Search results
Search for "catch and release" in Full Text gives 9 result(s) in Beilstein Journal of Organic Chemistry.
Anion–π catalysis on carbon allotropes
- M. Ángeles Gutiérrez López,
- Mei-Ling Tan,
- Giacomo Renno,
- Augustina Jozeliūnaitė,
- J. Jonathan Nué-Martinez,
- Javier Lopez-Andarias,
- Naomi Sakai and
- Stefan Matile
Beilstein J. Org. Chem. 2023, 19, 1881–1894, doi:10.3762/bjoc.19.140
- ][86][87][88][89][90][91][92][93][94]. They serve as catch-and-release scaffolds in different variations, and, less frequently, as (photo)redox partners. Although they might contribute to these activities, anion–π interactions have not been considered. Anion–π catalysis on carbon nanotubes has been
Graphical Abstract
Figure 1: (A) Anion–π catalysis: Stabilization of anionic transition states from substrate S to product P on ...
Figure 2: Bioinspired enolate addition chemistry to benchmark anion–π catalysts: Stabilization of “enol” inte...
Figure 3: Structure and activity of fullerene-amine dyads to catalyze the intrinsically disfavored but biolog...
Figure 4: Asymmetric anion–π catalysis of intrinsically disfavored exo-selective Diels–Alder reactions on ful...
Figure 5: Asymmetric anion–π catalysis to install remote stereogenic centers on fullerene catalyst 21, with n...
Figure 6: Primary anion–π autocatalysis on monofunctional fullerene 31, with catalytic and autocatalytic rate...
Figure 7: (A) Macrodipoles induced by anionic transition states account for anion–π catalysis on fullerenes. ...
Figure 8: Structure and activity of covalently and non-covalently modified SWCNTs and MWCNTs, with A/D ratios...
Figure 9: (A) Epoxide-opening ether cyclization on pristine carbon nanotubes occurs with (XVI) but not withou...
Figure 10: Electric-field-induced anion–π catalysis on MWCNTs 3 on graphite 76 in electrochemical microfluidic...
Inline purification in continuous flow synthesis – opportunities and challenges
- Jorge García-Lacuna and
- Marcus Baumann
Beilstein J. Org. Chem. 2022, 18, 1720–1740, doi:10.3762/bjoc.18.182
- ). In another case, the authors opt to use stoichiometric quantities of reagents to avoid the use of cartridges, even if the performance is worse, to reduce cost and time [93]. Catch and release strategy An interesting approach regarding the use of resins is their application in catch and release
- purification via a catch and release strategy [96]. Additionally, functionalized residues can be used to perform a solid-state synthesis approach, such as in the synthesis of 2-aminopyridine derivatives starting from amino-iminium residues [97]. To improve on this technology, Baxendale and co-workers utilized
- ]. Another example for using this catch and release strategy would be when the product is trapped on silica due to its polarity prior to its release with a more polar solvent. This case is reported in the synthesis of iloperidone (Scheme 12) [107]. Though limited to applications with highly polar products
Graphical Abstract
Scheme 1: Automated in-line chromatography with the Advion puriFlash® system. The rightmost part of the schem...
Scheme 2: Purification via pH tuning and several Zaiput membranes. Redrawn from [51].
Scheme 3: Two-phase recirculating system for purifications of an immobilized enzyme-based reaction. Redrawn f...
Scheme 4: Countercurrent L–L purification using large Zaiput membranes in the presence of a phase transfer ca...
Scheme 5: General scheme of a telescoped flow process using L–L separators.
Scheme 6: Example of phase separation using a computer-vision approach. Redrawn from [68].
Scheme 7: Example of an inline purification using heterogeneous scavenging. Redrawn from [76].
Scheme 8: General scheme of a telescoped process using heterogenous cartridges.
Scheme 9: Comparison of two strategies for flow-based imatinib syntheses. Redrawn from [91] and [92].
Scheme 10: General purification scheme using the catch and release strategy.
Scheme 11: Exemplar catch and release purification of a stereoselective oxidation. Redrawn from [105].
Scheme 12: Catch and release-type purification using conventional SiO2. Redrawn from [107].
Scheme 13: Schematic representation of an industrial continuous crystallization. Redrawn from [109].
Scheme 14: General scheme of an academic inline crystallization approach.
Scheme 15: Simplified overview of purification options and selected criteria.
Inductive heating and flow chemistry – a perfect synergy of emerging enabling technologies
- Conrad Kuhwald,
- Sibel Türkhan and
- Andreas Kirschning
Beilstein J. Org. Chem. 2022, 18, 688–706, doi:10.3762/bjoc.18.70
- 180 °C at 4.5 MPa for 7.5 min. These conditions allowed to suppress the decomposition of the N-alkylation product 78 by using a 1/8“-reactor. The subsequent purification was realized by a clever catch and release protocol based on a silica column, yielding iloperidone (80, 67%). The tricyclic
- multistep flow synthesis of Iloperidone (80) accompanied with a “catch and release” purification protocol. Continuous two-step flow process consisting of Grignard reaction followed by water elimination being the last steps of a multistep flow synthesis of the hydrochloride salt of amitryptiline 84
Graphical Abstract
Figure 1: Inductive heating, a powerful tool in industry and the Life Sciences.
Figure 2: Electric displacement field of a ferromagnetic and superparamagnetic material.
Figure 3: Temperature profiles of reactors heated conventionally and by RF heating (Figure 3 redrawn from [24]).
Scheme 1: Continuous flow synthesis of isopulegol (2) from citronellal (1).
Scheme 2: Dry (reaction 1) and steam (reaction 2) methane reforming.
Scheme 3: Calcination and RF heating.
Scheme 4: The continuously operated “Sabatier” process.
Scheme 5: Biofuel production from biomass using inductive heating for pyrolysis.
Scheme 6: Water electrolysis using an inductively heated electrolysis cell.
Scheme 7: Dimroth rearrangement (reaction 1) and three-component reaction (reaction 2) to propargyl amines 8 ...
Figure 4: A. Flow reactor filled with magnetic nanostructured particles (MagSilicaTM) and packed bed reactor ...
Scheme 8: Claisen rearrangement in flow: A. comparison between conventional heating (external oil bath), micr...
Scheme 9: Continuous flow reactions and comparison with batch reaction (oil bath). A. Pd-catalyzed transfer h...
Scheme 10: Continuous flow reactions and comparison with batch reaction (oil bath). A. pericyclic reactions an...
Scheme 11: Reactions under flow conditions using inductively heated fixed-bed materials serving as stoichiomet...
Scheme 12: Reactions under flow conditions using inductively heated fixed-bed materials serving as catalysts: ...
Scheme 13: Two step flow protocol for the preparation of 1,1'-diarylalkanes 77 from ketones and aldehydes 74, ...
Scheme 14: O-Alkylation, the last step in the multistep flow synthesis of Iloperidone (80) accompanied with a ...
Scheme 15: Continuous two-step flow process consisting of Grignard reaction followed by water elimination bein...
Scheme 16: Inductively heated continuous flow protocol for the synthesis of Iso E Super (88) [91,92].
Scheme 17: Three-step continuous flow synthesis of macrocycles 89 and 90 with musk-like olfactoric properties.
A comprehensive review of flow chemistry techniques tailored to the flavours and fragrances industries
- Guido Gambacorta,
- James S. Sharley and
- Ian R. Baxendale
Beilstein J. Org. Chem. 2021, 17, 1181–1312, doi:10.3762/bjoc.17.90
Graphical Abstract
Figure 1: Representative shares of the global F&F market (2018) segmented on their applications [1].
Figure 2: General structure of an international fragrance company [2].
Figure 3: The Michael Edwards fragrance wheel.
Figure 4: Examples of oriental (1–3), woody (4–7), fresh (8–10), and floral (11 and 12) notes.
Figure 5: A basic depiction of batch vs flow.
Scheme 1: Examples of reactions for which flow processing outperforms batch.
Scheme 2: Some industrially important aldol-based transformations.
Scheme 3: Biphasic continuous aldol reactions of acetone and various aldehydes.
Scheme 4: Aldol synthesis of 43 in flow using LiHMDS as the base.
Scheme 5: A semi-continuous synthesis of doravirine (49) involving a key aldol reaction.
Scheme 6: Enantioselective aldol reaction using 5-(pyrrolidin-2-yl)tetrazole (51) as catalyst in a microreact...
Scheme 7: Gröger's example of asymmetric aldol reaction in aqueous media.
Figure 6: Immobilised reagent column reactor types.
Scheme 8: Photoinduced thiol–ene coupling preparation of silica-supported 5-(pyrrolidin-2-yl)tetrazole 63 and...
Scheme 9: Continuous-flow approach for enantioselective aldol reactions using the supported catalyst 67.
Scheme 10: Ötvös’ employment of a solid-supported peptide aldol catalyst in flow.
Scheme 11: The use of proline tetrazole packed in a column for aldol reaction between cyclohexanone (65) and 2...
Scheme 12: Schematic diagram of an aminosilane-grafted Si-Zr-Ti/PAI-HF reactor for continuous-flow aldol and n...
Scheme 13: Continuous-flow condensation for the synthesis of the intermediate 76 to nabumetone (77) and Microi...
Scheme 14: Synthesis of ψ-Ionone (80) in continuous-flow via aldol condensation between citral (79) and aceton...
Scheme 15: Synthesis of β-methyl-ionones (83) from citral (79) in flow. The steps are separately described, an...
Scheme 16: Continuous-flow synthesis of 85 from 84 described by Gavriilidis et al.
Scheme 17: Continuous-flow scCO2 apparatus for the synthesis of 2-methylpentanal (87) and the self-condensed u...
Scheme 18: Chen’s two-step flow synthesis of coumarin (90).
Scheme 19: Pechmann condensation for the synthesis of 7-hydroxyxcoumarin (93) in flow. The setup extended to c...
Scheme 20: Synthesis of the dihydrojasmonate 35 exploiting nitro derivative proposed by Ballini et al.
Scheme 21: Silica-supported amines as heterogeneous catalyst for nitroaldol condensation in flow.
Scheme 22: Flow apparatus for the nitroaldol condensation of p-hydroxybenzaldehyde (102) to nitrostyrene 103 a...
Scheme 23: Nitroaldol reaction of 64 to 105 employing a quaternary ammonium functionalised PANF.
Scheme 24: Enantioselective nitroaldol condensation for the synthesis of 108 under flow conditions.
Scheme 25: Enatioselective synthesis of 1,2-aminoalcohol 110 via a copper-catalysed nitroaldol condensation.
Scheme 26: Examples of Knoevenagel condensations applied for fragrance components.
Scheme 27: Flow apparatus for Knoevenagel condensation described in 1989 by Venturello et al.
Scheme 28: Knoevenagel reaction using a coated multichannel membrane microreactor.
Scheme 29: Continuous-flow apparatus for Knoevenagel condensation employing sugar cane bagasse as support deve...
Scheme 30: Knoevenagel reaction for the synthesis of 131–135 in flow using an amine-functionalised silica gel. ...
Scheme 31: Continuous-flow synthesis of compound 137, a key intermediate for the synthesis of pregabalin (138)...
Scheme 32: Continuous solvent-free apparatus applied for the synthesis of compounds 140–143 using a TSE. Throu...
Scheme 33: Lewis et al. developed a spinning disc reactor for Darzens condensation of 144 and a ketone to furn...
Scheme 34: Some key industrial applications of conjugate additions in the F&F industry.
Scheme 35: Continuous-flow synthesis of 4-(2-hydroxyethyl)thiomorpholine 1,1-dioxide (156) via double conjugat...
Scheme 36: Continuous-flow system for Michael addition using CsF on alumina as the catalyst.
Scheme 37: Calcium chloride-catalysed asymmetric Michael addition using an immobilised chiral ligand.
Scheme 38: Continuous multistep synthesis for the preparation of (R)-rolipram (173). Si-NH2: primary amine-fun...
Scheme 39: Continuous-flow Michael addition using ion exchange resin Amberlyst® A26.
Scheme 40: Preparation of the heterogeneous catalyst 181 developed by Paixão et al. exploiting Ugi multicompon...
Scheme 41: Continuous-flow system developed by the Paixão’s group for the preparation of Michael asymmetric ad...
Scheme 42: Continuous-flow synthesis of nitroaldols catalysed by supported catalyst 184 developed by Wennemers...
Scheme 43: Heterogenous polystyrene-supported catalysts developed by Pericàs and co-workers.
Scheme 44: PANF-supported pyrrolidine catalyst for the conjugate addition of cyclohexanone (65) and trans-β-ni...
Scheme 45: Synthesis of (−)-paroxetine precursor 195 developed by Ötvös, Pericàs, and Kappe.
Scheme 46: Continuous-flow approach for the 5-step synthesis of (−)-oseltamivir (201) as devised by Hayashi an...
Scheme 47: Continuous-flow enzyme-catalysed Michael addition.
Scheme 48: Continuous-flow copper-catalysed 1,4 conjugate addition of Grignard reagents to enones. Reprinted w...
Scheme 49: A collection of commonly encountered hydrogenation reactions.
Figure 7: The ThalesNano H-Cube® continuous-flow hydrogenator.
Scheme 50: Chemoselective reduction of an α,β-unsaturated ketone using the H-Cube® reactor.
Scheme 51: Incorporation of Lindlar’s catalyst into the H-Cube® reactor for the reduction of an alkyne.
Scheme 52: Continuous-flow semi-hydrogenation of alkyne 208 to 209 using SACs with H-Cube® system.
Figure 8: The standard setups for tube-in-tube gas–liquid reactor units.
Scheme 53: Homogeneous hydrogenation of olefins using a tube-in-tube reactor setup.
Scheme 54: Recyclable heterogeneous flow hydrogenation system.
Scheme 55: Leadbeater’s reverse tube-in-tube hydrogenation system for olefin reductions.
Scheme 56: a) Hydrogenation using a Pd-immobilised microchannel reactor (MCR) and b) a representation of the i...
Scheme 57: Hydrogenation of alkyne 238 exploiting segmented flow in a Pd-immobilised capillary reactor.
Scheme 58: Continuous hydrogenation system for the preparation of cyrene (241) from (−)-levoglucosenone (240).
Scheme 59: Continuous hydrogenation system based on CSMs developed by Hornung et al.
Scheme 60: Chemoselective reduction of carbonyls (ketones over aldehydes) in flow.
Scheme 61: Continuous system for the semi-hydrogenation of 256 and 258, developed by Galarneau et al.
Scheme 62: Continuous synthesis of biodiesel fuel 261 from lignin-derived furfural acetone (260).
Scheme 63: Continuous synthesis of γ-valerolacetone (263) via CTH developed by Pineda et al.
Scheme 64: Continuous hydrogenation of lignin-derived biomass (products 265, 266, and 267) using a sustainable...
Scheme 65: Ru/C or Rh/C-catalysed hydrogenation of arene in flow as developed by Sajiki et al.
Scheme 66: Polysilane-immobilized Rh–Pt-catalysed hydrogenation of arenes in flow by Kobayashi et al.
Scheme 67: High-pressure in-line mixing of H2 for the asymmetric reduction of 278 at pilot scale with a 73 L p...
Figure 9: Picture of the PFR employed at Eli Lilly & Co. for the continuous hydrogenation of 278 [287]. Reprinted ...
Scheme 68: Continuous-flow asymmetric hydrogenation using Oppolzer's sultam 280 as chiral auxiliary.
Scheme 69: Some examples of industrially important oxidation reactions in the F&F industry. CFL: compact fluor...
Scheme 70: Gold-catalysed heterogeneous oxidation of alcohols in flow.
Scheme 71: Uozumi’s ARP-Pt flow oxidation protocol.
Scheme 72: High-throughput screening of aldehyde oxidation in flow using an in-line GC.
Scheme 73: Permanganate-mediated Nef oxidation of nitroalkanes in flow with the use of in-line sonication to p...
Scheme 74: Continuous-flow aerobic anti-Markovnikov Wacker oxidation.
Scheme 75: Continuous-flow oxidation of 2-benzylpyridine (312) using air as the oxidant.
Scheme 76: Continuous-flow photo-oxygenation of monoterpenes.
Scheme 77: A tubular reactor design for flow photo-oxygenation.
Scheme 78: Glucose oxidase (GOx)-mediated continuous oxidation of glucose using compressed air and the FFMR re...
Scheme 79: Schematic continuous-flow sodium hypochlorite/TEMPO oxidation of alcohols.
Scheme 80: Oxidation using immobilised TEMPO (344) was developed by McQuade et al.
Scheme 81: General protocol for the bleach/catalytic TBAB oxidation of aldehydes and alcohols.
Scheme 82: Continuous-flow PTC-assisted oxidation using hydrogen peroxide. The process was easily scaled up by...
Scheme 83: Continuous-flow epoxidation of cyclohexene (348) and in situ preparation of m-CPBA.
Scheme 84: Continuous-flow epoxidation using DMDO as oxidant.
Scheme 85: Mukayama aerobic epoxidation optimised in flow mode by the Favre-Réguillon group.
Scheme 86: Continuous-flow asymmetric epoxidation of derivatives of 359 exploiting a biomimetic iron catalyst.
Scheme 87: Continuous-flow enzymatic epoxidation of alkenes developed by Watts et al.
Scheme 88: Engineered multichannel microreactor for continuous-flow ozonolysis of 366.
Scheme 89: Continuous-flow synthesis of the vitamin D precursor 368 using multichannel microreactors. MFC: mas...
Scheme 90: Continuous ozonolysis setup used by Kappe et al. for the synthesis of various substrates employing ...
Scheme 91: Continuous-flow apparatus for ozonolysis as developed by Ley et al.
Scheme 92: Continuous-flow ozonolysis for synthesis of vanillin (2) using a film-shear flow reactor.
Scheme 93: Examples of preparative methods for ajoene (386) and allicin (388).
Scheme 94: Continuous-flow oxidation of thioanisole (389) using styrene-based polymer-supported peroxytungstat...
Scheme 95: Continuous oxidation of thiosulfinates using Oxone®-packed reactor.
Scheme 96: Continuous-flow electrochemical oxidation of thioethers.
Scheme 97: Continuous-flow oxidation of 400 to cinnamophenone (235).
Scheme 98: Continuous-flow synthesis of dehydrated material 401 via oxidation of methyl dihydrojasmonate (33).
Scheme 99: Some industrially important transformations involving Grignard reagents.
Scheme 100: Grachev et al. apparatus for continuous preparation of Grignard reagents.
Scheme 101: Example of fluidized Mg bed reactor with NMR spectrometer as on-line monitoring system.
Scheme 102: Continuous-flow synthesis of Grignard reagents and subsequent quenching reaction.
Figure 10: Membrane-based, liquid–liquid separator with integrated pressure control [52]. Adapted with permission ...
Scheme 103: Continuous-flow synthesis of 458, an intermediate to fluconazole (459).
Scheme 104: Continuous-flow synthesis of ketones starting from benzoyl chlorides.
Scheme 105: A Grignard alkylation combining CSTR and PFR technologies with in-line infrared reaction monitoring....
Scheme 106: Continuous-flow preparation of 469 from Grignard addition of methylmagnesium bromide.
Scheme 107: Continuous-flow synthesis of Grignard reagents 471.
Scheme 108: Preparation of the Grignard reagent 471 using CSTR and the continuous process for synthesis of the ...
Scheme 109: Continuous process for carboxylation of Grignard reagents in flow using tube-in-tube technology.
Scheme 110: Continuous synthesis of propargylic alcohols via ethynyl-Grignard reagent.
Scheme 111: Silica-supported catalysed enantioselective arylation of aldehydes using Grignard reagents in flow ...
Scheme 112: Acid-catalysed rearrangement of citral and dehydrolinalool derivatives.
Scheme 113: Continuous stilbene isomerisation with continuous recycling of photoredox catalyst.
Scheme 114: Continuous-flow synthesis of compound 494 as developed by Ley et al.
Scheme 115: Selected industrial applications of DA reaction.
Scheme 116: Multistep flow synthesis of the spirocyclic structure 505 via employing DA cycloaddition.
Scheme 117: Continuous-flow DA reaction developed in a plater flow reactor for the preparation of the adduct 508...
Scheme 118: Continuous-flow DA reaction using a silica-supported imidazolidinone organocatalyst.
Scheme 119: Batch vs flow for the DA reaction of (cyclohexa-1,5-dien-1-yloxy)trimethylsilane (513) with acrylon...
Scheme 120: Continuous-flow DA reaction between 510 and 515 using a shell-core droplet system.
Scheme 121: Continuous-flow synthesis of bicyclic systems from benzyne precursors.
Scheme 122: Continuous-flow synthesis of bicyclic scaffolds 527 and 528 for further development of potential ph...
Scheme 123: Continuous-flow inverse-electron hetero-DA reaction to pyridine derivatives such as 531.
Scheme 124: Comparison between batch and flow for the synthesis of pyrimidinones 532–536 via retro-DA reaction ...
Scheme 125: Continuous-flow coupled with ultrasonic system for preparation of ʟ-ascorbic acid derivatives 539 d...
Scheme 126: Two-step continuous-flow synthesis of triazole 543.
Scheme 127: Continuous-flow preparation of triazoles via CuAAC employing 546-based heterogeneous catalyst.
Scheme 128: Continuous-flow synthesis of compounds 558 through A3-coupling and 560 via AgAAC both employing the...
Scheme 129: Continuous-flow photoinduced [2 + 2] cycloaddition for the preparation of bicyclic derivatives of 5...
Scheme 130: Continuous-flow [2 + 2] and [5 + 2] cycloaddition on large scale employing a flow reactor developed...
Scheme 131: Continuous-flow preparation of the tricyclic structures 573 and 574 starting from pyrrole 570 via [...
Scheme 132: Continuous-flow [2 + 2] photocyclization of cinnamates.
Scheme 133: Continuous-flow preparation of cyclobutane 580 on a 5-plates photoreactor.
Scheme 134: Continuous-flow [2 + 2] photocycloaddition under white LED lamp using heterogeneous PCN as photocat...
Figure 11: Picture of the parallel tube flow reactor (PTFR) "The Firefly" developed by Booker-Milburn et al. a...
Scheme 135: Continuous-flow acid-catalysed [2 + 2] cycloaddition between silyl enol ethers and acrylic esters.
Scheme 136: Continuous synthesis of lactam 602 using glass column reactors.
Scheme 137: In situ generation of ketenes for the Staudinger lactam synthesis developed by Ley and Hafner.
Scheme 138: Application of [2 + 2 + 2] cycloadditions in flow employed by Ley et al.
Scheme 139: Examples of FC reactions applied in F&F industry.
Scheme 140: Continuous-flow synthesis of ibuprofen developed by McQuade et al.
Scheme 141: The FC acylation step of Jamison’s three-step ibuprofen synthesis.
Scheme 142: Synthesis of naphthalene derivative 629 via FC acylation in microreactors.
Scheme 143: Flow system for rapid screening of catalysts and reaction conditions developed by Weber et al.
Scheme 144: Continuous-flow system developed by Buorne, Muller et al. for DSD optimisation of the FC acylation ...
Scheme 145: Continuous-flow FC acylation of alkynes to yield β-chlorovinyl ketones such as 638.
Scheme 146: Continuous-flow synthesis of tonalide (619) developed by Wang et al.
Scheme 147: Continuous-flow preparation of acylated arene such as 290 employing Zr4+-β-zeolite developed by Kob...
Scheme 148: Flow system applied on an Aza-FC reaction catalysed by the thiourea catalyst 648.
Scheme 149: Continuous hydroformylation in scCO2.
Scheme 150: Two-step flow synthesis of aldehyde 655 through a sequential Heck reaction and subsequent hydroform...
Scheme 151: Single-droplet (above) and continuous (below) flow reactors developed by Abolhasani et al. for the ...
Scheme 152: Continuous hydroformylation of 1-dodecene (655) using a PFR-CSTR system developed by Sundmacher et ...
Scheme 153: Continuous-flow synthesis of the aldehyde 660 developed by Eli Lilly & Co. [32]. Adapted with permissio...
Scheme 154: Continuous asymmetric hydroformylation employing heterogenous catalst supported on carbon-based sup...
Scheme 155: Examples of acetylation in F&F industry: synthesis of bornyl (S,R,S-664) and isobornyl (S,S,S-664) ...
Scheme 156: Continuous-flow preparation of bornyl acetate (S,R,S-664) employing the oscillating flow reactor.
Scheme 157: Continuous-flow synthesis of geranyl acetate (666) from acetylation of geraniol (343) developed by ...
Scheme 158: 12-Ttungstosilicic acid-supported silica monolith-catalysed acetylation in flow.
Scheme 159: Continuous-flow preparation of cyclopentenone 676.
Scheme 160: Two-stage synthesis of coumarin (90) via acetylation of salicylaldehyde (88).
Scheme 161: Intensification process for acetylation of 5-methoxytryptamine (677) to melatonin (678) developed b...
Scheme 162: Examples of macrocyclic musky odorants both natural (679–681) and synthetic (682 and 683).
Scheme 163: Flow setup combined with microwave for the synthesis of macrocycle 686 via RCM.
Scheme 164: Continuous synthesis of 2,5-dihydro-1H-pyrroles via ring-closing metathesis.
Scheme 165: Continuous-flow metathesis of 485 developed by Leadbeater et al.
Figure 12: Comparison between RCM performed using different routes for the preparation of 696. On the left the...
Scheme 166: Continuous-flow RCM of 697 employed the solid-supported catalyst 698 developed by Grela, Kirschning...
Scheme 167: Continuous-flow RORCM of cyclooctene employing the silica-absorbed catalyst 700.
Scheme 168: Continuous-flow self-metathesis of methyl oleate (703) employing SILP catalyst 704.
Scheme 169: Flow apparatus for the RCM of 697 using a nanofiltration membrane for the recovery and reuse of the...
Scheme 170: Comparison of loadings between RCMs performed with different routes for the synthesis of 709.
Synergy between supported ionic liquid-like phases and immobilized palladium N-heterocyclic carbene–phosphine complexes for the Negishi reaction under flow conditions
- Edgar Peris,
- Raúl Porcar,
- María Macia,
- Jesús Alcázar,
- Eduardo García-Verdugo and
- Santiago V. Luis
Beilstein J. Org. Chem. 2020, 16, 1924–1935, doi:10.3762/bjoc.16.159
- . A catch and release mechanism can be established favored by the presence of the supported ionic liquid-like phases. SILLPs with a relatively low loading of methylimidazolium units provided the most efficient systems to be used in conjunction with the immobilized NHC–Pd–RuPhos. Negishi reaction
Graphical Abstract
Scheme 1: Synthesis of NHC-supported catalysts.
Scheme 2: Negishi benchmark reaction.
Figure 1: Negishi reaction catalyzed by immobilized NHC–Pd complexes. Conditions: methyl 4-bromobenzoate (0.2...
Scheme 3: Synthesis of immobilized NHC–Pd–RuPhos.
Figure 2: Negishi model reaction between 5 and 6 under flow conditions catalyzed by 4b. V = 0.535 mL, 363 mg ...
Figure 3: Negishi model reaction under flow conditions catalyzed by 8a. V = 2.9 mL, 1.25 g of catalyst, resid...
Figure 4: Negishi reaction between 5 and 6 catalyzed by 8a in the presence of SILLPs. a) Yield (%) vs time fo...
Figure 5: TEM images of the polymers after the Negishi reaction between 5 and 6. a) 8a, bar scale 20 nm, PdNP...
Scheme 4: Pd species immobilized onto SILLPs. i) 1 g SILLP 10, 100 mg PdCl2 in milli-Q® water (100 mL 1% HCl,...
Figure 6: Negishi reaction between 5 and 6 catalyzed by 11. 1 equiv methyl 4-bromobenzoate (6, 0.25 mmol), 2 ...
Figure 7: Negishi reaction between 5 and 6 under flow conditions catalyzed by 8a in the presence of a scaveng...
Figure 8: Effect of the structure of the SILLP scavenger for the Negishi reaction between 5 and 6 under flow ...
Figure 9: TEM images of the polymer after the Negishi reaction between 5 and 6 under flow conditions. a) 8a + ...
The Shono-type electroorganic oxidation of unfunctionalised amides. Carbon–carbon bond formation via electrogenerated N-acyliminium ions
- Alan M. Jones and
- Craig E. Banks
Beilstein J. Org. Chem. 2014, 10, 3056–3072, doi:10.3762/bjoc.10.323
- ) induced a “temporarily soluble” droplet of the nucleophile that can then intercept the N-acyliminium ion. Electrosynthesis have been adapted to use solid-supported bases [47][48][49][50][51], performing the electrosynthesis on compounds directly attached to a catch and release solid-support [52], or
- and release cation pool method [42]. Schematic illustration of the anodic substitution reaction system using acoustic emulsification. Figure redrawn from reference [45]. Example of a chiral auxiliary Shono-oxidation intermediate [69]. Application of anodic oxidation to the generation of new carbon
- electrochemists to significantly progress this exciting and burgeoning field. Schematic of a cation flow system and also shown is the electrochemical microflow reactor reported by Suga et al. Figure redrawn from reference [30]. Example of a parallel laminar flow set-up. Figure redrawn from reference [38]. A catch
Graphical Abstract
Scheme 1: Application of anodic oxidation to the generation of new carbon-carbon bonds [11].
Scheme 2: The influence of the amino protecting group on the “kinetic” and “thermodynamic” anodic methoxylati...
Scheme 3: Example of the application of the cation pool method [17].
Scheme 4: A thiophenyl electroauxiliary allows for regioselective anodic oxidation [32].
Scheme 5: A diastereoselective cation carbohydroxylation reaction and postulated intermediate 18 [18].
Scheme 6: A radical addition and electron transfer reaction of N-acyliminium ions generated electrosynthetica...
Scheme 7: Catalytic indirect anodic fluorodesulfurization reaction [37].
Figure 1: Schematic of a cation flow system and also shown is the electrochemical microflow reactor reported ...
Figure 2: Example of a parallel laminar flow set-up. Figure redrawn from reference [38].
Figure 3: A catch and release cation pool method [42].
Scheme 8: Micromixing effects on yield 92% vs 36% and ratio of alkylation products [43].
Figure 4: Schematic illustration of the anodic substitution reaction system using acoustic emulsification. Fi...
Scheme 9: Electrooxidation to prepare a chiral oxidation mediator and application to the kinetic resolution o...
Scheme 10: Electrooxidation reactions on 4-membered ring systems [68].
Figure 5: Example of a chiral auxiliary Shono-oxidation intermediate [69].
Scheme 11: An electrochemical multicomponent reaction where a carbon felt anode and platinum cathode were util...
Scheme 12: Preparation of dienes using the Shono oxidation [23].
Scheme 13: Combination of an electroauxiliary mediated anodic oxidation and RCM to afford spirocyclic compound...
Scheme 14: Total synthesis of (+)-myrtine (66) using an electrochemical approach [78].
Scheme 15: Total synthesis of (−)-A58365A (70) and (±)-A58365B (71) [79].
Scheme 16: Anodic oxidation used in the preparation of the poison frog alkaloid 195C [80].
Scheme 17: Preparation of iminosugars using an electrochemical approach [81].
Scheme 18: The electrosynthetic preparation of α-L-fucosidase inhibitors [84,85].
Scheme 19: Enantioselective synthesis of the anaesthetic ropivacaine 85 [71].
Scheme 20: The preparation of synthetically challenging aza-nucleosides employing an electrochemical step [88].
Scheme 21: Synthesis of a bridged tricyclic diproline analogue 93 that induces α-helix conformation into linea...
Scheme 22: Synthesis of (i) a peptidomimetic and (ii) a functionalised peptide from silyl electroauxiliary pre...
Scheme 23: Examples of Phe7–Phe8 mimics prepared using an electrochemical approach [93].
Scheme 24: Preparation of arginine mimics employing an electrooxidation step [96].
Scheme 25: Preparation of chiral cyclic amino acids [20].
Scheme 26: Two-step preparation of Nazlinine 117 using Shono flow electrochemistry [101].
Camera-enabled techniques for organic synthesis
- Steven V. Ley,
- Richard J. Ingham,
- Matthew O’Brien and
- Duncan L. Browne
Beilstein J. Org. Chem. 2013, 9, 1051–1072, doi:10.3762/bjoc.9.118
Graphical Abstract
Figure 1: The evolution of computer-based monitoring and control within the laboratory of the future. (a) In ...
Figure 2: A selection of the wide range of digital camera devices available, focusing on those that can be at...
Figure 3: (a) Network cameras (Linksys WVC54GC) in operation in the Innovative Technology Centre laboratory. ...
Figure 4: Remote transmission of video imagery and reaction monitoring data.
Figure 5: A camera can assist the chemist in a number of ways. Digital video recordings of reactions can be u...
Figure 6: Suzuki–Miyaura reaction performed within a microfluidic system. The product is observed by high-spe...
Figure 7: Friedel–Crafts reactions performed by using solid-acid catalysis at high pressures. A camera allowe...
Figure 8: (a) The video camera setup providing a view of the reaction within the microwave cavity; (b) a pall...
Figure 9: (a) Buchwald–Hartwig coupling within a microchannel reactor. (b) Camera view of aggregate deposits ...
Figure 10: The key diprotected piperazic acid precursor in the synthesis of chloptosin.
Figure 11: (a) Piperazic acid mixture, and (b) apparatus for enantiomeric upgrading by recorded crystallisatio...
Figure 12: (a) Crystallisation of a Mn(II) polyoxometalate. (b) A bespoke reactor produced using additive fabr...
Figure 13: Computer processing of digital imagery produces numerical data for later processing.
Figure 14: (a) The Morphologi G3 particle image analyser, which uses images captured with a camera microscope ...
Figure 15: Use of the Python Imaging Library to analyse the proportion of an image consisting of red pixels. A...
Figure 16: (a) Arduino [73,75], a flexible open-source platform for rapidly prototyping electronic applications. (b) ...
Figure 17: Patented device incorporating a standard 96-well plate illuminated by a white-light source. The pla...
Figure 18: Simple colour-change experiments to assess a new AF-2400 gas permeable flow reactor. The reactor co...
Figure 19: (a) Ozonolysis of a series of alkenes using ozone in a bottle-reactor; (b) Glaser–Hay coupling usin...
Figure 20: (a) Camera-assisted titration of ammonia using bromocresol green. NH3 is dissolved in the gas-flow ...
Figure 21: (a) Bubble-counting setup. As the output of the gas-flow reactor (hydrogen dissolved in dichloromet...
Figure 22: Usage of digital cameras to enable remote control of reactions.
Figure 23: In-line solvent switching apparatus. The reactor output is directed into a bottle positioned on a h...
Figure 24: Catch and Release apparatus. (1) The amide intermediate is sequestered onto the central sulfonic ac...
Figure 25: Clips from video footage showing the silica reagent changing appearance; the arrows indicate the ed...
Figure 26: Combination of computer vision and automation to enable machine-assisted synthetic processes.
Figure 27: A coloured float at the interface between heavy and light solvents allows a camera to recognise the...
Figure 28: Graphical demonstration of the image-recognition process. At the start of the experiment, the colou...
Figure 29: Application of the computer-vision-enabled liquid–liquid extractor. The product mixture of a hydraz...
Figure 30: Application of a computer-vision technique to measure the dispersion of a plug of material passing ...
Figure 31: Multiple extractors in series controlled by a single camera.
Figure 32: Two-step synthesis of branched aldehydes from aryl iodides using two reactive gases. A liquid–liqui...
Approaches towards the synthesis of 5-aminopyrazoles
- Ranjana Aggarwal,
- Vinod Kumar,
- Rajiv Kumar and
- Shiv P. Singh
Beilstein J. Org. Chem. 2011, 7, 179–197, doi:10.3762/bjoc.7.25
- -component, two-step “catch and release” solid-phase synthesis of 3,4,5-trisubstituted pyrazoles was reported which involved a base-promoted condensation of a 2-sulfonyl- or a 2-carbonyl-acetonitrile derivative (29 or 33) with an isothiocyanate and in situ immobilization of the resulting thiolate anion (30
- synthesis of 5-aminopyrazoles. Synthesis of 5-aminopyrazoles from resin supported enamine nitrile 25 as the starting material. Two-step “catch and release” solid-phase synthesis of 3,4,5-trisubstituted pyrazoles. Synthesis of pyrazolo[5,1-d][1,2,3,5]tetrazine-4(3H)-ones. Synthesis of the 5,5-ring system
Graphical Abstract
Figure 1: Pharmacologically active 5-aminopyrazoles.
Scheme 1: General equation for the condensation of β-ketonitriles with hydrazines.
Scheme 2: Reaction of hydrazinoheterocycles with α-phenyl-β-cyanoketones (4).
Scheme 3: Condensation of cyanoacetaldehyde (7) with hydrazines.
Scheme 4: Synthesis of 5-aminopyrazoles and their sulfonamide derivatives.
Scheme 5: Synthesis of 5-aminopyrazoles, containing a cyclohexylmethyl- or phenylmethyl- sulfonamido group at...
Scheme 6: Regioselective synthesis of 3-amino-2-alkyl (or aryl) thieno[3,4-c]pyrazoles 19.
Scheme 7: Solid supported synthesis of 5-aminopyrazoles.
Scheme 8: Synthesis of 5-aminopyrazoles from resin supported enamine nitrile 25 as the starting material.
Scheme 9: Two-step “catch and release” solid-phase synthesis of 3,4,5-trisubstituted pyrazoles.
Scheme 10: Synthesis of pyrazolo[5,1-d][1,2,3,5]tetrazine-4(3H)-ones.
Scheme 11: Synthesis of the 5,5-ring system, imidazo[1,2-b]pyrazol-2-ones.
Scheme 12: Synthesis of 5-amino-3-(pyrrol-2-yl)pyrazole-4-carbonitrile.
Scheme 13: Synthesis of N-(1,3-diaryl-1H-pyrazol-5-yl)benzamide.
Scheme 14: Synthesis of 3,7-bis(arylazo)-6-methyl-2-phenyl-1H-imidazo[1,2-b]pyrazoles.
Scheme 15: Synthesis of 3,5-diaminopyrazole.
Scheme 16: Synthesis of 5-amino-4-cyanopyrazole and 5-amino-3-hydrazinopyrazole.
Scheme 17: Synthesis of 3,5-diaminopyrazoles with substituted malononitriles.
Scheme 18: Synthesis of 3,5-diamino-4-oximinopyrazole.
Scheme 19: Synthesis of 4-arylazo-3,5-diaminopyrazoles.
Scheme 20: Synthesis of 3- or 5-amino-4-cyanopyrazoles.
Scheme 21: Synthesis of triazenopyrazoles.
Scheme 22: Synthesis of 5(3)-aminopyrazoles.
Scheme 23: Synthesis of 3-substituted 5-amino-4-cyanopyrazoles.
Scheme 24: Synthesis of 2-{[(1-acetyl-4-cyano-1H-pyrazol-5-yl)amino]methylene}malononitrile.
Scheme 25: Synthesis of 5-aminopyrazole carbodithioates and 5-amino-3-arylamino-1-phenylpyrazole-4-carboxamide...
Scheme 26: Synthesis of 5-amino-4-cyanopyrazoles.
Scheme 27: Synthesis of thiazolylpyrazoles.
Scheme 28: Synthesis of 5-amino-1-heteroaryl-3-methyl/aryl-4-cyanopyrazoles.
Scheme 29: Synthesis of 5-amino-3-methylpyrazole-4-carboxamide.
Scheme 30: Synthesis of 4-acylamino-3(5)-amino-5(3)-arylsulfanylpyrazoles.
Scheme 31: Synthesis of 5-amino-1-aryl-4-diethoxyphosphoryl-3-halomethylpyrazoles.
Scheme 32: Synthesis of substituted 5-amino-3-trifluoromethylpyrazoles 114 and 118.
Scheme 33: Solid-support synthesis of 5-N-alkylamino and 5-N-arylaminopyrazoles.
Scheme 34: Synthesis of 5-amino-1-cyanoacetyl-3-phenyl-1H-pyrazole.
Scheme 35: Synthesis of 3-substituted 5-amino-1-aryl-4-(benzothiazol-2-yl)pyrazoles.
Scheme 36: Synthesis of 5-amino-4-carbethoxy-3-methyl-1-(4-sulfamoylphenyl)pyrazole.
Scheme 37: Synthesis of inhibitors of hsp27-phosphorylation and TNFa-release.
Scheme 38: Synthesis of the diglycylpyrazole 142.
Scheme 39: Synthesis of 5-amino-1-aryl-4-benzoylpyrazole derivatives.
Scheme 40: Synthesis of 4-benzoyl-3,5-diamino-1-(2-cyanoethyl)pyrazole.
Scheme 41: Synthesis of the 5-aminopyrazole derivative 150.
Scheme 42: Synthesis of 3,5-diaminopyrazoles 153.
Scheme 43: Synthesis of 5-aminopyrazoles derivatives 155 via lithiated intermediates.
Scheme 44: Synthesis of 5-amino-4-(1,2,4-oxadiazol-5-yl)-pyrazoles 157.
Scheme 45: Synthesis of a 5-aminopyrazole with anticonvulsant activity.
Scheme 46: Synthesis of tetrasubstituted 5-aminopyrazole derivatives.
Scheme 47: Synthesis of substituted 5-aminopyrazoles from hydrazonoyl halides.
Scheme 48: Synthesis of 3-amino-5-phenylpyrazoles from isothiazoles.
Scheme 49: Synthesis of 5-aminopyrazoles via ring transformation.
Continuous flow based catch and release protocol for the synthesis of α-ketoesters
- Alessandro Palmieri,
- Steven V. Ley,
- Anastasios Polyzos,
- Mark Ladlow and
- Ian R. Baxendale
Beilstein J. Org. Chem. 2009, 5, No. 23, doi:10.3762/bjoc.5.23
- esters 1a,c. Nitroolefinic esters 1a,c prepared under flow conditions (as described in Scheme 3). Supporting Information Supporting Information File 42: Supporting Information – Continuous flow based catch and release protocol for the synthesis of α-ketoesters Acknowledgements We gratefully acknowledge
- and release; flow synthesis; α-ketoesters; mesoreactor; polymer supported reagents; Introduction Organic synthesis is changing rapidly owing to the discovery of processes that challenge current dogma and lead to the invention of new chemical reactions [1][2]. Likewise, new synthesis tools are
- chemical syntheses [38][39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54]. In this work we report the use of the Uniqsis FlowSyn™ continuous flow reactor [55] (Figure 1) to effect a flow-based preparation of α-ketoesters. The key feature of this process is the application of a catch and
Graphical Abstract
Figure 1: The Uniqsis FlowSyn™ continuous flow reactor comprising of a column holder and heating unit (A) and...
Scheme 1: General procedure for the flow synthesis of α-ketoester products 4a–j.
Scheme 2: General procedure for the batch synthesis of nitroolefinic esters 1a–j.
Scheme 3: General procedure for the flow synthesis of nitroolefinic esters 1a,c.
Figure 2: α-Ketoesters prepared and isolated yields.
