Advances in Alkene and Alkyne Metathesis

2011 ◽  
Author(s):  
Douglass Taber
Keyword(s):  
Acetic Acid ◽  
Diels Alder ◽  
Alkyne Metathesis ◽  
Santa Barbara ◽  
Ring Closing Metathesis ◽  
Enol Ethers ◽  
Cross Metathesis ◽  
Simple Filtration ◽  
The University ◽  
Academy Of Sciences

As alkene metathesis is extended to more and more challenging substrates, improved catalysts and solvents are required. Robert H. Grubbs of Caltech developed (Organic Lett. 2008, 10, 441) the diisopropyl complex 1, that efficiently formed the trisubstituted alkene 6 by cross metathesis of 4 with 5. Hervé Clavier and Stephen P. Nolan of ICIQ, Tarragona, and Marc Mauduit of ENSC Rennes found (J. Org. Chem. 2008, 73, 4225) that after cyclization of 7 with the complex 2b, simple filtration of the reaction mixture through silica gel delivered the product 8 containing only 5.5 ppm Ru. The merit of CH2Cl2 as a solvent for alkene metathesis is that the catalysts (e.g. 1 - 3) are very stable. Claire S. Adjiman of Imperial College and Paul C. Taylor of the University of Warwick established (Chem. Commun. 2008, 2806) that although the second generation Grubbs catalyst 3 is not as stable in acetic acid, for the cyclization of 9 to 10 it is a much more active catalyst in acetic acid than in CH2Cl2 . Bruce H. Lipshutz of the University of California, Santa Barbara observed (Adv. Synth. Cat . 2008, 350, 953) that even water could serve as the reaction solvent for the challenging cyclization of 11 to 12, so long as the solubility- enhancing amphiphile PTS was included. Ernesto G. Mata of the Universidad Nacional de Rosario explored (J. Org. Chem. 2008, 73, 2024) resin isolation to optimize cross-metathesis, finding that the acrylate 13 worked particularly well. Karol Grela of the Polish Academy of Sciences, Warsaw optimized (Chem. Commun. 2008, 2468) cross-metathesis with a halogenated alkene 16. Jean-Marc Campagne of ENSC Montpellier extended (J. Am. Chem. Soc. 2008, 130, 1562) ring-closing metathesis to enynes such as 19. The product diene 20 was a reactive Diels-Alder dienophile. István E. Markó of the Université Catholique de Louvain applied (Tetrahedron Lett. 2008, 49, 1523) the known (OHL 20070122) ring-closing metathesis of enol ethers to the cyclization of the Tebbe product from 23. The ether 24 was oxidized directly to the lactone 25.

Alkene and Alkyne Metathesis: (+)-Anamarine (Sabitha), ( ± )-Pseudotabersonine (Martin), Lactimidomycin (Fürstner)

2013 ◽  
Author(s):  
Douglass F. Taber
Keyword(s):  
Indian Institute ◽  
Alkyne Metathesis ◽  
Max Planck ◽  
Ring Closing Metathesis ◽  
University Of Texas ◽  
Ru Catalyst ◽  
Cross Metathesis ◽  
University Of Zurich ◽  
Indian Institute Of Science ◽  
The University

Masato Matsugi of Meijo University showed (J. Org. Chem. 2010, 75, 7905) that over five iterations, the fluorous-tagged Ru catalyst 1b was readily recovered and reused for the cyclization of 2 to 3. Hengquan Yang of Shanxi University reported (Chem. Commun. 2010, 46, 8659) that the Hoveyda catalyst 1a encapsulated in mesoporous SBA-1 could also be reused several times. Jean-Marie Basset of KAUST Catalysis Center, Régis M. Gauvin of Université Lille, and Mostafa Taoufik of Université Lyon 1 described (Chem. Commun. 2010, 46, 8944) a W catalyst on silica that was also active for alkene metathesis. Reto Dorta of the University of Zurich, exploring several alternatives, found (J. Am. Chem. Soc. 2010, 132, 15179) that only 4c cyclized cleanly to 5. Karol Grela of the Polish Academy of Sciences showed (Synlett 2010, 2931) that 3-nitropropene (not illustrated) participated in cross-metathesis when catalyst 1c was used. Shawn K. Collins of the Université de Montré al complexed (J. Am. Chem. Soc. 2010, 132, 12790) 6 with a quinolinium salt to direct paracyclophane formation. Min Shi of the Shanghai Institute of Organic Chemistry incorporated (Org. Lett. 2010, 12, 4462) the cyclopropene 8 in cross-metathesis, to give 10. A. Srikrishna of the Indian Institute of Science (Bangalore) constructed (Synlett 2010, 3015) the cyclooctenone 12 by ring-closing metathesis. LuAnne McNulty of Butler University established (J. Org. Chem. 2010, 75, 6001) that a cyclic boronic half acid 15, prepared by ring-closing metathesis, coupled with an iodoalkene 16 to deliver the diene 17 with high geometric control. Gowravaram Sabitha of the Indian Institute of Chemical Technology, Hyderabad, en route to (+)-anamarine 21, observed (Tetrahedron Lett. 2010, 51, 5736) that the tetraacetate 18b would not participate in cross-metathesis. Fortunately, 18a , an earlier intermediate in the synthesis, worked well. Stephen F. Martin of the University of Texas prepared (Org. Lett. 2010, 12, 3622) (±)-pseudotabersonine 24 by way of a spectacular metathesis that converted 22 to 23. Ring-closing alkyne metathesis was a key step in the total synthesis of lactimidomycin 27 reported (J. Am. Chem. Soc. 2010, 132, 14064) by Alois Fürstner of the Max-Planck- Institut Mülheim.

The Kozmin Synthesis of Spirofungin A

2011 ◽  
Author(s):  
Douglass Taber
Keyword(s):  
Absolute Configuration ◽  
Journal Article ◽  
Ring System ◽  
Spatial Proximity ◽  
Silyl Ether ◽  
Secondary Alcohols ◽  
Ring Closing Metathesis ◽  
Cross Metathesis ◽  
The University ◽  
Flexible Ring

Often, 6,6-spiroketals such as Spirofungin A 3 have a strong anomeric bias. Spirofungin A does not, as the epimer favored by double anomeric stabilization suffers from destabilizing steric interactions. In his synthesis of 3, Sergey A. Kozmin of the University of Chicago took advantage (Angew. Chem. Int. Ed. 2007, 46, 8854) of the normally-destablizing spatial proximity of the two alkyl branches of 3, joining them with a siloxy linker to assure the anomeric preference of the spiroketal. The assembly of 1 showcased the power of asymmetric crotylation, and of Professor Kozmin’s linchpin cyclopropenone ketal cross metathesis. To achieve the syn relative (and absolute) configuration of 6, commercial cis-2-butene was metalated, then condensed with the Brown (+)-MeOB(Ipc)2 auxiliary. The accompanying Supporting Information, accessible via the online HTML version of the journal article, includes a succinct but detailed procedure for carrying out this homologation. For the anti relative (and absolute) configuration of 9, it is more convenient to use the tartrate 8 introduced by Roush. Driven by the release of the ring strain inherent in 10, ring opening cross metathesis with 6 proceeded to give the 1:1 adduct 11 in near quantitative yield. The derived cross-linked silyl ether 12 underwent smooth ring-closing metathesis to the dienone 1. On hydogenation, the now-flexible ring system could fold into the spiro ketal. With the primary and secondary alcohols bridged by the linking silyl ether, only one anomeric form, 2, of the spiro ketal was energetically accessible. A remaining challenge was the stereocontrolled construction of the trisubstituted alkene. To this end, the aldehyde 13 was homologated to the dibromide 14. Pd-mediated coupling of the alkenyl stannane 15 with 14 was selective for the E bromide. The residual Z bromide was then coupled with Zn(CH3)2 to give 16. These steps, and the final steps to complete the construction of spirofungin A 3 , could be carried out without exposure to equilibrating acid, so the carefully established spiro ketal confi guration was maintained.

Alkene Metathesis: Synthesis of Panaxytriol (Lee), Isofagomine (Imahori and Takahata), Elatol (Stoltz), 5-F2t -Isoprostane (Snapper), and Ottelione B (Clive)

2011 ◽  
Author(s):  
Douglass Taber
Keyword(s):  
Grignard Reagent ◽  
Conjugate Addition ◽  
Ring Closing Metathesis ◽  
University Of Illinois ◽  
Enantiomerically Pure ◽  
University Of Alberta ◽  
Cross Metathesis ◽  
Grubbs Catalysts ◽  
The University ◽  
First And Second Generation

Alkene metathesis has been used to prepare more and more challenging natural products. The first and second generation Grubbs catalysts 1 and 2 and the Hoveyda catalyst 3 are the most widely used. Daesung Lee of the University of Illinois at Chicago designed (Organic Lett. 2008, 10, 257) a clever chain-walking cross metathesis, combining 4 and 5 to make 6. The diyne 3 was carried on (3R, 9R, 10R )-Panaxytriol 7. Tatsushi Imahori and Hiroki Takahata of Tohoku Pharmaceutical University found (Tetrahedron Lett. 2008, 49, 265) that of the several derivatives investigated, the unprotected alcohol 8 cyclized most efficiently. Selective cleavage of the monosubstituted alkene followed by hydroboration delivered the alkaloid Isofagomine 10. Brian M. Stoltz of Caltech established (J. Am. Chem. Soc. 2008 , 130 , 810) the absolute configuration of the halogenated chamigrene Elatol 14 using the enantioselective enolate allylation that he had previously devised. A key feature of this synthesis was the stereocontrolled preparation of the cis bromohydrin. Marc L. Snapper of Boston College opened (J. Org. Chem. 2008, 73, 3754) the strained cyclobutene 15 with ethylene to give the diene 16. Remarkably, cross metathesis with 17 delivered 18 with high regioselectivity, setting the stage for the preparation of the 5-F2t - Isoprostane 19. Derrick L. J. Clive of the University of Alberta assembled (J. Org. Chem. 2008, 73, 3078) Ottelione B 26 from the enantiomerically-pure aldehyde 20. Conjugate addition of the Grignard reagent 21 derived from chloroprene gave the kinetic product 22, that was equilibrated to the more stable 23. Addition of vinyl Grignard followed by selective ring-closing metathesis then led to 26.

Alkene and Alkyne Metathesis: Grandisol (Goess), 8-Epihalosilane (Kouklovsky/Vincent), (+)-Chinensiolide B (Hall)

2013 ◽  
Author(s):  
Douglass F. Taber
Keyword(s):  
Boll Weevil ◽  
Alkyne Metathesis ◽  
Ring Closing Metathesis ◽  
Enantiomerically Pure ◽  
Ru Catalyst ◽  
Complementary Approach ◽  
Terminal Substituent ◽  
Furman University ◽  
The Cost ◽  
The University

The cost of using Grubbs-type catalysts could be reduced dramatically if the turnover could be improved. Richard L. Pederson of Materia found (Organic Lett. 2010, 12, 984) that in MTBE at 50°C, the ring-closing metathesis of 1 proceeded to completion in 8 hours with just 500 ppm of H2 catalyst 2. Jianhui Wang of Tianjin University constructed (Angew. Chem. Int. Ed. 2010, 49, 4425) a modified H2 catalyst 5 tethered to a nitrobenzospiropyran. After the cyclization of 4 to 6 was run in CH2Cl2, the mixture was irradiated with visible light, converting 5 into its ionic form, which could be extracted with glycol/methanol, leaving little Ru residue in the cyclized product. In the dark, the catalyst reverted and could be extracted back into CH2Cl2 and reused. In a complementary approach, David W. Knight of Cardiff University found (Tetrahedron Lett. 2010, 51, 638) that the residual Ru after metathesis could be reduced to < 2 ppm simply by stirring the product with H2O2. Cyclopropenes such as 6 are readily available in enantiomerically pure form by the addition of diazoacetates to alkynes. Christophe Meyer and Janine Cossy of ESPCI ParisTech showed (Organic Lett. 2010, 12, 248) that with a Ti additive, G2 cyclized 7 to 8. Siegfried Blechert of the Technische Universität Berlin devised (Angew. Chem. Int. Ed. 2010, 49, 3972) the chiral Ru catalyst 11, which converted the prochiral 9 to 12 in high ee. Daesung Lee of the University of Illinois, Chicago, explored (J. Am. Chem. Soc. 2010, 132, 8840) the cyclization of the diyne 13 with 14 under G2 catalysis. Depending on the terminal substituent, the cyclization could be directed selectively to 15 or 16. Bran C. Goess of Furman University took advantage (J. Org. Chem. 2010, 75, 226) of alkyne ring-closing metathesis for the conversion of 17 to 18. Selective hydrogenation then delivered the boll weevil pheromone grandisol 19. Cyrille Kouklovsky and Guillaume Vincent of the Université de Paris Sud extended (J. Org. Chem. 2010, 75, 4333) ring-opening/ring-closing metathesis to the nitroso Diels-Alder adduct 20. Reduction led to 8-epihalosilane 22.

scholarly journals Recent Advances in Total Synthesis via Metathesis Reactions

Synthesis ◽  
2018 ◽  
Vol 50 (19) ◽  
pp. 3749-3786 ◽  
Author(s):  
Francisco Sarabia ◽  
Iván Cheng-Sánchez
Keyword(s):  
Total Synthesis ◽  
Tandem Reactions ◽  
Alkyne Metathesis ◽  
Enyne Metathesis ◽  
Metathesis Reaction ◽  
Ring Closing Metathesis ◽  
Total Syntheses ◽  
Cross Metathesis ◽  
Carbon Carbon Bonds ◽  
Metathesis Reactions

The metathesis reactions, in their various versions, have become a powerful and extremely valuable tool for the formation of carbon–carbon bonds in organic synthesis. The plethora of available catalysts to perform these reactions, combined with the various transformations that can be accomplished, have positioned the metathesis processes as one of the most important reactions of this century. In this review, we highlight the most relevant synthetic contributions published between 2012 and early 2018 in the field of total synthesis, reflecting the state of the art of this chemistry and demonstrating the significant synthetic potential of these methodologies.1 Introduction2 Alkene Metathesis in Total Synthesis2.1 Total Synthesis Based on a Ring-Closing-Metathesis Reaction2.2 Total Synthesis Based on a Cross-Metathesis Reaction2.3 Strategies for Selective and Efficient Metathesis Reactions of Alkenes2.3.1 Temporary Tethered Ring-Closing Metathesis2.3.2 Relay Ring-Closing Metathesis2.3.3 Stereoselective Alkene Metathesis2.3.4 Alkene Metathesis in Tandem Reactions3 Enyne Metathesis in Total Synthesis3.1 Total Syntheses Based on a Ring-Closing Enyne-Metathesis Reaction3.2 Total Syntheses Based on an Enyne Cross-Metathesis Reaction3.3 Enyne Metathesis in Tandem Reactions4 Alkyne Metathesis in Total Synthesis4.1 Total Synthesis Based on a Ring-Closing Alkyne-Metathesis Reaction4.2 Other Types of Alkyne-Metathesis Reactions5 Conclusions

Alkene and Alkyne Metathesis: Navenone B (Cossy), (+)-Asperpentyn (Daesung Lee), (-)-Amphidinolide K (Eun Lee), Norhalichondrin B (Phillips)

2013 ◽  
Author(s):  
Douglass F. Taber
Keyword(s):  
Allylic Alcohol ◽  
Alkyne Metathesis ◽  
University Of Illinois ◽  
Cross Metathesis ◽  
Synthetic Strategy ◽  
University Of Colorado ◽  
National University ◽  
The Cross ◽  
Seoul National University ◽  
The University

A variety of antibiotics and immune-suppressive agents contain extended arrays of all- ( E )-polyenes. Samir Bouzbouz of CNS Rouen and Janine Cossy of ESPCI ParisTech devised ( Synlett 2009, 803) a simple iterative route to polyacetates such as 1 and demonstrated that after cross-metathesis, elimination, in this case to give Navenone B 3, was facile. Both ketones and esters can promote the elimination. Daesung Lee of the University of Illinois at Chicago designed (Organic Lett. 2009, 11 , 571) a clever chain-walking ring-closing ene-yne metathesis, cyclizing 4 to 5. Deprotection led to (+)-asperpentyn 6. This should be a general entry to such polyoxygenated cyclohexenes. For the structures of H2 and G2, see Organic Highlights, September 13, 2004. One of the challenges in the synthesis of (-)-amphidinoloide K 10 is the assembly of the complex conjugated diene. Eun Lee of Seoul National University found (Angew. Chem. Int. Ed. 2009, 48, 2364) a solution to this problem in the Ru-catalyzed cross-metathesis between the alkyne 7 and the alkene 8. Note that the cross-metathesis proceeded with high regioselectivity and with substantial (7.5:1) control of the product alkene geometry. For the construction of complex natural products such as norhalichondrin B 14, it is important to employ a convergent synthetic strategy. For this to be successful, efficient methods for convergent coupling are required. In the course of a synthesis of 14, Andrew J. Phillips of the University of Colorado showed (Angew. Chem. Int. Ed. 2009, 48, 2346) that Ru-mediated cross-metathesis could be used to couple the enone 11 with the alkene 12. A less congested version of H2, designed by Robert H. Grubbs of Caltech, was used for the coupling. The electron-deficient alkene of 11 and the more electron-rich alkene of 12 made a matched set, promoting the cross-coupling. Note again, in this context, the desirability of leaving the allylic alcohol of 12 unprotected to facilitate Ru-catalyzed alkene cross-metathesis.

scholarly journals Ring Rearrangement Metathesis in 7-Oxabicyclo[2.2.1]heptene (7-Oxanorbornene) Derivatives. Some Applications in Natural Product Chemistry

2017 ◽  
Vol 12 (5) ◽  
pp. 1934578X1701200
Author(s):  
Silvia Roscales ◽  
Joaquín Plumet
Keyword(s):  
Diels Alder ◽  
Coupling Reactions ◽  
Alkyne Metathesis ◽  
Heck Reactions ◽  
One Pot ◽  
Cross Metathesis ◽  
Cross Coupling Reactions ◽  
Synthetic Procedure ◽  
Metathesis Reactions ◽  
Metal Catalyzed

Metathesis reactions is firmly established as a valuable synthetic tool in organic chemistry, clearly comparable with the venerable Diels-Alder and Wittig reactions and, more recently, with the metal-catalyzed cross-coupling reactions. Metathesis reactions can be considered as a fascinating synthetic methodology, allowing different variants regarding substrate (alkene and alkyne metathesis) and type of metathetical reactions. On the other hand, tandem metathesis reactions such Ring Rearrangement Metathesis (RRM) and the coupling of metathesis reaction with other reactions of alkenes such as Diels-Alder or Heck reactions, makes metathesis one of the most powerful and reliable synthetic procedure. In particular, Ring-Rearrangement Metathesis (RRM) refers to the combination of several metathesis transformations into a domino process such as ring-opening metathesis (ROM)/ring-closing metathesis (RCM) and ROM-cross metathesis (CM) in a one-pot operation. RRM delivers complex frameworks that are difficult to assemble by conventional methods constitutingan atom economic process. RRM is applicable to mono- and polycyclic systems of varying ring sizes such as cyclopropene, cyclobutene, cyclopentene, cyclohexene, pyran systems, bicyclo[2.2.1]heptene derivatives, bicyclo[2.2.2]octene derivatives, bicyclo[3.2.1]octene derivatives and bicyclo[3.2.1]octene derivatives. In this review our attention has focused on the RRM reactions in 7-oxabicyclo[2.2.1]heptene derivatives and on their application in the synthesis of natural products or significant subunits of them.

Advances in Alkene Metathesis: The Kobayashi Synthesis of (+)-TMC-151C

2015 ◽  
Author(s):  
Douglass F. Taber
Keyword(s):  
Ethyl Acrylate ◽  
Cascade Process ◽  
Aqueous Mixtures ◽  
University Of Minnesota ◽  
Ring Closing Metathesis ◽  
Ru Catalyst ◽  
Cross Metathesis ◽  
Mo Catalyst ◽  
Institute Of Technology ◽  
The University

Shazia Zaman of the University of Canterbury and Andrew D. Abell of the University of Adelaide devised (Tetrahedron Lett. 2011, 52, 878) a polyethylene glycol-tagged Ru catalyst that is effective for alkene metathesis in aqueous mixtures, cyclizing 1 to 2. Bruce H. Lipshutz of the University of California, Santa Barbara developed (J. Org. Chem. 2011, 76, 4697, 5061) an alternative approach for aqueous methathesis, and also showed that CuI is an effective cocatalyst, converting 3 to 5. Christian Slugovc of the Graz University of Technology showed (Tetrahedron Lett. 2011, 52, 2560) that cross metathesis of the diene 6 with ethyl acrylate 7 could be carried out with very low catalyst loadings. Robert H. Grubbs of the California Institute of Technology designed (J. Am. Chem. Soc. 2011, 133, 7490) a Ru catalyst for the ethylenolysis of 9 to 10 and 11. Thomas R. Hoye of the University of Minnesota showed (Angew. Chem. Int. Ed. 2011, 50, 2141) that the allyl malonate linker of 12 was particularly effective in promoting relay ring-closing metathesis to 13. Amir H. Hoveyda of Boston College designed (Nature 2011, 471, 461) a Mo catalyst that mediated the cross metathesis of 14 with 15 to give 16 with high Z selectivity. Professor Grubbs designed (J. Am. Chem. Soc. 2011, 133, 8525) a Z selective Ru catalyst. Damian W. Young of the Broad Institute demonstrated (J. Am. Chem. Soc. 2011, 133, 9196) that ring closing metathesis of 17 followed by desilylation also led to the Z product, 18. Thomas E. Nielsen of the Technical University of Denmark devised (Angew. Chem. Int. Ed. 2011, 50, 5188) a Ru-mediated cascade process, effecting ring-closing metathesis of 19, followed by alkene migration to the enamide, and finally diastereoselective cyclization to 20. In the course of a total synthesis of (–)-goniomitine, Chisato Mukai of Kanazawa University showed (Org. Lett. 2011, 13, 1796) that even the very congested alkene of 22 smoothly participated in cross metathesis with 21 to give 23. En route to leustroducsin B, Jeffrey S. Johnson of the University of North Carolina protected (Org. Lett. 2011, 13, 3206) an otherwise incompatible terminal alkyne as its Co complex 24, allowing ring closing methathesis to 25.

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