Co-reporter:Vikas Kumar
Chemical Communications 2017 vol. 53(Issue 73) pp:10212-10215
Publication Date(Web):2017/09/12
DOI:10.1039/C7CC05561G
A new N-heterocyclic carbene-catalysed oxidative amidation of aldehydes has been developed which converts the aldehyde to a benzil acylating agent in situ. The process uses an air-recyclable oxidant and a nucleophilic co-catalyst and does not require the use of a large excess of either one coupling partner or catalyst.
Co-reporter:Cristina Trujillo;Isabel Rozas;Astrid Botte
Chemical Communications 2017 vol. 53(Issue 63) pp:8874-8877
Publication Date(Web):2017/08/03
DOI:10.1039/C7CC04596D
The first DFT study of the cycloaddition of benzaldehyde with homophthalic anhydride under the influence of a bifunctional organocatalyst is reported. The catalyst first binds and then deprotonates the anhydride, leading to a squaramide-bound enolate, which then adds to the aldehyde with activation of the electrophile by the catalyst's ammonium ion.
Co-reporter:Francesco Manoni;Umar Farid;Cristina Trujillo
Organic & Biomolecular Chemistry 2017 vol. 15(Issue 6) pp:1463-1474
Publication Date(Web):2017/02/07
DOI:10.1039/C6OB02637K
The first examples of asymmetric Tamura cycloaddition reactions involving singly activated alkenes are reported. Homophthalic anhydride reacts with α-methyl nitrosytrenes in the presence of an alkaloid-based catalyst to generate fused bicyclic aromatic ketone products with three new stereocentres (which are susceptible to subsequent equilibration) in 12–99% ee. An unusual equilibration process which occurs in methanolic medium in the absence of a recognisable base via proton transfer at the α-carbon of an ester was investigated experimentally and computationally.
Co-reporter:Emiliano Sorrentino and Stephen J. Connon
Organic Letters 2016 Volume 18(Issue 20) pp:5204-5207
Publication Date(Web):October 4, 2016
DOI:10.1021/acs.orglett.6b02398
The first strategy for bringing about highly enantioselective alkylative enolate kinetic resolutions using a simple phase-transfer protocol via SN2 chemistry has been developed. In the presence of a new squaramide-based quaternized cinchona alkaloid-derived catalyst and aqueous base, benzyl, allyl, and propargyl halides react with racemic substituted oxindoles to generate densely functionalized products with the two contiguous stereocenters, one of which is an all-carbon quaternary.
Co-reporter:Claudio Cornaggia, Sivaji Gundala, Francesco Manoni, Nagaraju Gopalasetty and Stephen J. Connon
Organic & Biomolecular Chemistry 2016 vol. 14(Issue 11) pp:3040-3046
Publication Date(Web):18 Feb 2016
DOI:10.1039/C6OB00089D
It has been shown for the first time that enolisable anhydrides can participate in highly efficient and diastereo/enantioselective additions to activated ketones. In these reactions the anhydride component formally acts (initially) as the nucleophilic component. These processes are promoted by novel, readily prepared urea-substituted cinchona alkaloid-derived catalysts at low loadings under mild conditions. Three classes of enolisable anhydride and three different types of activated ketone were shown to be compatible with the process – generating a diverse range of structurally distinct and densely functionalised lactone products with the formation of two new stereocentres, one of which is quaternary. In one example, a product incorporating two contiguous quaternary stereocentres (one all carbon) was formed with outstanding enantiocontrol. It has been shown in the case of glutaconic anhydride derivatives that the cycloaddtion process is reversible, and can be accompanied by decarboxylation and olefin isomerisation. Reaction conditions can be modified to give access to three types of product with good–excellent ee.
Co-reporter:Sarah A. Cronin, Aarón Gutiérrez Collar, Sivaji Gundala, Claudio Cornaggia, Esther Torrente, Francesco Manoni, Astrid Botte, Brendan Twamley and Stephen J. Connon
Organic & Biomolecular Chemistry 2016 vol. 14(Issue 29) pp:6955-6959
Publication Date(Web):06 Jul 2016
DOI:10.1039/C6OB00048G
The first catalytic, asymmetric reactions of imines with homophthalic anhydride to form disubstituted 3,4-dihydroisoquinolones are reported. The use of N-mesyl aldimines is key, as more basic imines undergo rapid uncatalysed reactions, while imines possessing larger N-sulphonyl substituents form lactams with lower ee.
Co-reporter:Lauren Myles;Nicholas Gathergood
European Journal of Organic Chemistry 2015 Volume 2015( Issue 1) pp:188-194
Publication Date(Web):
DOI:10.1002/ejoc.201402947
Abstract
A new, organocatalytic approach to the hydrolytic deprotection of dithianes has been developed involving a low-toxicity imidazolium-ion-based catalyst in an aqueous medium. A complimentary solvent-free method without added water and involving a sacrificial aldehyde is also reported. The catalyst does not appear to operate by a specific-acid catalysis mechanism.
Co-reporter:Dr. Sean Tallon;Dr. Francesco Manoni ; Stephen J. Connon
Angewandte Chemie International Edition 2015 Volume 54( Issue 3) pp:813-817
Publication Date(Web):
DOI:10.1002/anie.201406857
Abstract
The first strategy for bringing about enantioselective azlactone dynamic kinetic resolution to generate orthogonally protected amino acids has been developed. In the presence of a C2-symmetric squaramide-based catalyst, benzyl alcohol reacts with novel yet readily prepared tetrachloroisopropoxycarbonyl-substituted azlactones to generate trapped phthalimide products of significant synthetic interest with excellent enantiocontrol. These materials are masked amino acids which are demonstrably orthogonally protected: cleavage of the phthalimide can be achieved in the presence of the ester and vice versa. This process could be utilized to bring about a highly stereoselective ligation-type coupling of protected serines (at stoichiometric loadings) with racemic azlactones derived from both natural and abiotic amino acids. After deprotection, a subsequent base-mediated ON acyl transfer occurs to form a dipeptide.
Co-reporter:Dr. Sean Tallon;Dr. Francesco Manoni ; Stephen J. Connon
Angewandte Chemie 2015 Volume 127( Issue 3) pp:827-831
Publication Date(Web):
DOI:10.1002/ange.201406857
Abstract
The first strategy for bringing about enantioselective azlactone dynamic kinetic resolution to generate orthogonally protected amino acids has been developed. In the presence of a C2-symmetric squaramide-based catalyst, benzyl alcohol reacts with novel yet readily prepared tetrachloroisopropoxycarbonyl-substituted azlactones to generate trapped phthalimide products of significant synthetic interest with excellent enantiocontrol. These materials are masked amino acids which are demonstrably orthogonally protected: cleavage of the phthalimide can be achieved in the presence of the ester and vice versa. This process could be utilized to bring about a highly stereoselective ligation-type coupling of protected serines (at stoichiometric loadings) with racemic azlactones derived from both natural and abiotic amino acids. After deprotection, a subsequent base-mediated ON acyl transfer occurs to form a dipeptide.
Co-reporter:Francesco Manoni ; Stephen J. Connon
Angewandte Chemie 2014 Volume 126( Issue 10) pp:2666-2670
Publication Date(Web):
DOI:10.1002/ange.201309297
Abstract
In the presence of a novel, tert-butyl-substituted squaramide-based catalyst, enolizable anhydrides react with alkylidene oxindoles to generate spirooxindole products of significant synthetic interest with excellent enantio- and diastereocontrol. The methodology is of wide scope and encompasses both homophthalic and glutaconic anhydride derivatives, which lead to structurally diverse products. Glutaconic acid-derived anhydrides undergo a clean post-cyclization decarboxylation process which is not a feature of reactions involving homophthalic acid-derived anhydrides. The unusual influence of reaction temperature on diastereocontrol has been probed, with reactions occurring at 30 °C and −30 °C delivering products epimeric at one stereocenter only, in near optical purity.
Co-reporter: Stephen J. Connon
Angewandte Chemie 2014 Volume 126( Issue 5) pp:1225-1227
Publication Date(Web):
DOI:10.1002/ange.201309256
Co-reporter:Francesco Manoni ; Stephen J. Connon
Angewandte Chemie International Edition 2014 Volume 53( Issue 10) pp:2628-2632
Publication Date(Web):
DOI:10.1002/anie.201309297
Abstract
In the presence of a novel, tert-butyl-substituted squaramide-based catalyst, enolizable anhydrides react with alkylidene oxindoles to generate spirooxindole products of significant synthetic interest with excellent enantio- and diastereocontrol. The methodology is of wide scope and encompasses both homophthalic and glutaconic anhydride derivatives, which lead to structurally diverse products. Glutaconic acid-derived anhydrides undergo a clean post-cyclization decarboxylation process which is not a feature of reactions involving homophthalic acid-derived anhydrides. The unusual influence of reaction temperature on diastereocontrol has been probed, with reactions occurring at 30 °C and −30 °C delivering products epimeric at one stereocenter only, in near optical purity.
Co-reporter: Stephen J. Connon
Angewandte Chemie International Edition 2014 Volume 53( Issue 5) pp:1203-1205
Publication Date(Web):
DOI:10.1002/anie.201309256
Co-reporter:Lauren Myles, Rohitkumar G. Gore, Nicholas Gathergood and Stephen J. Connon
Green Chemistry 2013 vol. 15(Issue 10) pp:2740-2746
Publication Date(Web):29 Aug 2013
DOI:10.1039/C3GC40975A
Catalysts which have low antimicrobial toxicity and are aprotic, yet which can act as Brønsted acidic catalysts in the presence of protic additives have been developed. The catalysts are recyclable, considerably more active (i.e. can be used at 10–50 times lower loadings) and of broader scope than their antecedent generation.
Co-reporter:Eoghan G. Delany, Claire-Louise Fagan, Sivaji Gundala, Alessandra Mari, Thomas Broja, Kirsten Zeitler and Stephen J. Connon
Chemical Communications 2013 vol. 49(Issue 58) pp:6510-6512
Publication Date(Web):14 Jun 2013
DOI:10.1039/C3CC42596G
A highly efficient, broad scope, additive-free mild protocol for the oxidative carbene-catalysed esterification of aldehydes (including the related aqueous oxidation to acids) has been developed.
Co-reporter:Eoghan G. Delany, Claire-Louise Fagan, Sivaji Gundala, Kirsten Zeitler and Stephen J. Connon
Chemical Communications 2013 vol. 49(Issue 58) pp:6513-6515
Publication Date(Web):14 Jun 2013
DOI:10.1039/C3CC42597E
Benzoin (and neither the Breslow intermediate nor the NHC–aldehyde tetrahedral adduct) has been unambiguously identified as the oxidised species in aerobic NHC-catalysed aldehyde esterifications.
Co-reporter:Lauren Myles, Nicholas Gathergood and Stephen J. Connon
Chemical Communications 2013 vol. 49(Issue 46) pp:5316-5318
Publication Date(Web):03 May 2013
DOI:10.1039/C3CC41588K
The ability of triazolium salts to serve as a precatalyst for both an acid and a powerful base/nucleophile (controlled by additives) has been exploited in a process characterised by a unique in situ catalyst modification strategy.
Co-reporter:Sarah A. Kavanagh, Alessandro Piccinini and Stephen J. Connon
Organic & Biomolecular Chemistry 2013 vol. 11(Issue 21) pp:3535-3540
Publication Date(Web):18 Apr 2013
DOI:10.1039/C3OB27271K
A new ylide-based protocol for the asymmetric aziridination of imines via methylene transfer has been developed involving the use of a simple chiral sulfonium salt and an organic strong base. A systematic study identified triisopropylphenyl sulfonylimines as optimal substrates for the process. Unexpectedly, hindered C2-symmetric sulfonyl salts incorporating bulky ethers at C-2 and C-5 – which had previously been useful in the corresponding epoxidation chemistry – decomposed in these aziridination reactions via competing elimination pathways. Under optimised conditions it was found that a simple salt derived from (2R,5R)-2,5-diisopropyl thiolane could mediate asymmetric methylene transfer to a range of imines with uniformly excellent yields with 19–30% ee. Since this is a similar level of enantiomeric excess to that obtained using these same salts in epoxidation chemistry, it was concluded that if more bulky sulfonium salts could be devised which were resistant to decomposition under the reaction conditions, that highly enantioselective aziridine formation by methylene transfer would be possible.
Co-reporter:Carole Palacio
European Journal of Organic Chemistry 2013 Volume 2013( Issue 24) pp:5398-5413
Publication Date(Web):
DOI:10.1002/ejoc.201300451
Abstract
The highly enantioselective dynamic kinetic resolution (DKR) of azlactones by thiolysis has been achieved for the first time. Although both the parent alkaloid quinine and known C-5′-urea derivatives fail to promote the reaction effectively, a new class of C-5′-hydroxylated catalysts proved capable of catalysing the DKR of a range of azlactones derived from both unbranched- and, previously challenging, branched-chain amino acids in 84–92 % ee, including an example of the synthesis of an enantioenriched N-protected thioester derived from an extraterrestrial amino acid isolated from the Murchison meteorite.
Co-reporter:Christopher A. Rose, Sivaji Gundala, Claire-Louise Fagan, Johannes F. Franz, Stephen J. Connon and Kirsten Zeitler
Chemical Science 2012 vol. 3(Issue 3) pp:735-740
Publication Date(Web):12 Dec 2011
DOI:10.1039/C2SC00622G
It has been shown for the first time that relatively electron deficient triazolium pre-catalysts promote (at low loadings in the presence of base) highly chemoselective crossed acyloin condensation reactions between aldehydes and α-ketoesters to afford densely functionalized products incorporating a quaternary stereocentre of considerable synthetic potential. Hydroacylation pathways which have hitherto been dominant in these reactions can be completely avoided. The scope of the process is extraordinarily broad with respect to both coupling partners, and a preliminary study has established the principle that a high degree of stereochemical control over the reaction can also be exercised via the use of a chiral NHC precursor. It has also been shown for the first time that coupling of benzyl α-ketoesters with aldehydes followed by acylation and simple hydrogenolysis furnishes a product formally derived from the chemoselective 1:1 coupling of two different aliphatic aldehydes in high yield with absolute control over which coupling partner behaves as the acyl-anion equivalent.
Co-reporter:Cormac Quigley, Zaida Rodríguez-Docampo and Stephen J. Connon
Chemical Communications 2012 vol. 48(Issue 10) pp:1443-1445
Publication Date(Web):06 Sep 2011
DOI:10.1039/C1CC14684J
We report the design and evaluation of a library of chiral bifunctional organocatalysts in which the distance between the catalytically active units can be systematically varied.
Co-reporter:Claudio Cornaggia, Francesco Manoni, Esther Torrente, Sean Tallon, and Stephen J. Connon
Organic Letters 2012 Volume 14(Issue 7) pp:1850-1853
Publication Date(Web):March 26, 2012
DOI:10.1021/ol300453s
In the presence of a highly efficient novel bifunctional organocatalyst at low loadings under mild conditions, enolizable homophthalic anhydrides can be added to a range of aromatic and aliphatic aldehydes to give dihydroisocoumarins, with excellent yields and diastereo- and enantiocontrol (up to 99% ee).
Co-reporter:Alessandro Piccinini, Sarah A. Kavanagh and Stephen J. Connon
Chemical Communications 2012 vol. 48(Issue 63) pp:7814-7816
Publication Date(Web):02 Jul 2012
DOI:10.1039/C2CC32101G
The highly efficient asymmetric epoxidation of aldehydes by methylene transfer is now possible using new sulfonium salts.
Co-reporter:Francesco Manoni, Claudio Cornaggia, James Murray, Sean Tallon and Stephen J. Connon
Chemical Communications 2012 vol. 48(Issue 52) pp:6502-6504
Publication Date(Web):23 May 2012
DOI:10.1039/C2CC32147E
A new, highly enantio- and diastereoselective catalytic asymmetric formal cycloaddition of aryl succinic anhydrides and aldehydes which generates paraconic acid (γ-butyrolactone) derivatives is reported.
Co-reporter:Carole Palacio and Stephen J. Connon
Chemical Communications 2012 vol. 48(Issue 23) pp:2849-2851
Publication Date(Web):10 Feb 2012
DOI:10.1039/C2CC17965B
A new bifunctional C-5′ substituted cinchona alkaloid-based catalyst promotes the first highly enantioselective additions of alkyl thiols to nitrostyrenes.
Co-reporter:Simon P. Curran and Stephen J. Connon
Organic Letters 2012 Volume 14(Issue 4) pp:1074-1077
Publication Date(Web):February 3, 2012
DOI:10.1021/ol203439g
Selenide ions have been shown to catalyze the Tishchenko reaction for the first time. These catalysts are superior to previously reported thiolate analogues and promote the disproportionation of aldehydes with increased reaction rates and broader scope at lower catalyst loadings and temperatures. Significantly improved catalyst performance was also observed in the aryl selenide mediated crossed intermolecular Tishchenko reaction.
Co-reporter:Dr. Zaida Rodriguez-Docampo ; Stephen J. Connon
ChemCatChem 2012 Volume 4( Issue 2) pp:151-168
Publication Date(Web):
DOI:10.1002/cctc.201100266
Abstract
This review charts the recent progress of two related, yet distinct organocatalytic processes: the desymmetrisation of meso-anhydrides and the dynamic kinetic resolution of azlactones. Driven by recent advances in catalyst design, both these processes have undergone something of a renaissance in recent years and are now becoming very powerful and versatile synthetic methodologies. The material is presented in a critical fashion and the material is organised by reaction type and catalyst class.
Co-reporter:Simon P. Curran ; Stephen J. Connon
Angewandte Chemie 2012 Volume 124( Issue 43) pp:11024-11028
Publication Date(Web):
DOI:10.1002/ange.201206343
Co-reporter:Simon P. Curran ; Stephen J. Connon
Angewandte Chemie International Edition 2012 Volume 51( Issue 43) pp:10866-10870
Publication Date(Web):
DOI:10.1002/anie.201206343
Co-reporter:Zaida Rodríguez-Docampo, Cormac Quigley, Sean Tallon, and Stephen J. Connon
The Journal of Organic Chemistry 2012 Volume 77(Issue 5) pp:2407-2414
Publication Date(Web):February 22, 2012
DOI:10.1021/jo202662d
A significant improvement of the available organocatalytic methods (in terms of product substrate scope and product enantiomeric excess) for the generation of enantioenriched α-amino acid thioesters via the dynamic kinetic resolution of azlactones is reported. C-9 arylated cinchona alkaloid catalysts have been found to be considerably superior to other bifunctional alkaloid catalysts as the promoters of this asymmetric process.
Co-reporter:Oliver Gleeson, Gemma-Louise Davies, Aldo Peschiulli, Renata Tekoriute, Yurii K. Gun'ko and Stephen J. Connon
Organic & Biomolecular Chemistry 2011 vol. 9(Issue 22) pp:7929-7940
Publication Date(Web):11 Oct 2011
DOI:10.1039/C1OB06110K
A systematic study concerning the immobilisation onto magnetic nanoparticles of three useful classes of chiral organocatalyst which rely on a confluence of weak, easily perturbed van der Waals and hydrogen bonding interactions to promote enantioselective reactions has been undertaken for the first time. The catalysts were evaluated in three different synthetically useful reaction classes: the kinetic resolution of sec-alcohols, the conjugate addition of dimethyl malonate to a nitroolefin and the desymmetrisation of meso anhydrides. A chiral bifunctional 4-N,N-dialkylaminopyridine derivative could be readily immobilised; the resulting heterogeneous catalyst is highly active and is capable of promoting the kinetic resolution of sec-alcohols with synthetically useful selectivity under process-scale friendly conditions and has been demonstrated to be reusable in a minimum of 32 consecutive cycles. The immobilisation of a cinchona alkaloid-derived urea-substituted catalyst proved considerably less successful in terms of both catalyst stability and product levels of enantiomeric excess. An immobilised cinchona alkaloid-derived sulfonamide catalyst was also prepared, with mixed results: the catalyst exhibits outstanding recyclability on a par with that associated with the successful N,N-dialkylaminopyridine analogue, however product enantiomeric excess is consistently lower than that obtained using the corresponding homogeneous catalyst. While no physical deterioration of the heterogeneous catalysts was detected on analysis after multiple recycles, in the cases of both the conjugate addition to nitroolefins and the desymmetrisation of meso anhydrides, significant levels of background catalysis by the nanoparticles in the absence of the organocatalyst was detected, which explains in part the poor performance of the immobilised organocatalysts in these reactions from a stereoselectivity standpoint. It seems clear that the immobilisation of sensitive chiral organocatalysts onto magnetite nanoparticles does not always result in heterogeneous catalysts with acceptable activity and selectivity profiles, and that consequently the applicability of the strategy must be ascertained (until more data is available) on a case-by-case basis.
Co-reporter:Cornelius J. O' Connor, Francesco Manoni, Simon P. Curran and Stephen J. Connon
New Journal of Chemistry 2011 vol. 35(Issue 3) pp:551-553
Publication Date(Web):31 Jan 2011
DOI:10.1039/C0NJ00790K
Recently, the first efficient intermolecular crossed Tishchenko reactions were reported. The utility of these processes is curtailed by long reaction times of up to 4 days (at reflux). Herein we report that these reactions are highly susceptible to acceleration by microwave irradiation—allowing fast, efficient, high-yielding coupling to proceed in 10–180 min.
Co-reporter:Lauren Myles, Rohitkumar Gore, Marcel Špulák, Nicholas Gathergood and Stephen J. Connon
Green Chemistry 2010 vol. 12(Issue 7) pp:1157-1162
Publication Date(Web):18 May 2010
DOI:10.1039/C003301D
Imidazolium derived ionic liquid catalysts have been developed which are aprotic and of low antimicrobial and antifungal toxicity, yet which can act as efficient Brønsted acidic catalysts in the presence of protic additives. The catalysts can be utilised at low loadings and can be recycled 15 times without any discernible loss of activity.
Co-reporter:Alessandro Piccinini, Sarah A. Kavanagh, Paul B. Connon and Stephen J. Connon
Organic Letters 2010 Volume 12(Issue 3) pp:608-611
Publication Date(Web):January 7, 2010
DOI:10.1021/ol902816w
An investigation into the poor activity of sulfides as catalysts for sulfonium-ylide-mediated methylene transfer to aldehydes has indicated that ylide formation is the problematic catalytic cycle step. Alkylation with traditional electrophiles does not proceed with sufficient efficiency to allow the sulfide to be used catalytically. Methyl triflate rapidly alkylates cyclic thiolanes under mild conditions, allowing their use in efficient aldehyde epoxidation reactions (in conjunction with phosphazene bases) at loadings as low as 10 mol %.
Co-reporter:SarahA. Kavanagh;Alessro Piccinini ;StephenJ. Connon
Advanced Synthesis & Catalysis 2010 Volume 352( Issue 11-12) pp:2089-2093
Publication Date(Web):
DOI:10.1002/adsc.201000255
Abstract
It has been demonstrated for the first time that a sulfide catalyst, utilised at 20 mol% loading, can promote methylene transfer to ketones in the presence of methyl triflate and an organic base. This metal-free methodology is of broad scope – both aliphatic and aromatic ketones (including trifluoromethyl ketones) can be converted to synthetically useful terminal epoxides in excellent yields at room temperature.
Co-reporter:David P. Power, Olivier Lozach, Laurent Meijer, David H. Grayson, Stephen J. Connon
Bioorganic & Medicinal Chemistry Letters 2010 Volume 20(Issue 16) pp:4940-4944
Publication Date(Web):15 August 2010
DOI:10.1016/j.bmcl.2010.06.024
A remarkably concise, chromatography-free route to the parent compound of the paullone family of cyclin-dependent kinase (CDK) inhibitors is reported. A similar strategy allowed the synthesis of the hitherto missing 9-azapaullone and its protonated, N-oxidised and N-alkylated derivatives. Screening studies identified an active and strongly selective inhibitor of CDK9/cyclin T.
Co-reporter:Linda Cronin Dr.;Francesco Manoni;CorneliusJ. O'Connor Dr. ;StephenJ. Connon Dr.
Angewandte Chemie International Edition 2010 Volume 49( Issue 17) pp:3045-3048
Publication Date(Web):
DOI:10.1002/anie.200907167
Co-reporter:Linda Cronin Dr.;Francesco Manoni;CorneliusJ. O'Connor Dr. ;StephenJ. Connon Dr.
Angewandte Chemie 2010 Volume 122( Issue 17) pp:3109-3112
Publication Date(Web):
DOI:10.1002/ange.200907167
Co-reporter:Sarah E. O'Toole and Stephen J. Connon
Organic & Biomolecular Chemistry 2009 vol. 7(Issue 17) pp:3584-3593
Publication Date(Web):10 Jul 2009
DOI:10.1039/B908517C
The design of a new class of triazolium ion precatalysts incorporating protic substituents is described. These materials promote the enantioselective benzoin condensation of a range of aromatic aldehydes (1–62% ee). Catalyst evaluation studies strongly support the involvement of hydrogen bond donation by the catalyst in the stereocentre-forming step of the catalytic cycle.
Co-reporter:Oliver Gleeson;Renata Tekoriute;YuriiK. Gun'ko ;StephenJ. Connon Dr.
Chemistry - A European Journal 2009 Volume 15( Issue 23) pp:5669-5673
Publication Date(Web):
DOI:10.1002/chem.200900532
Co-reporter:Barbara Procuranti and Stephen J. Connon
Organic Letters 2008 Volume 10(Issue 21) pp:4935-4938
Publication Date(Web):October 7, 2008
DOI:10.1021/ol802008m
Simple pyridinium salt derivatives have been (rather unexpectedly) shown to promote highly efficient acetalization reactions of both aldehydes and ketones at ambient temperature. The optimum catalyst is aprotic, yet it can promote the formation of benzaldehyde dimethyl acetal at 0.1 mol % loading more efficiently than a protic Brønsted acid catalyst with a pKa of 2.2. The process is of wide scope with respect to both the nucleophilic and electrophilic components, and the ionic catalyst can be readily recovered by precipitation and reused without loss of activity.
Co-reporter:Sarah A. Kavanagh, Alessandro Piccinini, Eimear M. Fleming and Stephen J. Connon
Organic & Biomolecular Chemistry 2008 vol. 6(Issue 8) pp:1339-1343
Publication Date(Web):05 Mar 2008
DOI:10.1039/B719767E
N,N′-Diarylureas have been shown to efficiently catalyse sulfonium ylide-mediated aldehyde epoxidation reactions for the first time. These processes are of broad scope and can be coupled with a subsequent Cu(II) ion-catalysed Meinwald rearrangement to give an efficient and convenient protocol for aldehyde homologation without intermediate purification.
Co-reporter:StephenJ. Connon Dr.
Angewandte Chemie 2008 Volume 120( Issue 7) pp:1194-1197
Publication Date(Web):
DOI:10.1002/ange.200703879
Co-reporter:StephenJ. Connon Dr.
Angewandte Chemie International Edition 2008 Volume 47( Issue 7) pp:1176-1178
Publication Date(Web):
DOI:10.1002/anie.200703879
Co-reporter:Sarah A. Kavanagh, Stephen J. Connon
Tetrahedron: Asymmetry 2008 Volume 19(Issue 12) pp:1414-1417
Publication Date(Web):30 June 2008
DOI:10.1016/j.tetasy.2008.05.029
N-Alkyl salts derived from ephedrine have twice been reported to act as chiral phase-transfer catalysts in Corey–Chaykovsky reactions between sulfonium ylides and benzaldehyde; reportedly furnishing the terminal epoxide product in moderate–excellent enantiomeric excess. This study unequivocally demonstrates that these reactions proceed without measurable stereoinduction and explains how previous studies mistakenly attributed product optical activity to asymmetric catalysis.(1R,2R)-1,2-Epoxy-1-phenyl-propaneC9H10OAbsolute configuration: (1R,2R)[α]D20=+64.6 (c 0.71)
Co-reporter:Barbara Procuranti and Stephen J. Connon
Chemical Communications 2007 (Issue 14) pp:1421-1423
Publication Date(Web):30 Jan 2007
DOI:10.1039/B618792G
A new class of bifunctional organocatalyst promotes the chemoselective reduction of diketone electrophiles at catalytic loadings in the presence of an inorganic co-reductant.
Co-reporter:Stephen J. Connon
Organic & Biomolecular Chemistry 2007 vol. 5(Issue 21) pp:3407-3417
Publication Date(Web):11 Sep 2007
DOI:10.1039/B711499K
Catalytic asymmetric reduction reactions have long been the preserve of the transition metal catalyst. Inspired by the myriad efficient enzyme-catalysed reduction reactions routine in biological systems, chemists have recently begun to design chiral metal-free organocatalysts that employ synthetic dihydropyridine NADH analogues as the hydride source with impressive results. Recent developments in this burgeoning field are discussed.
Co-reporter:Ciarán Ó Dálaigh;Serena A. Corr;Yurii Gun'ko Dr.;Stephen J. Connon Dr.
Angewandte Chemie 2007 Volume 119(Issue 23) pp:
Publication Date(Web):2 MAY 2007
DOI:10.1002/ange.200605216
Schnell wieder zur Hand: Der erste Organokatalysator auf magnetischen Nanopartikeln als Träger wurde hergestellt. Der Heterogenkatalysator unterstützt eine Vielzahl an nucleophilen Reaktionen und kann einfach mithilfe eines externen Magneten zurückgewonnen werden (siehe Bild). Außerdem kann er über 30-mal ohne Aktivitätsverlust wiederverwendet werden.
Co-reporter:Ciarán Ó Dálaigh;Serena A. Corr;Yurii Gun'ko Dr.;Stephen J. Connon Dr.
Angewandte Chemie International Edition 2007 Volume 46(Issue 23) pp:
Publication Date(Web):2 MAY 2007
DOI:10.1002/anie.200605216
Quick recovery: The first magnetic-nanoparticle-supported organocatalyst is prepared. The heterogeneous catalyst promotes a range of nucleophilic reactions and can be recovered by exposure to an external magnet (see picture). Furthermore, it can be recycled over 30 times without loss of activity.
Co-reporter:Ciarán Ó. Dálaigh, Stephen J. Hynes, John E. O'Brien, Thomas McCabe, Declan J. Maher, Graeme W. Watson and Stephen J. Connon
Organic & Biomolecular Chemistry 2006 vol. 4(Issue 14) pp:2785-2793
Publication Date(Web):20 Jun 2006
DOI:10.1039/B604632K
The development of a new class of chiral 4-N,N-dialkylaminopyridine acyl-transfer catalysts capable of exploiting both van der Waals (π) and H-bonding interactions to allow remote chiral information to stereochemically control the kinetic resolution of sec-alcohols with moderate to excellent selectivity (s = 6–30). Catalysts derived from (S)-α,α-diarylprolinol are considerably superior to analogues devoid of a tertiary hydroxyl moiety and possess high activity and selectivity across a broad range of substrates.
Co-reporter:Stephen J. Connon Dr.
Angewandte Chemie International Edition 2006 Volume 45(Issue 24) pp:
Publication Date(Web):24 MAY 2006
DOI:10.1002/anie.200600529
Loaded with potential: The enormous potential of chiral phosphoric acids (see formulae) as promoters of novel, highly enantioselective addition reactions to imines under mild conditions has recently been recognized. The use of such catalysts has brought about the development of a number of new asymmetric reactions for the synthesis of amine-based chiral building blocks.
Co-reporter:Stephen J. Connon Dr.
Angewandte Chemie 2006 Volume 118(Issue 24) pp:
Publication Date(Web):24 MAY 2006
DOI:10.1002/ange.200600529
Hohes Potenzial: Chirale Phosphorsäuren (siehe Formeln) bieten exzellente Möglichkeiten als Katalysatoren für hoch enantioselektive Additionen an Imine unter milden Reaktionsbedingungen. Einige aufsehenerregende asymmetrische Reaktionen in Gegenwart dieser Katalystoren zur Herstellung chiraler Aminderivate werden betrachtet.
Co-reporter:Stephen J. Connon Dr.
Chemistry - A European Journal 2006 Volume 12(Issue 21) pp:
Publication Date(Web):3 MAR 2006
DOI:10.1002/chem.200501076
Over the last decade the potential for N,N-dialkyl(thio)urea derivatives to serve as active metal-free organocatalysts for a wide range of synthetically useful reactions susceptible to the influence of general acid catalysis has begun to be realised. This article charts the development of these catalysts (with emphasis on the design principles involved), from early “proof-of-concept” materials to contemporary active chiral (bifunctional) promoters of highly selective asymmetric transformations.
Co-reporter:Julie E. Murtagh, Séamus H. McCooey and Stephen J. Connon
Chemical Communications 2005 (Issue 2) pp:227-229
Publication Date(Web):26 Nov 2004
DOI:10.1039/B414895A
Substoichiometric loadings of DBU catalyse the efficient 1,4-addition of alcohols and non-nucleophilic amines such as pyrrole to activated alkenes; the application of this methodology in a one-pot synthesis of a natural product, and as a novel strategy for the synthesis of mono-protected 1,3-carbonyl compounds is reported.
Co-reporter:Ciarán Ó Dálaigh, Stephen J. Hynes, Declan J. Maher and Stephen J. Connon
Organic & Biomolecular Chemistry 2005 vol. 3(Issue 6) pp:981-984
Publication Date(Web):2005/02/10
DOI:10.1039/B419335K
We report the development of a new class of readily prepared chiral 4-(pyrrolidino)-pyridine catalysts capable of exploiting both van der Waals (π) and H-bonding interactions, thus allowing remote chiral information to stereochemically control the kinetic resolution of sec-alcohols.
Co-reporter:Séamus H. McCooey,Stephen J. Connon
Angewandte Chemie International Edition 2005 44(39) pp:6367-6370
Publication Date(Web):
DOI:10.1002/anie.200501721
Co-reporter:Séamus H. McCooey Dr.
Angewandte Chemie 2005 Volume 117(Issue 39) pp:
Publication Date(Web):1 SEP 2005
DOI:10.1002/ange.200501721
Verkehrte Welt: Neuartige N-Aryl-Harnstoff- und N-Aryl-Thioharnstoffderivate von Dihydrocinchona-Alkaloiden katalysieren effizient die asymmetrische Addition von Dimethylmalonat an Nitroalkene. Die Aktivität und Selektivität der Katalysatoren hängt stark von der relativen Konfiguration an C8/C9 ab: Bereits in Konzentrationen von 0.5 Mol-% ergaben die Katalysatoren mit der „nichtnatürlichen“ Konfiguration an C9 hervorragende Aktivitäten und Enantioselektivitäten.
Co-reporter:Francesco Manoni, Umar Farid, Cristina Trujillo and Stephen J. Connon
Organic & Biomolecular Chemistry 2017 - vol. 15(Issue 6) pp:NaN1474-1474
Publication Date(Web):2017/01/23
DOI:10.1039/C6OB02637K
The first examples of asymmetric Tamura cycloaddition reactions involving singly activated alkenes are reported. Homophthalic anhydride reacts with α-methyl nitrosytrenes in the presence of an alkaloid-based catalyst to generate fused bicyclic aromatic ketone products with three new stereocentres (which are susceptible to subsequent equilibration) in 12–99% ee. An unusual equilibration process which occurs in methanolic medium in the absence of a recognisable base via proton transfer at the α-carbon of an ester was investigated experimentally and computationally.
Co-reporter:Lauren Myles, Nicholas Gathergood and Stephen J. Connon
Chemical Communications 2013 - vol. 49(Issue 46) pp:NaN5318-5318
Publication Date(Web):2013/05/03
DOI:10.1039/C3CC41588K
The ability of triazolium salts to serve as a precatalyst for both an acid and a powerful base/nucleophile (controlled by additives) has been exploited in a process characterised by a unique in situ catalyst modification strategy.
Co-reporter:Cormac Quigley, Zaida Rodríguez-Docampo and Stephen J. Connon
Chemical Communications 2012 - vol. 48(Issue 10) pp:NaN1445-1445
Publication Date(Web):2011/09/06
DOI:10.1039/C1CC14684J
We report the design and evaluation of a library of chiral bifunctional organocatalysts in which the distance between the catalytically active units can be systematically varied.
Co-reporter:Carole Palacio and Stephen J. Connon
Chemical Communications 2012 - vol. 48(Issue 23) pp:NaN2851-2851
Publication Date(Web):2012/02/10
DOI:10.1039/C2CC17965B
A new bifunctional C-5′ substituted cinchona alkaloid-based catalyst promotes the first highly enantioselective additions of alkyl thiols to nitrostyrenes.
Co-reporter:Alessandro Piccinini, Sarah A. Kavanagh and Stephen J. Connon
Chemical Communications 2012 - vol. 48(Issue 63) pp:NaN7816-7816
Publication Date(Web):2012/07/02
DOI:10.1039/C2CC32101G
The highly efficient asymmetric epoxidation of aldehydes by methylene transfer is now possible using new sulfonium salts.
Co-reporter:Francesco Manoni, Claudio Cornaggia, James Murray, Sean Tallon and Stephen J. Connon
Chemical Communications 2012 - vol. 48(Issue 52) pp:NaN6504-6504
Publication Date(Web):2012/05/23
DOI:10.1039/C2CC32147E
A new, highly enantio- and diastereoselective catalytic asymmetric formal cycloaddition of aryl succinic anhydrides and aldehydes which generates paraconic acid (γ-butyrolactone) derivatives is reported.
Co-reporter:Barbara Procuranti and Stephen J. Connon
Chemical Communications 2007(Issue 14) pp:NaN1423-1423
Publication Date(Web):2007/01/30
DOI:10.1039/B618792G
A new class of bifunctional organocatalyst promotes the chemoselective reduction of diketone electrophiles at catalytic loadings in the presence of an inorganic co-reductant.
Co-reporter:Christopher A. Rose, Sivaji Gundala, Claire-Louise Fagan, Johannes F. Franz, Stephen J. Connon and Kirsten Zeitler
Chemical Science (2010-Present) 2012 - vol. 3(Issue 3) pp:NaN740-740
Publication Date(Web):2011/12/12
DOI:10.1039/C2SC00622G
It has been shown for the first time that relatively electron deficient triazolium pre-catalysts promote (at low loadings in the presence of base) highly chemoselective crossed acyloin condensation reactions between aldehydes and α-ketoesters to afford densely functionalized products incorporating a quaternary stereocentre of considerable synthetic potential. Hydroacylation pathways which have hitherto been dominant in these reactions can be completely avoided. The scope of the process is extraordinarily broad with respect to both coupling partners, and a preliminary study has established the principle that a high degree of stereochemical control over the reaction can also be exercised via the use of a chiral NHC precursor. It has also been shown for the first time that coupling of benzyl α-ketoesters with aldehydes followed by acylation and simple hydrogenolysis furnishes a product formally derived from the chemoselective 1:1 coupling of two different aliphatic aldehydes in high yield with absolute control over which coupling partner behaves as the acyl-anion equivalent.
Co-reporter:Claudio Cornaggia, Sivaji Gundala, Francesco Manoni, Nagaraju Gopalasetty and Stephen J. Connon
Organic & Biomolecular Chemistry 2016 - vol. 14(Issue 11) pp:NaN3046-3046
Publication Date(Web):2016/02/18
DOI:10.1039/C6OB00089D
It has been shown for the first time that enolisable anhydrides can participate in highly efficient and diastereo/enantioselective additions to activated ketones. In these reactions the anhydride component formally acts (initially) as the nucleophilic component. These processes are promoted by novel, readily prepared urea-substituted cinchona alkaloid-derived catalysts at low loadings under mild conditions. Three classes of enolisable anhydride and three different types of activated ketone were shown to be compatible with the process – generating a diverse range of structurally distinct and densely functionalised lactone products with the formation of two new stereocentres, one of which is quaternary. In one example, a product incorporating two contiguous quaternary stereocentres (one all carbon) was formed with outstanding enantiocontrol. It has been shown in the case of glutaconic anhydride derivatives that the cycloaddtion process is reversible, and can be accompanied by decarboxylation and olefin isomerisation. Reaction conditions can be modified to give access to three types of product with good–excellent ee.
Co-reporter:Sarah A. Cronin, Aarón Gutiérrez Collar, Sivaji Gundala, Claudio Cornaggia, Esther Torrente, Francesco Manoni, Astrid Botte, Brendan Twamley and Stephen J. Connon
Organic & Biomolecular Chemistry 2016 - vol. 14(Issue 29) pp:NaN6959-6959
Publication Date(Web):2016/07/06
DOI:10.1039/C6OB00048G
The first catalytic, asymmetric reactions of imines with homophthalic anhydride to form disubstituted 3,4-dihydroisoquinolones are reported. The use of N-mesyl aldimines is key, as more basic imines undergo rapid uncatalysed reactions, while imines possessing larger N-sulphonyl substituents form lactams with lower ee.
Co-reporter:Sarah A. Kavanagh, Alessandro Piccinini and Stephen J. Connon
Organic & Biomolecular Chemistry 2013 - vol. 11(Issue 21) pp:NaN3540-3540
Publication Date(Web):2013/04/18
DOI:10.1039/C3OB27271K
A new ylide-based protocol for the asymmetric aziridination of imines via methylene transfer has been developed involving the use of a simple chiral sulfonium salt and an organic strong base. A systematic study identified triisopropylphenyl sulfonylimines as optimal substrates for the process. Unexpectedly, hindered C2-symmetric sulfonyl salts incorporating bulky ethers at C-2 and C-5 – which had previously been useful in the corresponding epoxidation chemistry – decomposed in these aziridination reactions via competing elimination pathways. Under optimised conditions it was found that a simple salt derived from (2R,5R)-2,5-diisopropyl thiolane could mediate asymmetric methylene transfer to a range of imines with uniformly excellent yields with 19–30% ee. Since this is a similar level of enantiomeric excess to that obtained using these same salts in epoxidation chemistry, it was concluded that if more bulky sulfonium salts could be devised which were resistant to decomposition under the reaction conditions, that highly enantioselective aziridine formation by methylene transfer would be possible.
Co-reporter:Sarah E. O'Toole and Stephen J. Connon
Organic & Biomolecular Chemistry 2009 - vol. 7(Issue 17) pp:NaN3593-3593
Publication Date(Web):2009/07/10
DOI:10.1039/B908517C
The design of a new class of triazolium ion precatalysts incorporating protic substituents is described. These materials promote the enantioselective benzoin condensation of a range of aromatic aldehydes (1–62% ee). Catalyst evaluation studies strongly support the involvement of hydrogen bond donation by the catalyst in the stereocentre-forming step of the catalytic cycle.
Co-reporter:Sarah A. Kavanagh, Alessandro Piccinini, Eimear M. Fleming and Stephen J. Connon
Organic & Biomolecular Chemistry 2008 - vol. 6(Issue 8) pp:NaN1343-1343
Publication Date(Web):2008/03/05
DOI:10.1039/B719767E
N,N′-Diarylureas have been shown to efficiently catalyse sulfonium ylide-mediated aldehyde epoxidation reactions for the first time. These processes are of broad scope and can be coupled with a subsequent Cu(II) ion-catalysed Meinwald rearrangement to give an efficient and convenient protocol for aldehyde homologation without intermediate purification.
Co-reporter:Stephen J. Connon
Organic & Biomolecular Chemistry 2007 - vol. 5(Issue 21) pp:NaN3417-3417
Publication Date(Web):2007/09/11
DOI:10.1039/B711499K
Catalytic asymmetric reduction reactions have long been the preserve of the transition metal catalyst. Inspired by the myriad efficient enzyme-catalysed reduction reactions routine in biological systems, chemists have recently begun to design chiral metal-free organocatalysts that employ synthetic dihydropyridine NADH analogues as the hydride source with impressive results. Recent developments in this burgeoning field are discussed.
Co-reporter:Oliver Gleeson, Gemma-Louise Davies, Aldo Peschiulli, Renata Tekoriute, Yurii K. Gun'ko and Stephen J. Connon
Organic & Biomolecular Chemistry 2011 - vol. 9(Issue 22) pp:NaN7940-7940
Publication Date(Web):2011/10/11
DOI:10.1039/C1OB06110K
A systematic study concerning the immobilisation onto magnetic nanoparticles of three useful classes of chiral organocatalyst which rely on a confluence of weak, easily perturbed van der Waals and hydrogen bonding interactions to promote enantioselective reactions has been undertaken for the first time. The catalysts were evaluated in three different synthetically useful reaction classes: the kinetic resolution of sec-alcohols, the conjugate addition of dimethyl malonate to a nitroolefin and the desymmetrisation of meso anhydrides. A chiral bifunctional 4-N,N-dialkylaminopyridine derivative could be readily immobilised; the resulting heterogeneous catalyst is highly active and is capable of promoting the kinetic resolution of sec-alcohols with synthetically useful selectivity under process-scale friendly conditions and has been demonstrated to be reusable in a minimum of 32 consecutive cycles. The immobilisation of a cinchona alkaloid-derived urea-substituted catalyst proved considerably less successful in terms of both catalyst stability and product levels of enantiomeric excess. An immobilised cinchona alkaloid-derived sulfonamide catalyst was also prepared, with mixed results: the catalyst exhibits outstanding recyclability on a par with that associated with the successful N,N-dialkylaminopyridine analogue, however product enantiomeric excess is consistently lower than that obtained using the corresponding homogeneous catalyst. While no physical deterioration of the heterogeneous catalysts was detected on analysis after multiple recycles, in the cases of both the conjugate addition to nitroolefins and the desymmetrisation of meso anhydrides, significant levels of background catalysis by the nanoparticles in the absence of the organocatalyst was detected, which explains in part the poor performance of the immobilised organocatalysts in these reactions from a stereoselectivity standpoint. It seems clear that the immobilisation of sensitive chiral organocatalysts onto magnetite nanoparticles does not always result in heterogeneous catalysts with acceptable activity and selectivity profiles, and that consequently the applicability of the strategy must be ascertained (until more data is available) on a case-by-case basis.
Co-reporter:Eoghan G. Delany, Claire-Louise Fagan, Sivaji Gundala, Kirsten Zeitler and Stephen J. Connon
Chemical Communications 2013 - vol. 49(Issue 58) pp:NaN6515-6515
Publication Date(Web):2013/06/14
DOI:10.1039/C3CC42597E
Benzoin (and neither the Breslow intermediate nor the NHC–aldehyde tetrahedral adduct) has been unambiguously identified as the oxidised species in aerobic NHC-catalysed aldehyde esterifications.
Co-reporter:Eoghan G. Delany, Claire-Louise Fagan, Sivaji Gundala, Alessandra Mari, Thomas Broja, Kirsten Zeitler and Stephen J. Connon
Chemical Communications 2013 - vol. 49(Issue 58) pp:NaN6512-6512
Publication Date(Web):2013/06/14
DOI:10.1039/C3CC42596G
A highly efficient, broad scope, additive-free mild protocol for the oxidative carbene-catalysed esterification of aldehydes (including the related aqueous oxidation to acids) has been developed.
![5(4H)-Oxazolone, 4-methyl-2-[4-(trifluoromethyl)phenyl]-](/data/chemimg/3721500/1361143-04-5.png)
![5(4H)-Oxazolone, 4-methyl-2-[4-(trifluoromethyl)phenyl]-](/data/chemimg/3721500/1361143-04-5_b.png)
![Pyrrolidine, 1-[[4-(1-pyrrolidinyl)-3-pyridinyl]carbonyl]-](http://img.cochemist.com/ccimg/851100/851010-80-5.png)
![Pyrrolidine, 1-[[4-(1-pyrrolidinyl)-3-pyridinyl]carbonyl]-](http://img.cochemist.com/ccimg/851100/851010-80-5_b.png)
![Pyridine, 2-chloro-4-[(trimethylsilyl)methyl]-](http://img.cochemist.com/ccimg/778000/777931-65-4.png)
![Pyridine, 2-chloro-4-[(trimethylsilyl)methyl]-](http://img.cochemist.com/ccimg/778000/777931-65-4_b.png)
![Alanine, N-[4-(trifluoromethyl)benzoyl]-, methyl ester](http://img.cochemist.com/ccimg/591800/591774-62-8.png)
![Alanine, N-[4-(trifluoromethyl)benzoyl]-, methyl ester](http://img.cochemist.com/ccimg/591800/591774-62-8_b.png)
![Propanedioic acid, [1-(4-methoxyphenyl)propyl]-, dimethyl ester, rel-(+)-](http://img.cochemist.com/ccimg/761500/761434-49-5.png)
![Propanedioic acid, [1-(4-methoxyphenyl)propyl]-, dimethyl ester, rel-(+)-](http://img.cochemist.com/ccimg/761500/761434-49-5_b.png)
![Propanedioic acid, [1-(4-bromophenyl)propyl]-, dimethyl ester, rel-(+)-](http://img.cochemist.com/ccimg/761500/761434-43-9.png)
![Propanedioic acid, [1-(4-bromophenyl)propyl]-, dimethyl ester, rel-(+)-](http://img.cochemist.com/ccimg/761500/761434-43-9_b.png)
![5(4H)-Oxazolone, 4-[2-(methylthio)ethyl]-2-phenyl-](/data/chemimg/3224100/51127-20-9.png)
![5(4H)-Oxazolone, 4-[2-(methylthio)ethyl]-2-phenyl-](/data/chemimg/3224100/51127-20-9_b.png)
![L-Valine, N-[4-(trifluoromethyl)benzoyl]-, methyl ester](http://img.cochemist.com/ccimg/497200/497156-72-6.png)
![L-Valine, N-[4-(trifluoromethyl)benzoyl]-, methyl ester](http://img.cochemist.com/ccimg/497200/497156-72-6_b.png)
![Ethanethioic acid, S-[[4-(1,1-dimethylethyl)phenyl]methyl] ester](http://img.cochemist.com/ccimg/362600/362528-98-1.png)
![Ethanethioic acid, S-[[4-(1,1-dimethylethyl)phenyl]methyl] ester](http://img.cochemist.com/ccimg/362600/362528-98-1_b.png)
![Oxirane, [(1E)-2-phenylethenyl]-](http://img.cochemist.com/ccimg/89400/89368-01-4.png)
![Oxirane, [(1E)-2-phenylethenyl]-](http://img.cochemist.com/ccimg/89400/89368-01-4_b.png)
![Propanedioic acid, [(1S)-2-nitro-1-phenylethyl]-, dimethyl ester](http://img.cochemist.com/ccimg/252400/252338-26-4.png)
![Propanedioic acid, [(1S)-2-nitro-1-phenylethyl]-, dimethyl ester](http://img.cochemist.com/ccimg/252400/252338-26-4_b.png)
![Urea, N-1-azabicyclo[2.2.2]oct-3-yl-N'-[3,5-bis(trifluoromethyl)phenyl]-](http://img.cochemist.com/ccimg/674400/674310-55-5.png)
![Urea, N-1-azabicyclo[2.2.2]oct-3-yl-N'-[3,5-bis(trifluoromethyl)phenyl]-](http://img.cochemist.com/ccimg/674400/674310-55-5_b.png)
![CYCLOHEXANE, [(1E)-2-NITRO-1-PROPENYL]-](http://img.cochemist.com/ccimg/126500/126416-08-8.png)
![CYCLOHEXANE, [(1E)-2-NITRO-1-PROPENYL]-](http://img.cochemist.com/ccimg/126500/126416-08-8_b.png)
![Magnesium, bromo[1,1':3',1''-terphenyl]-5'-yl-](http://img.cochemist.com/ccimg/247600/247575-72-0.png)
![Magnesium, bromo[1,1':3',1''-terphenyl]-5'-yl-](http://img.cochemist.com/ccimg/247600/247575-72-0_b.png)
![4-Pyridinamine, N-methyl-N-[3-(triethoxysilyl)propyl]-](http://img.cochemist.com/ccimg/128900/128823-45-0.png)
![4-Pyridinamine, N-methyl-N-[3-(triethoxysilyl)propyl]-](http://img.cochemist.com/ccimg/128900/128823-45-0_b.png)
![PYRANO[4,3-B]PYRROLE-4,6-DIONE, 1,7-DIHYDRO-1,3-DIMETHYL-](http://img.cochemist.com/ccimg/86900/86814-97-3.png)
![PYRANO[4,3-B]PYRROLE-4,6-DIONE, 1,7-DIHYDRO-1,3-DIMETHYL-](http://img.cochemist.com/ccimg/86900/86814-97-3_b.png)
![1,4-DIOXASPIRO[4.5]DEC-7-ENE-7-ACETIC ACID, 8-CARBOXY-](http://img.cochemist.com/ccimg/90500/90473-46-4.png)
![1,4-DIOXASPIRO[4.5]DEC-7-ENE-7-ACETIC ACID, 8-CARBOXY-](http://img.cochemist.com/ccimg/90500/90473-46-4_b.png)
![BICYCLO[2.2.1]HEPT-5-ENE-2,3-DICARBOXYLIC ACID, 2-METHYL ESTER, (1R,2S,3R,4S)-](http://img.cochemist.com/ccimg/96300/96243-74-2.png)
![BICYCLO[2.2.1]HEPT-5-ENE-2,3-DICARBOXYLIC ACID, 2-METHYL ESTER, (1R,2S,3R,4S)-](http://img.cochemist.com/ccimg/96300/96243-74-2_b.png)
![L-ALANINE, N-[N-[(1,1-DIMETHYLETHOXY)CARBONYL]-L-SERYL]-, METHYL ESTER](http://img.cochemist.com/ccimg/39800/39747-66-5.png)
![L-ALANINE, N-[N-[(1,1-DIMETHYLETHOXY)CARBONYL]-L-SERYL]-, METHYL ESTER](http://img.cochemist.com/ccimg/39800/39747-66-5_b.png)
![Naphthalene, 1-[(1E)-2-nitroethenyl]-](http://img.cochemist.com/ccimg/37700/37630-26-5.png)
![Naphthalene, 1-[(1E)-2-nitroethenyl]-](http://img.cochemist.com/ccimg/37700/37630-26-5_b.png)
![5(4H)-OXAZOLONE, 4-(1-METHYLETHYL)-2-[4-(TRIFLUOROMETHYL)PHENYL]-](http://img.cochemist.com/ccimg/591800/591774-74-2.png)
![5(4H)-OXAZOLONE, 4-(1-METHYLETHYL)-2-[4-(TRIFLUOROMETHYL)PHENYL]-](http://img.cochemist.com/ccimg/591800/591774-74-2_b.png)
![L-VALINE, N-[4-(TRIFLUOROMETHYL)BENZOYL]-](http://img.cochemist.com/ccimg/841400/841303-81-9.png)
![L-VALINE, N-[4-(TRIFLUOROMETHYL)BENZOYL]-](http://img.cochemist.com/ccimg/841400/841303-81-9_b.png)
![Bicyclo[2.2.1]hept-5-ene-2,3-dicarboxylic acid, monomethyl ester, (1S,2R,3S,4R)-](/data/chemimg/2073600/96243-73-1.png)
![Bicyclo[2.2.1]hept-5-ene-2,3-dicarboxylic acid, monomethyl ester, (1S,2R,3S,4R)-](/data/chemimg/2073600/96243-73-1_b.png)
![L-Alanine, N-[4-(trifluoromethyl)benzoyl]-](http://img.cochemist.com/ccimg/214700/214629-16-0.png)
![L-Alanine, N-[4-(trifluoromethyl)benzoyl]-](http://img.cochemist.com/ccimg/214700/214629-16-0_b.png)
![Pyridine,2-[(1E)-2-nitroethenyl]-(9CI)](http://img.cochemist.com/ccimg/100500/100446-36-4.png)
![Pyridine,2-[(1E)-2-nitroethenyl]-(9CI)](http://img.cochemist.com/ccimg/100500/100446-36-4_b.png)
![Benzaldehyde, 2-[[(4-methylphenyl)sulfonyl]oxy]-](http://img.cochemist.com/ccimg/19900/19820-56-5.png)
![Benzaldehyde, 2-[[(4-methylphenyl)sulfonyl]oxy]-](http://img.cochemist.com/ccimg/19900/19820-56-5_b.png)
![1,5-dithiaspiro[5.5]undecane](http://img.cochemist.com/ccimg/200/180-96-1.png)
![1,5-dithiaspiro[5.5]undecane](http://img.cochemist.com/ccimg/200/180-96-1_b.png)
![N-[3,5-Bis(trifluoromethyl)phenyl]-N′-[(8a,9S)-10,11-dihydro-6′-methoxy-9-cinchonanyl]thiourea](/data/chemimg/1588800/852913-19-0.png)
![N-[3,5-Bis(trifluoromethyl)phenyl]-N′-[(8a,9S)-10,11-dihydro-6′-methoxy-9-cinchonanyl]thiourea](/data/chemimg/1588800/852913-19-0_b.png)
![1-chloro-4-[(1E)-2-nitroprop-1-en-1-yl]benzene](http://img.cochemist.com/ccimg/37700/37629-52-0.png)
![1-chloro-4-[(1E)-2-nitroprop-1-en-1-yl]benzene](http://img.cochemist.com/ccimg/37700/37629-52-0_b.png)
![Benzene, [(1E)-3,3-dimethoxy-1-propenyl]-](http://img.cochemist.com/ccimg/63600/63511-93-3.png)
![Benzene, [(1E)-3,3-dimethoxy-1-propenyl]-](http://img.cochemist.com/ccimg/63600/63511-93-3_b.png)
![Aziridine, 1-[(4-methylphenyl)sulfonyl]-2-phenyl-, (R)-](http://img.cochemist.com/ccimg/62600/62596-62-7.png)
![Aziridine, 1-[(4-methylphenyl)sulfonyl]-2-phenyl-, (R)-](http://img.cochemist.com/ccimg/62600/62596-62-7_b.png)
![[1,1'-Biphenyl]-2,2'-dicarboxylicacid, 2,2'-dimethyl ester](http://img.cochemist.com/ccimg/5900/5807-64-7.png)
![[1,1'-Biphenyl]-2,2'-dicarboxylicacid, 2,2'-dimethyl ester](http://img.cochemist.com/ccimg/5900/5807-64-7_b.png)
![L-Serine, N-[(1,1-dimethylethoxy)carbonyl]-, (4-nitrophenyl)methyl ester](/data/chemimg/1154200/16938-11-7.png)
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![Propanedioic acid, [(1R)-2-nitro-1-phenylethyl]-, dimethyl ester](http://img.cochemist.com/ccimg/773200/773148-47-3_b.png)
![Aziridine,1-[(4-methylphenyl)sulfonyl]-2-phenyl-](http://img.cochemist.com/ccimg/24400/24395-14-0.png)
![Aziridine,1-[(4-methylphenyl)sulfonyl]-2-phenyl-](http://img.cochemist.com/ccimg/24400/24395-14-0_b.png)
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![[(3E)-4-nitropent-3-en-1-yl]benzene](http://img.cochemist.com/ccimg/138700/138668-14-1_b.png)
![1-Oxaspiro[2.5]octane](http://img.cochemist.com/ccimg/200/185-70-6.png)
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![3-[HYDROXY(PHENYL)METHYL]BUT-3-EN-2-ONE](http://img.cochemist.com/ccimg/73300/73255-39-7_b.png)
![6-PHENYL-1-OXASPIRO[2.5]OCTANE](http://img.cochemist.com/ccimg/2900/2815-37-4.png)
![6-PHENYL-1-OXASPIRO[2.5]OCTANE](http://img.cochemist.com/ccimg/2900/2815-37-4_b.png)
![1-methyl-2-[(e)-2-nitrovinyl]benzene](http://img.cochemist.com/ccimg/28700/28638-59-7.png)
![1-methyl-2-[(e)-2-nitrovinyl]benzene](http://img.cochemist.com/ccimg/28700/28638-59-7_b.png)
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![N-[(2,6-DICHLOROPHENYL)SULFONYL]ALANINE](http://img.cochemist.com/ccimg/3900/3898-66-6.png)
![N-[(2,6-DICHLOROPHENYL)SULFONYL]ALANINE](http://img.cochemist.com/ccimg/3900/3898-66-6_b.png)
![7,12-dihydroindolo[3,2-d][1]benzazepin-6(5H)-one](http://img.cochemist.com/ccimg/142300/142273-18-5.png)
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![[2,2'-Bipyridine]-3,3'-dicarboxylic acid, 3,3'-dimethyl ester](/data/chemimg/567300/39775-31-0_b.png)
![3,3-BIS(METHYLSULFANYL)-1-[3-(TRIFLUOROMETHYL)PHENYL]PROP-2-EN-1-ONE](http://img.cochemist.com/ccimg/41300/41246-22-4.png)
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![Diselenide, bis[3-(trifluoromethyl)phenyl]](http://img.cochemist.com/ccimg/54000/53973-75-4.png)
![Diselenide, bis[3-(trifluoromethyl)phenyl]](http://img.cochemist.com/ccimg/54000/53973-75-4_b.png)
![6-tert-butyl-1-oxaspiro[2.5]octane](http://img.cochemist.com/ccimg/2900/2815-45-4.png)
![6-tert-butyl-1-oxaspiro[2.5]octane](http://img.cochemist.com/ccimg/2900/2815-45-4_b.png)
![3-Cyclobutene-1,2-dione, 3-[[3,5-bis(trifluoromethyl)phenyl]amino]-4-methoxy-](/data/chemimg/144700/1223105-85-8.png)
![3-Cyclobutene-1,2-dione, 3-[[3,5-bis(trifluoromethyl)phenyl]amino]-4-methoxy-](/data/chemimg/144700/1223105-85-8_b.png)
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![2-[(1e)-2-nitro-1-propen-1-yl]fur](http://img.cochemist.com/ccimg/134600/134538-48-0_b.png)
![Indolo[3,2-d][1]benzazepin-6(5H)-one,9-bromo-7,12-dihydro-](http://img.cochemist.com/ccimg/142300/142273-20-9.png)
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![Cyclohexane, [(1E)-2-nitroethenyl]-](http://img.cochemist.com/ccimg/132900/132839-80-6.png)
![Cyclohexane, [(1E)-2-nitroethenyl]-](http://img.cochemist.com/ccimg/132900/132839-80-6_b.png)
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![[2,2'-Binaphthalene]-1,1'-diol, (1R)-](http://img.cochemist.com/ccimg/122600/122531-87-7_b.png)
![1,3-Bis[3,5-bis(trifluoromethyl)phenyl]thiourea](/data/chemimg/315700/1060-92-0.png)
![1,3-Bis[3,5-bis(trifluoromethyl)phenyl]thiourea](/data/chemimg/315700/1060-92-0_b.png)
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