Search Results (49)

Dietary bioactive compounds are increasingly explored as complementary cardioprotective strategies, and the nitration of unsaturated fatty acids has emerged as a process capable of enhancing antiplatelet properties. This study investigated whether Phaseolus vulgaris L. extracts can generate nitrated fatty acids under gastric-like conditions and evaluated their effects on human platelet function. Bean extracts and major fatty acids were nitrated in vitro and tested using washed platelets to assess cytotoxicity, TRAP-6 and collagen-induced aggregation, activation markers (P-selectin, CD63), and mitochondrial responses including membrane potential, ROS production, and Ca²⁺ dynamics. Nitrated extracts markedly inhibited TRAP-6 induced aggregation (IC₅₀ ≈ 1.8 mg/mL), whereas non-nitrated extracts showed minimal activity; this effect was reversed by β-mercaptoethanol, indicating dependence on electrophilic nitroalkenes. Fractionation revealed that the lipidic fraction accounted for most of the antiplatelet effect, and isolated nitrated fatty acids (NO₂-LN, NO₂-LA, NO₂-OA) displayed stronger inhibition than their native counterparts without increasing cytotoxicity. Nitrated species additionally reduced mitochondrial membrane potential and granule secretion without elevating ROS. These findings identify Phaseolus vulgaris L. as a natural source of bioactive nitrated fatty acids and support their potential as nutraceutical agents capable of modulating platelet activation and contributing to cardiovascular risk reduction. Full article

Amino acid derivatives, such as β-keto esters and pyrrolones, were used as nucleophiles in organocatalyzed Michael additions to nitroalkene acceptors, while fatty acid derivatives acted as both nucleophiles (β-keto esters) and electrophiles (nitroalkene acceptors). Bifunctional noncovalent organocatalysts were employed as asymmetric organocatalysts. Twenty compounds—including fatty acid and amino acid derivatives, as well as fatty acid–amino acid conjugates—were prepared with enantioselectivities of up to 98% ee. All novel products were fully characterized. This research demonstrates the ease of assembling readily available fatty acid and amino acid building blocks under ambient conditions. Full article

We investigated the Diels-Alder cycloaddition of methylcyclopentadiene with conjugated nitroalkenes and examined the influence of solvent polarity and substituent effects on the reaction mechanism. In nonpolar media (toluene), pathways A and C proceed via a pre-reactive molecular complex (MC), two transition states, and a heterocyclic intermediate, whereas pathways B and D follow a single-transition-state route directly to the norbornene product. Moderate increases in solvent polarity (acetone) do not qualitatively alter the energy profiles or mechanistic patterns, whereas highly polar solvents (methanol, acetonitrile, water, nitromethane) induce a fundamental transformation in pathway B, which adopts a stepwise, zwitterionic mechanism. NPA, MEP, and NCI analyses confirm the polar, charge-separated nature of the zwitterionic intermediate, while BET analysis elucidates the sequential electronic reorganization, highlighting early polarization toward the nitro fragment and stepwise formation of the C-C bonds. Substituent effect studies using Hammett σ parameters reveal that electron-withdrawing groups lower activation barriers, whereas electron-donating groups increase them, indicating that electronic effects dominate over steric factors. Overall, the study demonstrates a general, solvent- and substituent-dependent Diels-Alder mechanism, with pathway B proceeding through a polar, highly asynchronous, stepwise route involving a zwitterionic intermediate. Full article

The kinetic aspects and molecular mechanism of the thermal decomposition of nitroalkyl phosphates were evaluated on the basis of DFT quantum-chemical calculations at the ωb97xd/6-311G(d,p) (PCM) level of theory. These reactions were found to proceed via a single-step mechanism with a six-membered transition state. This mechanism is similar to the mechanism of the elimination reaction of carboxylic acids from their esters. However, this is not a pericyclic mechanism. BET studies have shown that migration of hydrogen takes place before the breaking of the C-O bond. The effect of substituents on the nitroalkyl moiety of the ester on the reaction kinetics was also explored. Based on the obtained results, this mechanism can be proposed as general for a wider group of compounds. Full article

The relative reactivity of the nitrovinyl molecular segment characterized by the “cis” orientation of nitro group and the aryl ring was evaluated based on the experimental and Density Functional Theory quantum chemical data. It was found that, on the contrary to E-R-nitroethenes, the Z-2-Ar-1-EWG-1-nitroethene molecular segment is not planar. This fact reduces the possibility of the conjugation of π-electron systems, and as a consequence, decreases the global reactivity. Due to these conditions, the reaction of the model ethyl 4,β-dinitrocinnamate and 2-methylenecyclopentane is realized as a very difficult process; however, with full regioselectivity, it leads to the expected (4 + 2) hetero Diels–Alder cycloadduct. Bonding Evolution Theory studies show that the first new C4-C5 single bond is formed in Phase VIII by merging two pseudoradical centers. In turn, the second C6-O1 single bond is formed in last phase of the reaction, by the depopulation of V(C6), V(O1) and V’(O1) monosynaptic basins. According to this, the title reaction was classified as a process carried out according to a “one-step two-stage” mechanism. Full article

Sulfur-containing heterocyclic structures play an important role in modern biotechnology. Their synthesis is made possible by means of the hetero Diels–Alder reaction involving unsaturated sulfur compounds. In the framework of this paper, the molecular mechanism of the cycloaddition reactions between tioanalogs of the butadiene generated in situ with the participation of the Lawesson reagent and the E-2-phenyl-1-nitroethene was evaluated on the basis of the DFT quantum chemical calculations. It was found that the most favored reaction path is realized according to a stepwise mechanism with the participation of the zwitterionic intermediate. To study this further, the molecular mechanism of the deamination process of the primary cycloadducts was also analyzed. It was found that this mechanism is substantially different to the case of other known β-elimination processes and is achieved via a stepwise scheme. In addition to these investigations, the LA catalysis of the deamination process was also explored. Full article

This study presents a theoretical investigation of the electronic properties of mono- and pentasubstituted cyclopentadiene analogs and variously substituted conjugated nitroalkenes bearing electron-donating and electron-withdrawing groups. Conceptual Density Functional Theory (CDFT) and Electron Localization Function (ELF) analyses were employed to characterize the global and local reactivity indices of the reactants. The obtained data provided insights into the nucleophilic and electrophilic nature of the investigated systems, allowing for the prediction of their reactivity patterns in Diels–Alder reactions. A reactivity model for conjugated alkenes toward cyclopentadienes was developed based on correlation analysis using Hammett substituent constants. This approach enabled the prediction of reaction polarity in (4+2) cycloaddition processes, providing insight into how the electronic effects of substituents influence the reaction course. These findings contribute to a deeper understanding of structure–reactivity relationships in Diels–Alder processes. Full article

The phenomena of regio- and stereoselectivity and the molecular mechanism of the [2 + 2] cycloaddition reaction between (E)-2-arylnitroethenes and the ynamine molecular system were analyzed using wb97xd/6-311 + G(d) (PCM) quantumchemical calculations. It was found that, independently of the stepwise nature of the cycloaddition, the full retention of the stereoconfiguration of the nitroalkene can be interpreted and explained. Next, the analysis of the electronic properties of the localized reaction intermediate suggests its possible zwitterionic nature. Additionally, the solvent and the substituent effect on the reaction course were also evaluated. In consequence, the proposed mechanism can be treated as general for some groups of [2 + 2] cycloaddition processes. Lastly, for the model process, the full Bonding Evolution Theory (BET) analysis along the reaction coordinate was performed. It was found that the [2 + 2] cycloaddition reaction between (E)-2-phenylonitroethene and ynamine begins with the formation of two pseudoradical centers at the C2 and C3 atoms. First, a C2-C3 single bond is formed in phase V by combining two pseudoradical centers, while the formation of a second C4-C1 single bond begins at the last, eleventh phase of the reaction path. A BET analysis of intermediate (I) allows it to be classified as a compound with a pseudoradical structure. Next to zwitterions and biradicals, it is evidently new type of intermediate on the path of the [2 + 2] cycloaddition reaction. Full article

The search for new heterocyclic compounds with biological potential is one of the current challenges in modern chemistry. Therefore, the comprehensive study of (3 + 2) cycloaddition (32CA) reactions between a series of aryl-substituted nitrile N-oxides (NOs) and (E)-3,3,3-tribromo-1-nitroprop-1-ene (TBNP) is carried out. According to the experimental research, in all tested 32CAs, the proper (4RS,5RS)-3-aryl-4-nitro-5-tribromomethyl-2-isoxazolines are obtained as only one reaction product. In turn, the quantum–chemical MEDT study shows that the creation of heterocycles occur via the polar attack of zwitterionic moderate-nucleophilic NOs to strong electrophilic TBNP. The reactions are realized according to a two-stage, one-step asynchronous mechanism, in which the formation of the O-C(CBr₃) bond takes place once the C-C(NO₂) bond is already formed. What is more, the computational analysis confirmed the experimental results. At the end, the obtained 2-isoxazolines were docked to three proteins: gelatinase B, cyclooxygenase COX-1, and Caspase-7. We hope that the presented study will be helpful for searching for the future direction of application for this class of organic compounds. Full article

The regio- and stereoselectivity and the molecular mechanisms of the [3 + 2] cycloaddition reactions between Syn-propanethial S-oxide and selected conjugated nitroalkenes were explored theoretically in the framework of the Molecular Electron Density Theory. It was found that cycloadditions with the participation of nitroethene as well as its methyl- and chloro-substituted analogs can be realized via a single-step mechanism. On the other hand, [3 + 2] cycloaddition reactions between Syn-propanethial S-oxide and 1,1-dinitroethene can proceed according to a stepwise mechanism with a zwitterionic intermediate. Finally, we evaluated the affinity of model reaction products for several target proteins: cytochrome P450 14α-sterol demethylase CYP51 (RSCB Database PDB ID: 1EA1), metalloproteinase gelatinase B (MMP-9; PDB ID: 4XCT), and the inhibitors of cyclooxygenase COX-1 (PDB:3KK6) and COX-2 (PDB:5KIR). Full article

The molecular mechanism of the reaction between 2-methoxyfuran and ethyl (Z)-3-phenyl-2-nitroprop-2-enoate was investigated using wb97xd/6-311+G(d,p)(PCM) quantum chemical calculations. It was found that the most probable reaction mechanism is fundamentally different from what was previously postulated. In particular, six possible zwitterionic intermediates were detected on the reaction pathway. Their formation is determined by the nature of local nucleophile/electrophile interactions. Additionally, the channel involving the formation of the exo-nitro Diels–Alder cycloadduct was completely ruled out. Finally, the electronic nature of the five- and six-membered nitronates as potential TACs was evaluated. Full article

H-bonding has achieved massive advancements by utilizing an H-bond donor (HBD) to interact with the electron-rich site of the substrate, and an H-bond acceptor (HBA) to coordinate with the electron-deficient site. Rapid transformation is often correlated with the acidity of HBD, namely the degree of charge deficiency of the hydrogen proton. In addition, the positive cations were employed to enhance the HBD; the electron-withdrawing groups were also a dissimilar approach for increasing the capability of the H-bond donor. We first introduced the H-bonding organic ion pair tris(phenylamino)cyclopropenium (TPAC·Cl) into the Friedel–Crafts alkylation of indoles with nitroalkenes, which was implemented via vicinal positive charges on the cyclopropenium core. The counter ion chloride anion became a potential HBA to activate the electron-deficient part of the substrate. X-ray analyses of a single crystal of TPAC·Cl described the 3D architecture and the delocalized cationic charge in the solid state. The aromatic cyclopropenium endowed the N–H moieties with the ability of the H-bond donor to activate the nitroalkene; meanwhile, the chloride anion acted as the H-bond acceptor to activate the indole. The amino-cyclopropenium-offered HBD and HBA displayed cooperative organocatalysis in the Friedel–Crafts alkylation of indole with nitroalkene. A new class of hydrogen bonding catalysis and a working mechanism were proposed. Full article

The molecular mechanism of the Diels–Alder reaction with the participation of cyclopentadiene and isopropyl 3-nitroprop-2-enate was examined based on wb97xd/6-311+G(d) (PCM) quantum chemical calculations. It was found that the type of mechanism for the conversion of addends depends significantly on the reaction conditions. In less-polar environments, a one-step polar mechanism is realised. In more polar solvents, the formation of “extended”-type zwitterionic intermediates is possible. In contrast, in the presence of an LA-type catalyst, the one-step mechanisms are replaced by respective stepwise mechanisms with zwitterionic or heterocyclic intermediates. Full article

Hetero Diels-Alder (HDA) reactions with the participation of E-2-aryl-1-cyano-1-nitroethenes and methylenecyclopentane were evaluated on the basis of experimental as well as quantumchemical data. It was found that contrary to most known HDA reactions, title processes are realised under non-catalytic conditions and with full regiocontrol. The DFT study shows, without any doubt, the polar but single-step reaction mechanism. Deeper exploration using Bonding Evolution Theory (BET) techniques gives a clear image of the sequences of electron density reorganisation along the reaction coordinate. The first C4-C5 bond is created in phase VII by merging two monosynaptic basins, while the second O1-C6 bond is created in the last phase by a donation of the nonbonding electron density of O1 to C6. Based on the research, we can conclude that the analysed reaction proceeds according to a two-stage one-step mechanism. Full article

[3 + 2] Cycloaddition reactions with the participation of Z-C-(3-pyridyl)-N-methylnitrone and series of E-2-R-nitroethenes were both experimentally and theoretically explored in the framework of Molecular Electron Density Theory. It was found that all considered processes are realized under mild conditions and in full regio- and stereocontrol. The ELF analysis additionally showed that the studied reaction proceeds by a two-stage, one-step mechanism. Full article