) download file view on ChemRxiv Sm(II) Catalysis (RAF).pdf (746.24 KiB) download file view on ChemRxiv SI_Sm(II) catalysis.pdf (3.10 MiB) download file view on ChemRxiv Sm(II) Catalysis (RAF).doc (574.50 KiB)

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Section: Role Of Proton Donors and H-bonding In Smi 2 Catalysismentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Mechanistic Study and Development of Catalytic Reactions of Sm(II)

Maity

Flowers

2019

J. Am. Chem. Soc.

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“…Among the spirocyclic oxindoles, 3spirocyclopropane-2-oxindoles represent an important class that has shown remarkable biological activities and emerged recently as potent drug candidates. [14][15][16][17][18][19][20] Among the various transition-metal catalysts used, rhodium(II) catalysts bearing carboxylate ligands are one of the most extensively studied and employed catalysts in cyclopropanation reactions. [8][9][10][11][12] Since the pioneering work of Nozaki and Noyori, 13 the transition metal-catalyzed asymmetric cyclopropanation between diazo compounds and alkenes has emerged as a powerful strategy for the synthesis of cyclopropane derivatives.…”

Section: Introductionmentioning

confidence: 99%

Mechanism and stereoselectivity of the Rh(ii)-catalyzed cyclopropanation of diazooxindole: a density functional theory study

2015

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The mechanism and origin of stereoselectivity of rhodium(II)-catalyzed cyclopropanation reactions with diazooxindole and styrene has been studied using density functional theory calculations. The catalyzed reactions by achiral Rh 2 (OAc) 4 and chiral Rh 2 (S-PTTL) 4 as well as the uncatalyzed model were comparatively studied. The computational results indicate that the cyclopropanation step in both Rh 2 (OAc) 4 and Rh 2 (S-PTTL) 4 models is a single concerted but asynchronous process. The nitrogen extrusion step is found to be the rate-limiting step of the catalytic cycle, whereas the cyclopropanation step is the stereoselectivity-determining step. The diastereomeric ratios (dr) and the enantiomeric excess (ee) values are successfully predicted, which are in good agreement with the experimental values. The high trans-diastereoselectivity might be governed by the p-p interactions between the syn indole ring in carbenoid ligand and the phenyl group in styrene, whereas the good enantioselectivity can be ascribed to the steric interaction between the phenyl ring in styrene and the phthalimido group in the catalyst as well as the aromatic interactions (p-p and CH-p) in the transition states. Additionally, the methodological study using different functionals demonstrated the importance of considering the dispersion interactions in the current reaction systems. This theoretical study will help in understanding the mechanism of the asymmetric cyclopropanations of olefins through carbene-transfer reactions. † Electronic supplementary information (ESI) available: Comparison of different DFT methods (Table S1), calculated relative free energies with and without BSSE correction (Table S2), NBO analysis of TS11a and TS11b (Table S3), natural charge analysis (Tables S4 and S5), energy prole for the uncatalyzed cyclopropanation in Re-face pathway (Fig. S1), comparison between the DFT and X-ray structure of Rh 2 (OAc) 4 (Fig. S2), and other gures and tables, and xyz le giving the Cartesian coordinates for all structures. See Scheme 1 Rh 2 (S-PTTL) 4 catalyzed cyclopropanation of styrene and diazooxindole.Scheme 2 Proposed catalytic cycle for the asymmetric cyclopropanation.57782 | RSC Adv., 2015, 5, 57781-57791This journal is

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“…For this purpose,w ee nvisioned the reductive coupling of 4-oxo-4H-1-benzopyrans,t hrough their 2-positions,b ym eans of samarium diiodideasasingle-electron transfer (SET) reagent.Samarium diiodide [3] is unique when compared with other SET reagents given its well-known high versatility in providing different radicals in organic synthesis.I nfact, the use of samarium diiodide has been widely covered in the literature in different reductivep rocesses, [4] including homo-or heterocoupling reactions. [5] Our group has accumulated aw idee xperience in the use of samarium diiodidei nb oth ionic and radicalr eactions,i ncluding its application in 1,2-elimination processes, [6] cyclopropanation reactions [7] reduction of multiple bonds [8] and the stereoselective synthesis of compounds of high value derived from naturalp roducts such as carbohydrates [9] or aaminoa cids. [10] Encouraged by the pharmacological interest in biflavonoids, [1f] hereinw er eport the use of different easily availablef lavanones as startingm aterials for the stereoselective synthesiso fb iflavonoids through as amarium diiodidepromoted and temperature-depending stereodivergent radical-coupling reaction.Initial reactions were performed on commercially available flavone 1a at room temperature.T hus, treatment of flavone 1a (1.0 equiv) dissolved in THF and the use of methanol (1.25 equiv) as the co-solvent with a0 .…”

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confidence: 99%

Temperature‐Controlled Stereodivergent Synthesis of 2,2′‐Biflavanones Promoted by Samarium Diiodide

Soto

Soengas

Silva

et al. 2019

Chemistry A European J

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In this work,t he first exampleo faradical stereodivergent reactiond irected towardst he stereoselective synthesis of both (R*,R*)-and (R*,S*)-2,2'-biflavanones promoted by samarium diiodide is reported. Control experiments showedt hat the selectivity of this reaction was exclusively controlled by the temperature. It was possible to generate av ariety of 2,2'-biflavanones bearing different substitution patterns at the aromatic ring in good-toquantitative yields, being both stereoisomerso ft he desired compounds obtained with total or high control of selectivity.Amechanismt hat explains both the generation of the corresponding 2,2'-biflavanones and the selectivity is also discussed. The structure ands tereochemistry determination of each isomer was unequivocally elucidatedb y single-crystal X-ray diffraction experiments.Flavonoid-derivedc ompounds are gainingi ncreasinga ttention owing to their interesting biological activity,i ncluding their anticarcinogenic, antifungal, antiviral,a ntibacterial,a ntimicrobial, antioxidant, anxiolytic and anti-inflammatory properties. For this reason, several methodsd irected towards the stereoselective synthesis of flavonoid-related compounds, includingb iflavonoids, have been recently published. [1] Despite the large number of biflavonoids that are suggestedt oe xist in nature, only ac ouple of dozen naturalb iflavonoidsh ave been explored for biological activity studies. In this respect, it has also been shown that, in general terms, the dimerization of flavonoid units is av aluable protocol for the synthesis of biflavonoids, being the bioactivity of these compounds remarkably increased when compared with that shown by the flavonoid monomer. [2] For all these reasons, the developmento fn ew stereoselectives ynthetic proceduresa imed the synthesis of bifla-vonoidsa re of great interesti no rganic synthesis. Moreover,a s part of an ongoing project on the synthesis and biological evaluation of phenolic compounds, we became also interested in the efficient preparation of 2,2'-biflavonoids. For this purpose,w ee nvisioned the reductive coupling of 4-oxo-4H-1-benzopyrans,t hrough their 2-positions,b ym eans of samarium diiodideasasingle-electron transfer (SET) reagent.Samarium diiodide [3] is unique when compared with other SET reagents given its well-known high versatility in providing different radicals in organic synthesis.I nfact, the use of samarium diiodide has been widely covered in the literature in different reductivep rocesses, [4] including homo-or heterocoupling reactions. [5] Our group has accumulated aw idee xperience in the use of samarium diiodidei nb oth ionic and radicalr eactions,i ncluding its application in 1,2-elimination processes, [6] cyclopropanation reactions [7] reduction of multiple bonds [8] and the stereoselective synthesis of compounds of high value derived from naturalp roducts such as carbohydrates [9] or aaminoa cids. [10] Encouraged by the pharmacological interest in biflavonoids, [1f] hereinw er eport the use of different easily availablef l...

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Stereospecific and highly stereoselective cyclopropanation reactions promoted by samarium

Cited by 77 publications

References 63 publications

Mechanistic Study and Development of Catalytic Reactions of Sm(II)

Mechanistic Study and Development of Catalytic Reactions of Sm(II)

Mechanism and stereoselectivity of the Rh(ii)-catalyzed cyclopropanation of diazooxindole: a density functional theory study

Temperature‐Controlled Stereodivergent Synthesis of 2,2′‐Biflavanones Promoted by Samarium Diiodide

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