Computer-Aided Insight into the Relative Stability of Enamines

 

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Dedicated to Pere Mir, in memoriam

Abstract

Venerable aldol, Michael, and Mannich reactions have undergone a renaissance in the past fifteen years, as a consequence of the development of direct organocatalytic versions, mediated by chiral amines. Chiral enamines are key intermediates in these reactions. This review focuses on the formation of enamines from secondary amines and their relative thermodynamic stability, as well as on the reverse reactions (hydrolysis). Experimental results and predictions based on MO calculations are reviewed to show which enamine forms may predominate in the reaction medium and to compare several secondary amines as organocatalysts.

1 Introduction

2 Relative Stability of Enamines as Determined Experimentally

3 Pyrrolidine Enamines

4 Enamines of the Jørgensen–Hayashi Catalyst

5 Proline Enamines

6 Free Enthalpies and Polar Solvent Effects

7 Comparison of Organocatalysts

8 Summary and Outlook

9 Appendix

• References


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• 29e Triandafillidi I. Bisticha A. Voutyritsa E. Galiatsatou G. Kokotos CG. Tetrahedron 2015; 71: 932
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• 30a With the J–H catalyst, the related values, in kcal/mol, are as follows: propanedial, ΔE –19.7, ΔG ^ѳ –18.6, ΔG ^ѳ(DMSO) –20.5, ΔG ^ѳ(H₂O) –22.1; PhCH₂CHO, ΔE –10.3, ΔG ^ѳ –10.4, ΔG ^ѳ(DMSO) –12.8, ΔG ^ѳ(H₂O) –12.7; Me₂CHCH₂CHO, ΔE –5.0, ΔG ^ѳ –5.6, ΔG ^ѳ(DMSO) –7.3, ΔG ^ѳ(H₂O) –6.6; Me₃CCOMe, enamine ap, ΔE 6.3, ΔG ^ѳ 7.4, ΔG ^ѳ(DMSO) 7.5, ΔG ^ѳ(H₂O) 7.6; Me₃CCOMe, sc-exo, ΔE 10.3, ΔG ^ѳ 11.4, ΔG ^ѳ(DMSO) 10.5, ΔG ^ѳ (H₂O) 9.9.
• 30b With Pro, the values are as follows: propanedial, CO₂H s-cis, ΔE –11.5, ΔG ^ѳ –13.4, ΔG ^ѳ(DMSO) –13.0, ΔG ^ѳ(H₂O) –15.6; propanedial, s-trans, ΔE –8.7, ΔG ^ѳ –10.4, ΔG ^ѳ(DMSO) –12.6, ΔG ^ѳ(H₂O) –14.3; PhCH₂CHO, s-cis, ΔE –5.5, ΔG ^ѳ –6.7, ΔG ^ѳ(DMSO) –6.4, ΔG ^ѳ(H₂O) –7.6; Me₂CHCH₂CHO, s-trans, ΔE –1.8, ΔG ^ѳ –2.9, ΔG ^ѳ(DMSO) –4.4, ΔG ^ѳ(H₂O) –4.0; EtCHO, s-trans, ΔE –1.1, ΔG ^ѳ –1.6, ΔG ^ѳ(DMSO) –2.7, ΔG ^ѳ(H₂O) –2.5; Me₃CCOMe, s-cis, ΔE 9.4, ΔG ^ѳ 10.6, ΔG ^ѳ(DMSO) 12.3, ΔG ^ѳ(H₂O) 11.2.
• 31a Pyrrolidine-sulfonamide, nitro-Michael: Wang J. Li H. Lou B. Zu L. Guo H. Wang W. Chem. Eur. J. 2006; 12: 4321
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• 31b 5-(Pyrrolidin-2-yl)tetrazole: Arnó M. Zaragozá RJ. Domingo LR. Tetrahedron: Asymmetry 2007; 18: 157
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• 31c Pro-NHSO₂Ar, Mannich: Veverková E. Strasserová J. Sebesta R. Toma S. Tetrahedron: Asymmetry 2010; 21: 58
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• 31d 4-OH-pyrrolidine derivatives, Mannich anti-selective: Gómez-Bengoa E. Maestro M. Mielgo A. Otazo I. Palomo C. Velilla I. Chem. Eur. J. 2010; 16: 5333
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• 31e Pyrrolidine-ureas, nitro-Michael: Cao X.-Y. Zheng J.-C. Li Y.-X. Shu Z.-C. Sun X.-L. Wang B.-Q. Tang Y. Tetrahedron 2010; 66: 9703
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• 31f 2-CHPh₂ and 2-CPh₂OMe, MVK: Patil MP. Sharma AK. Sunoj RB. J. Org. Chem. 2010; 75: 7310
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• 31g Thiaproline: Parasuk W. Parasuk V. Comput. Theor. Chem. 2011; 964: 133
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• 31h Mannich, thiaproline: Parasuk W. Parasuk V. Asian J. Org. Chem. 2013; 2: 85
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• 31i 4-OH-prolinamides, nitro-Michael: Watts J. Luu L. McKee V. Carey E. Kelleher F. Adv. Synth. Catal. 2012; 354: 1035
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• 31j Mannich, 2-(pyrrolidin-1-ylmethyl)pyrrolidine: ref. 26g.
• 31k Pro dipeptides vs. Pro tripeptides, aldol: Szöllösi G. Csámpai A. Somlai C. Fekete M. Bartók M. J. Mol. Catal. A: Chem. 2014; 382: 86
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• 31l Pyrrolidinyl-oxazolecarboxamides: Kamal A. Sathish M. Srinivasulu V. Chetna J. Shekar KC. Nekkanti S. Tangella Y. Shankaraiah N. Org. Biomol. Chem. 2014; 12: 8008
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• 31m Pro-hydrazide, explicit water: Chakrabarty K. Ghosh A. Basak A. Das GK. Comput. Theor. Chem. 2015; 1062: 11
  Crossref
• 31n For a review, see: ref. 26a.

For studies on the nucleophilicity of enamines, see:
• 32a Kempf B. Hampel N. Ofial AR. Mayr H. Chem. Eur. J. 2003; 9: 2209
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• 32b Ref. 4e.