Reaction Of Imines Research Articles

Synthetic Approaches for the Construction of Chiral Aziridines

Optically active aziridines represent a pivotal class of rigid three‐membered nitrogen‐heterocyclic compounds found in natural products, pharmaceuticals, agrochemicals, and functional motifs, which have demonstrated outstanding practicability as therapeutic molecular frameworks, versatile synthetic endpoints, and functional materials in both academic and industrial communities. Recent years have witnessed a broad spectrum of prominent breakthroughs in the field of chiral aziridines due to the aziridine‐based rigid and three‐dimensional pharmacophores, which have resulted in streamlining the drug discovery process. Over the past few decades, particular attention has been directed towards the strategically efficient, versatile, and practical assembly of optically active aziridines. These synthesis approaches have demonstrated great potential in the context of the construction of pharmaceutical molecules, biologically and pharmacologically relevant natural products, and functional materials. In this review, several synthetic strategies for the assembly of chiral aziridines are summarized, which could be divided into five categories; (1) Introduction; (2) Construction of optically active aziridines via reactions of olefines with nitrene sources; (3) Construction of optically active aziridines via reactions of imines with carbenes; (4) Construction of optically active aziridines via reaction of azirines; (5) Construction of optically active aziridines via intramolecular cyclization of amine derivatives.

Synthesis of spiroindolenines through a one-pot multistep process mediated by visible light.

Spiro-heterocyclic indolenines are privileged scaffolds widely present in numerous indole alkaloids. Here, we develop a novel approach for the one-pot multistep synthesis of different spiro[indole-isoquinolines]. The protocol proposed involves the visible light mediated oxidation of N-aryl tertiary amines using bromochloroform with the generation of a reactive iminium species, which reacts with an isocyanide and an electron-rich aniline in a three-component Ugi-type reaction to give an α-aminoamidine. This compound might undergo an additional visible light-mediated oxidation to furnish a second iminium intermediate, which acts as electrophile in an intramolecular electrophilic aromatic substitution giving the final spiro-indolenine. The scope of the process has been investigated with respect to all three components. Simple operations, mild conditions, and good yields make this strategy a convenient and sustainable way to obtain novel spiro-indolenine derivatives.

Alkylaluminum Complexes Featuring Bridged Bis-Formylfluorenimide Ligands for Hydroboration of Aldehyde, Ketone, and Imines.

Three bis-formylfluorenimide ligands with different bridging groups were designed and synthesized, leading to the successful preparation of six novel alkylaluminum complexes through their reaction with alkylaluminum reagents (AlMe3 or AlEt3). Complexes 1 and 2 were obtained by the reaction of 1,2-propylene-bridged diamine (L1) with AlMe3 or AlEt3. By reacting 1,2-cyclohexylene-bridged diamine (L2) with AlMe3 or AlEt3 to obtain complexes 3 and 4. The above ligands formed a bidentate four-coordinate structure with alkylaluminum, which involved the elimination of one alkyl group as the ligand reacted with alkylaluminum. The complexes 5 and 6 were synthesized through the reaction of 1,2-phenylene-bridged diamine (L3) with AlEt3 in toluene or tetrahydrofuran. Notably, L3 exhibited unique reactivity compared with the other ligands, which formed a tridentate four-coordinated structure when reacting with alkylaluminum. The formation of the tridentate complex resulted from the introduction of a benzimidazole derivative or tetrahydrofuran (THF) molecule along with the elimination of two alkyl groups during its coordination with alkylaluminum. All complexes were characterized via 1H NMR, 13C NMR, and elemental analysis, with structural determination confirmed through X-ray. Furthermore, the catalytic activity in the hydroboration reaction of aldehyde, ketone, and imines was investigated with these complexes as catalysts. Among them, complex 1 demonstrated excellent catalytic performance (up to 99% yield) and broad substrate compatibility (more than 30 substrates) at low catalyst loading (1 mol %) under mild reaction conditions.

Transition from Kwon [4+2]- to [3+2]-cycloaddition enabled by AgF-assisted phosphine catalysis

Phosphine catalysis generally relies on the potential of carbanion-phosphonium zwitterions that are generated via nucleophilic addition of phosphine catalyst to electrophilic reactants. Consequently, structural modification of zwitterions using distinct electrophilic reactants has emerged as a prominent strategy to enhance catalysis diversity. Herein, we present an alternative strategy that utilizes AgF additive to expand phosphine catalysis. We find that AgF can readily transform the canonical carbanion–phosphonium zwitterion into silver enolate–fluorophosphorane intermediate, eventually furnishing a P(III)/P(V) catalytic cycle. This strategy has been successfully applied to the phosphine-catalyzed reaction of 2-substituted allenoate and imine, resulting in the transition from Kwon [4 + 2] cycloaddition to [3 + 2] cycloaddition. This [3 + 2] cycloaddition features remarkable diastereoselectivity, high yield, and broad substrate scope. Experimental and computational studies have validated the proposed mechanism. Given the prevalence of carbanion–phosphonium zwitterions in phosphine catalysis, this AgF-assisted strategy is believed to hold significant potential for advancing P(III)/P(V) catalysis.

Magnetic alginate core-shell nanoparticles based on Schiff-base imine bonding for pH-responsive doxorubicin delivery system

This research describes the development of a novel pH-responsive drug delivery system (DDS) based on sodium alginate (SA) and magnetic nanoparticles (MNPs) for cancer treatments. One possible approach to creating a wide variety of functional nanoparticles is to graft functional materials onto magnetite nanoparticles. In this study, we demonstrate the effective alteration of Fe3O4 nanoparticles using the alginate dialdehyde (ADA) group through a Schiff-Base imine reaction toward synthesizing Fe3O4@SiO2@APTMS@ADA (FSA@ADA) nanocarrier (NC). doxorubicin (DOX) as an anticancer drug was loaded (about 93 % drug loading capacities) on the FSA@ADA NC through chemical and physical interactions. doxorubicin (DOX) as an anticancer drug was loaded (about 93 % drug loading capacities) on the FSA@ADA NC through chemical and physical interactions. The synthesized nanocarriers were thoroughly characterized by various techniques, including FT-IR, FE-SEM, EDX-MAP, TEM, XRD, VSM, TGA, and 1HNMR. In vitro DOX release studies showed a pH-dependent manner and its release rate is lower (< 15 %) at 7.4 than pH 5 (about 75 %) over 25 days. Cytotoxicity results showed good biocompatibility for blank FSA@ADA (over about 85 % cell viability), whereas DOX-loaded FSA@ADA NCs had higher cytotoxic effects (IC50 value: ∼6 µg/mL) as a result of the controlled release of DOX into HeLa cells. Results showed that the magnetic core-shell FSA@ADA/DOX NC has the potential to be used as a targeted stimuli-responsive drug for cancer treatment.

Organo‐Soluble Colloidal MoS2 Quantum Dots (QDs) as an Efficient Photocatalyst for α‐Amino Phosphonate Synthesis

Abstractα‐Amino phosphonates are bio‐isosteres of amino acids and have numerous biochemical activities. While they are generally prepared via carbon–phosphorus bond formation using a plethora of methods but using recyclable photo‐catalysts and readily accessible amine and phosphites are not commonly used in synthesis. Herein, we used organo‐soluble MoS2 Quantum Dots (QDs) as an exceptionally efficient nano‐photocatalyst for the synthesis of α‐amino phosphonates. Our approach emphasizes on photocatalysis within organic media, providing a facile and effective method for conducting these intricate organic conversions under mild conditions. This straightforward process harnesses the power of molecular oxygen (O2) as an oxidizing agent. To elaborate, our method is intricately guided by the inherent capability of MoS2 QDs to enter an excited state upon absorption of blue light. This excited state bears appropriate potential energy to initiate the formation of reactive iminium ion species from N‐phenyl benzylamine, thus driving the desired product formation. Mechanistic analysis has also unveiled the pivotal role of MoS2 QDs in generating reactive superoxide radicals from O2 through single electron transfer (SET), underscoring their significance in the process. Remarkably, this photocatalytic transformation furnishes a diverse array of functionalized products, expanding its applicability and potential implications in various contexts.

Isothermal Phase Transitions in Liquid Crystals Driven by Dynamic Covalent Chemistry

AbstractThe dynamic nature of calamitic liquid crystals is exploited to perform isothermal phase transitions driven by dynamic covalent chemistry. For this purpose, nematic (N) arrays based on aldehyde 1 were treated with different amines (A–E) in an on‐surface process, which resulted in different isothermal phase transitions. These phase transformations were caused by in situ imination reactions and are dependent on the nature of the added amine. Transitions from the N to crystal (1A, 1E), isotropic (1B), and smectic (Sm) (1C, 1D) phases were achieved, while the resulting materials feature thermotropic liquid crystal behavior. A sequential transformation from the N 1 to the Sm 1C and then to the N 1B was achieved by coupling an imination to a transimination processes and adjusting the temperature. All of these processes were well characterized by microscopic, spectroscopic, and X‐ray techniques, unlocking not only the constitutional but also the structural aspects of the phase transitions. This work provides new insights into designing constitutionally and structurally adaptable liquid crystal systems, paving the way toward the conception of programable evolutive pathways and adaptive materials.

Boosting primary amines renewable tandem synthesis via defect engineering of NiCo alloy

AbstractReductive amination of biomass aldehydes is a vital process to synthesize chemical intermediates primary amine, but the selectivity is severely compromised by the self‐condensation of highly reactive imine intermediates. Herein, we proposed a solution by manipulating the adsorption configuration of secondary imine via defect engineering. Specifically, a gradient reduction strategy was used to adjust the driving force of NiCo alloy crystallization, thus motivating the formation of metal vacancy clusters. The primary amine selectivity was raised from 70.9% to 95.1% with defect concentration increased from 36.1% to 42.5% on catalysts. In situ fourier transform infrared spectroscopy (FTIR) and density functional theory demonstrated metal vacancy clusters induced remarkable NiCo electron transfer, which strengthened electronic coupling between secondary imine with catalyst, resulting in a flat configuration that was conducive to CN bond breakage to guarantee smooth conversion into primary amines. This catalyst exhibited potential real‐life application prospects for its low cost, universality in reductive amination of various aldehydes, and long‐life reusability.

2-(((4-(Trifluoromethyl)quinolin-6-yl)amino)methyl)phenols: Synthesis, optical properties, thermal, and electrochemical behavior

This paper describes the synthesis, photophysical properties, and thermal and redox behavior of a novel series of nine selected 2-(((2-substituted-4-(trifluoromethyl)quinolin-6-yl)amino)methyl)phenols (4). These phenols contain 2-Me, 2-aryl, or 2-(2-furyl)-quinolines and 5-OMe, 4-Br or 4-NO2 substituted amino methylphenol cores assembled in the scaffolds of 4. Optimized yields of 51–98 % were obtained when the reactions of the respective imines 3 were conducted with sodium borohydride in ethanol at 80 °C for 30 min. The structural characterization of compounds 4 was performed by multinuclear NMR, FTIR, and HRMS techniques. Thermogravimetric analysis experiments indicated that the majority of the compounds obtained exhibited high thermal stability at temperatures over 200 °C. The UV–Vis steady-state and time-resolved fluorescence emission, TD-DFT calculations, and redox analyses were used to determine the photophysical and electrochemical properties of the studied derivatives, revealing a correlation between the electronic effects of the substituents attached to the quinoline and phenol cores and the evaluated parameters.

Catalytic Asymmetric Construction of Chiral Amines with Three Nonadjacent Stereocenters via Trifunctional Catalysis.

Pharmaceuticals and biologically active natural products usually contain multiple stereocenters. The development of catalytic asymmetric reactions for the direct construction of complex motifs containing three nonadjacent stereocenters is a particularly important and formidable challenge. In this paper, we report an unprecedented method for the direct asymmetric construction of complex chiral amines with 1,3,5- or 1,3,4-stereocenters from readily available achiral and racemic starting materials. The reaction was made possible by the development of highly efficient chiral ammonium catalysts that serve three distinct functions: promoting efficient kinetic resolution by chiral recognition of racemic electrophiles, promoting asymmetric C-C bond forming reactions by recognizing enantiotropic faces of achiral nucleophiles, and mediating a highly stereoselective protonation of carbanions. Using these trifunctional catalysts, the reaction of imines and tulipane derivatives proceeded in a highly regio-, chemo-, and stereoselective manner to produce synthetically useful yields of complex chiral amines. We believe that trifunctional catalysis can be applied in a variety of asymmetric transformations for the streamlined asymmetric synthesis of complex chiral molecules with multiple stereocenters.

Cover Feature: Experimental and Theoretical Studies on the Reactions of Aliphatic Imines with Isocyanates (Chem. Eur. J. 14/2024)

Cover Feature: Experimental and Theoretical Studies on the Reactions of Aliphatic Imines with Isocyanates (Chem. Eur. J. 14/2024)

Experimental and Theoretical Studies on the Reactions of Aliphatic Imines with Isocyanates.

In the context of a project aiming at the replacement of the 3-substituted β-lactam ring in classical β-lactam antibiotics by an N(3)-acyl-1,3-diazetidinone moiety, we have investigated the reaction of isocyanates with imines derived from allyl glycinate and differently substituted propionaldehydes. Imines of aromatic aldehydes with anilines have been reported to react with acyl isocyanates to give 1,3-diazetidinones or 2,3-dihydro-4H-1,3,5-oxadiazin-4-ones, via [2+2] or [4+2] cycloaddition, respectively. However, neither of these products was formed with imines derived from allyl glycinate and 2-(mono)methyl propionaldehydes. α,α-Dimethylation of the imine enabled the [4+2] cycloaddition pathway, but the desired 1,3-diazetidinone products were not observed. Surprisingly, the imines obtained from thioesters of 2,2-dimethyl 3-oxo propionic acid reacted with aryl isocyanates or with benzyl isocyanate to give 5,5-dimethyl-2,4-dioxo-6-(aryl-/alkylthio)tetrahydropyrimidines, via thiol displacement and re-addition to a putative six-membered iminium intermediate. These experimental results obtained for the reactions could be rationalized by DFT calculations. In addition, we have shown that N(3)-acyl-1,3-diazetidinone and 2,3-dihydro-4H-1,3,5-oxadiazin-4-one products can be distinguished based on experimental IR data in combination with theoretical reference spectra employing the IR spectra alignment (IRSA) algorithm. This discrimination was not possible by means of 1 H, 13 C, or 15 N NMR spectroscopy.

Nitrile Imines as Peptide and Oligonucleotide Photo-Cross-Linkers in Gas-Phase Ions.

Nitrile imines produced by photodissociation of 2,5-diaryltetrazoles undergo cross-linking reactions with amide groups in peptide-tetrazole (tet-peptide) conjugates and a tet-peptide-dinucleotide complex. Tetrazole photodissociation in gas-phase ions is efficient, achieving ca. 50% conversion with 2 laser pulses at 250 nm. The formation of cross-links was detected by CID-MS3 that showed structure-significant dissociations by loss of side-chain groups and internal peptide segments. The structure and composition of cross-linking products were established by a combination of UV-vis action spectroscopy and cyclic ion mobility mass spectrometry (c-IMS). The experimental absorption bands were found to match the bands calculated for vibronic absorption spectra of nitrile imines and cross-linked hydrazone isomers. The calculated collision cross sections (CCSth) for these ions were related to the matching experimental CCSexp from multipass c-IMS measurements. Loss of N2 from tet-peptide conjugates was calculated to be a mildly endothermic reaction with ΔH0 = 80 kJ mol-1 in the gas phase. The excess energy in the photolytically formed nitrile imine is thought to drive endothermic proton transfer, followed by exothermic cyclization to a sterically accessible peptide amide group. The exothermic nitrile imine reaction with peptide amides is promoted by proton transfer and may involve an initial [3 + 2] cycloaddition followed by cleavage of the oxadiazole intermediate. Nucleophilic groups, such as cysteine thiol, did not compete with the amide cyclization. Nitrile imine cross-linking to 2'-deoxycytidylguanosine was found to be >80% efficient and highly specific in targeting guanine. The further potential for exploring nitrile-imine cross-linking for biomolecular structure analysis is discussed.

Asymmetric aza-Henry reaction of BOC-protected imines with zinc-FAM catalyst

Derivatives of ferrocenyl-substituted aziridinyl methanol (FAM) ligands were used with zinc metal for asymmetric aza-Henry (nitro-aldol) reaction of N-Boc protected imines with nitroalkanes. At optimized reaction conditions Zn-PFAM1 catalyst system with a variety of aromatic imines provided products in up to 77% ee and 88% yield. In addition, the reaction of N-Boc substituted imines with nitroethane also proceeded smoothly with moderate enantioselectivities and diastereoselectivities.

On the mucoadhesive properties of synthetic and natural polyampholytes

HypothesisThe mucoadhesive characteristics of amphoteric polymers (also known as polyampholytes) can vary and are influenced by factors such as the solution's pH and its relative position against their isoelectric point (pHIEP). Whilst the literature contains numerous reports on mucoadhesive properties of either cationic or anionic polymers, very little is known about these characteristics for polyampholytes ExperimentsHere, two amphoteric polymers were synthesized by reaction of linear polyethylene imine (l-PEI) with succinic or phthalic anhydride and their mucoadhesive properties were compared to bovine serum albumin (BSA), selected as a natural polyampholyte. Interactions between these polymers and porcine gastric mucin were studied using turbidimetric titration and isothermal titration calorimetry across a wide range of pHs. Model tablets were designed, coated with these polymers and tested to evaluate their adhesion to porcine gastric mucosa at different pHs. Moreover, a retention study using fluorescein isothiocyanate (FITC)-labelled polyampholytes deposited onto mucosal surfaces was also conducted FindingsAll these studies indicated the importance of solution pH and its relative position against pHIEP in the mucoadhesive properties of polyampholytes. Both synthetic and natural polyampholytes exhibited strong interactions with mucin and good mucoadhesive properties at pH < pHIEP.

Key structural features to favour imines over hydrates in water: pyridoxal phosphate as a muse.

Imination reactions in water represent a challenge not only because of the high propensity of imines to be hydrolysed but also as a result of the competing hydrate formation through H2O addition to the aldehyde. In the present work we report a successful approach that allows for favouring imitation reactions while silencing hydrate formation. Such remarkable reactivity and selectivity can be attained by fine-tuning the electronic and steric structural features of the ortho-substituents of the carbonyl groups. It resulted from studying the structure-reactivity relationships in a series of condensation reactions between different amines and aldehydes, comparing the results to the ones obtained in the presence of the biologically-relevant pyridoxal phosphate (PLP). The key role of negatively-charged and sterically-crowding units (i.e., sulfonate groups) in disfavouring hydrate formation was corroborated by DFT and steric-hindrance calculations. Furthermore, the best-performing aldehyde leads to higher imine yields, selectivity and stability than those of PLP itself, allowing for the inhibition of a PLP-dependent enzyme (transaminase) through dynamic aldimine exchange. These results will increase the applicability of imine-based dynamic covalent chemistry (DCvC) under physiological conditions and will pave the way for the design of new carbonyl derivatives that might be used in the dynamic modification of biomolecules.

Enantioselective synthesis of α-tetrasubstituted (1-indolizinyl) (diaryl)-methanamines via chiral phosphoric acid catalysis.

An enantioselective Friedel-Crafts reaction of cyclic α-diaryl N-acyl imines with indolizines catalyzed by a chiral spirocyclic phosphoric acid has been developed. The asymmetric transformation proceeds smoothly to afford α-tetrasubstituted (1-indolizinyl) (diaryl)methanamines in good yields with up to 98% ee under mild conditions.

Visible-light-induced catalyst-free reductive coupling of aldehydes, ketones and imines with cyanopyridines.

This article introduces a reductive coupling driven by visible-light, facilitating the synthesis of pyridine-substituted alcohols and amines through the reaction of aldehydes, ketones and imines with cyanopyridines. Hantzsch esters serve as reductants in this process, eliminating the need for transition-metals or photosensitizers. The method demonstrates extensive compatibility and finds utility in the late-stage functionalization of both natural and pharmaceutical products, offering a sustainable pathway for the diversification of chemical compounds.

Transformation of PMMA from sunlight-blocking to sunlight-activated coupled with DNH photocatalytic platform for oxidative coupling of amines and generation/regeneration of LDC/NADH.

The photocatalytic oxidation and generation/regeneration of amines to imines and leucodopaminechrome (LDC)/NADH are subjects of intense interest in contemporary research. Imines serve as crucial intermediates for the synthesis of solar fuels, fine chemicals, agricultural chemicals, and pharmaceuticals. While significant progress has been made in developing efficient processes for the oxidation and generation/regeneration of secondary amines, the oxidation of primary amines has received comparatively less attention until recently. This discrepancy can be attributed to the high reactivity of imines generated from primary amines, which are prone to dehydrogenation into nitriles. In this study, we present the synthesis and characterization of a novel polymer-based photocatalyst, denoted as PMMA-DNH, designed for solar light-harvesting applications. PMMA-DNH incorporates the light-harvesting molecule dinitrophenyl hydrazine (DNH) at varying concentrations (5%, 10%, 20%, 30%, and 40%). Leveraging its high molar extinction coefficient and slow charge recombination, the 30% DNH-incorporated PMMA photocatalyst proves to be particularly efficient. This photocatalytic system demonstrates exceptional yields (96.5%) in imine production and high generation/regeneration rates for LDC/NADH (65.27%/78.77%). The research presented herein emphasizes the development and application of a newly engineered polymer-based photocatalyst, which holds significant promise for direct solar-assisted chemical synthesis in diverse commercial applications.

Construction of Polyheterocyclic Skeletons through C−H Bond Activation‐Initiated Cascade Reactions by Using Cyclopropanol as Alkylating Agent as well as Masked Nucleophile and Electrophile

AbstractPresented herein is a synthesis of indane fused bicyclic pyrazolidinones based on the reactions of aryl azomethine imines with cyclopropanols. Mechanistically, the formation of product involves Rh(III)‐catalyzed direct aryl C(sp2)−H alkylation of aryl azomethine imine with cyclopropanol through in situ ring‐opening, followed by cascade intramolecular C‐ and N‐nucleophilic addition. In this tandem process, cyclopropanol acts as not only an alkylating agent but also masked nucleophile and electrophile to participate in the construction of both the indane and the bicyclic pyrazolidinone scaffolds. To our knowledge, such a cascade reaction pattern has not been disclosed. In general, this synthetic protocol has advantages such as easily obtainable substrates, valuable products, concise synthetic procedure, unique reaction pathway, and good compatibility with diverse functional groups.