| Literature DB >> 23117425 |
György Keglevich1, Erika Bálint.
Abstract
The Kabachnik-Fields (phospha-Entities:
Mesh:
Substances:
Year: 2012 PMID: 23117425 PMCID: PMC6268146 DOI: 10.3390/molecules171112821
Source DB: PubMed Journal: Molecules ISSN: 1420-3049 Impact factor: 4.411
Scheme 1General scheme for the Kabachnik–Fields reaction.
Scheme 2The “imine” mechanism proposed for a Kabachnik–Fields reaction [15,16].
Scheme 3The “α-hydroxyphosphonate” mechanism proposed for a Kabachnik–Fields reaction [15,17].
Scheme 4The Kabachnik–Fields reaction studied by us.
Scheme 5Possible routes for the Kabachnik–Fields reaction studied by us.
Figure 1Concentration profile for the Kabachnik–Fields reaction studied at 80 °C in acetonitrile.
Scheme 6Another Kabachnik–Fields reaction investigated by us.
Scheme 7Possible pathways for the second model investigated.
Figure 2Concentration profile for the Kabachnik–Fields reaction studied at 80 °C in acetonitrile.
Relative energies for the four states calculated.
| Species | Relative energy (kJ/mol) |
|---|---|
| Reactants (benzaldehyde, cyclohexylamine and dimethyl phosphite) | 0.0 |
| Imine intermediate | –18.6 |
| α-Hydroxyphosphonate intermediate | –40.5 |
| Product | –42.9 |
Scheme 8General scheme for the solventless, catalyst-free MW-assisted Kabachnik–Fields reactions studied.
Kabachnik–Fields reactions carried out without the use of a solvent and a catalyst under MW irradiation [25].
| Entry | R1 | R2 | R3 | Y | Product | T (°C) | Yield (%) | Yield (%) of catalytic methods [ref.] † |
|---|---|---|---|---|---|---|---|---|
| 1 | Ph | H | H | EtO |
| 80 a | 91 | |
|
| 100 b | |||||||
| 2 | Ph | H | H | MeO |
| 80 a | 80 | |
| 80 b | ||||||||
| 3 | Ph | H | H | Ph |
| 80 | 94 | |
| 4 | Bn | H | H | EtO |
| 100 | 81 | |
| 5 | Bn | H | H | Ph |
| 80 | 88 | |
| 6 | Ph | H | Ph | EtO |
| 100 | 93 | 98 [ |
| 7 | Ph | H | Ph | MeO |
| 100 | 86 | 98 [ |
| 8 | Ph | H | Ph | Ph |
| 80 | 87 | |
| 9 | Bn | H | Ph | EtO |
| 100 | 83 | 99 [ |
| 10 | Bn | H | Ph | MeO |
| 100 | 87 | 95 [ |
| 11 | Ph | Me | Ph | EtO |
| 120 | 80 | 75 [ |
| 12 | Bn | Me | Ph | EtO |
| 120 | 84 | 92 [ |
| 13 | Bn | Me | Ph | Ph |
| 100 a | 80 | |
| 120 b | 80 | |||||||
| 14 | Ph | EtO |
| 120 | 81 | 92 [ | ||
| 15 | Bn | EtO |
| 120 | 91 | 85 [ | ||
| 16 | Bn | MeO |
| 120 | 85 | 92 [ | ||
| 17 | Bn | Ph |
| 100 a | 80 | |||
| 120 b |
† for details see Table 3; a condensation of the oxo-component and the amine; b addition of the >P(O)H species to the Schiff-base.
Kabachnik–Fields reactions carried out in the presence of catalysts.
| Catalyst | Solvent | MW/Δ | T [°C] | t | Yield (Product) [%] | Ref. |
|---|---|---|---|---|---|---|
| Phthalocyanine-AlCl | CH2Cl2 | – | 26 a | 12 h | 92 ( | [ |
| Mg(ClO4)2 | – | – | 26 | 2 min/8 h | 90–98 ( | [ |
| Mg(ClO4)2 | – | Δ | 50-80 | 45 min–12 h | 80–99 ( | [ |
| Mg(ClO4)2 | EtOH | Δ | 50 | 5 h/12 h | 85 ( | [ |
| M(OTf)n M = Li, Mg, Al, Cu, Ce | – | Δ | 80 | 20 min–3.5 h | 72–95 ( | [ |
| GaI3 | CH2Cl2 | – | 26 | 3–6 h | 74–92 ( | [ |
| In(OTf)3 | THF | Δ | 66 | 21–35 h | 47–85 ( | [ |
| BiNO3 | – | – b | 26 | 10 h | 93 ( | [ |
| BiCl3 | MeCN | Δ | 80 | 6–15 h | 80–92 ( | [ |
| FeCl3 | EtOH (or solvent free) | – | 26 | ~90 ( | [ | |
| YbCl3 | MeCN | – | 26 | 24 h | 63–96 ( | [ |
| SmI2 (+ 4 Å mol sieves) | MeCN | Δ | 80 | 24 h | 18–92 ( | [ |
| ceric ammonium nitrate | MeCN | – | 26 | 3 h | 86 ( | [ |
| InCl3 | THF | Δ | 66 | 9–12 h | 81–93 ( | [ |
| InCl3 | DMF | MW | no data | 2 min | 82 ( | [ |
| InCl3 | [bmim][PF6] | MW | no data | 2 min | 91 ( | [ |
| Ln(OTf)3 Ln = Yb, Sc, Dy, Sm | DMF | MW | no data | 2 min | 72 (
| [ |
| Ln(OTf)3 Ln = Yb, Sc, Dy, Sm | [bmim][PF6] | – | 26 | 27 h | 92 ( | [ |
| Ln(OTf)3 Ln = Yb, Sc, Dy, Gd | [bmim][PF6] | MW | no data | 2 min | 89 ( | [ |
| the solvent acts as catalyst | [bmim][BF4] | – | 26 | 5 h/8 h | 90 ( | [ |
a Diethyl phosphite was added to preformed imines; b Was also performed under MW; c The product was extracted with benzene.
Scheme 9Kabachnik–Fields reactions applying N-heterocycles as the amine component.
Scheme 10Kabachnik-Fields reactions applying 1,3,2-dioxaphosphorine oxide as the P-reactant.
Scheme 11Synthesis of α-aminophosphonates via the imine intermediate.
Scheme 12Kabachnik–Fields reaction applying a dibenzooxaphosphorine oxide as the P-reactant.
Scheme 13Synthesis of an α-aminophosphonates in two steps.
Scheme 14Synthesis of bis(phosphonomethyl)amines and related derivatives by the double Kabachnik–Fields reaction.
Scheme 15Bis(phosphinoxidomethyl)amines by the double phospha-Mannich reaction.
Scheme 16Synthesis of ring platinum complexes from bis(phosphinoxidomethyl)amines.
Scheme 17Stabilization of a bis(phosphinomethyl)amine as a bis(borane complex).
Scheme 18MW-assisted synthesis of α-hydroxyphosphonates and α-hydroxyphosphine oxides.
Scheme 19Preparation of α-aminophosphonates by substitution of α-hydroxyphosphonates.