Chalcone Derivatives with a High Potential as Multifunctional Antioxidant Neuroprotectors.

A systematic, rational search for chalcone derivatives with multifunctional behavior has been carried out, with the support of a computer-assisted protocol (CADMA-Chem). A total of 568 derivatives were constructed by incorporating functional groups into the chalcone structure. Selection scores were calculated from ADME properties, toxicity, and manufacturability descriptors. They were used to select a subset of molecules (23) with the best drug-like behavior. Reactivity indices were calculated for this subset. They were chosen to account for electron and hydrogen atom donating capabilities, which are key processes for antioxidant activity. The indexes showed that four chalcone derivatives (dCHA-279, dCHA-568, dCHA-553, and dCHA-283) are better electron and H donors than the parent molecule and some reference antioxidants (Trolox, ascorbic acid, and α-tocopherol). In addition, based on molecular docking, they are predicted to act as catechol-O-methyltransferase (COMT), acetylcholinesterase (AChE), and monoamine oxidase B (MAO-B) inhibitors. Therefore, these four molecules are proposed as promising candidates to act as multifunctional antioxidants with neuroprotective effects.

CADMA-Chem: A Computational Protocol Based on Chemical Properties Aimed to Design Multifunctional Antioxidants.

A computational protocol aimed to design new antioxidants with versatile behavior is presented. It is called Computer-Assisted Design of Multifunctional Antioxidants and is based on chemical properties (CADMA-Chem). The desired multi-functionality consists of in different methods of antioxidant protection combined with neuroprotection, although the protocol can also be used to pursue other health benefits. The dM38 melatonin derivative is used as a study case to illustrate the protocol in detail. This was found to be a highly promising candidate for the treatment of neurodegeneration, in particular Parkinson's and Alzheimer's diseases. This also has the desired properties of an oral-drug, which is significantly better than Trolox for scavenging free radicals, and has chelates redox metals, prevents the ●OH production, via Fenton-like reactions, repairs oxidative damage in biomolecules (lipids, proteins, and DNA), and acts as a polygenic neuroprotector by inhibiting catechol-O-methyl transferase (COMT), acetylcholinesterase (AChE) and monoamine oxidase B (MAOB). To the best of our best knowledge, CADMA-Chem is currently the only protocol that simultaneously involves the analyses of drug-like behavior, toxicity, manufacturability, versatile antioxidant protection, and receptor-ligand binding affinities. It is expected to provide a starting point that helps to accelerate the discovery of oral drugs with the potential to prevent, or slow down, multifactorial human health disorders.

Antioxidants into Nopal (Opuntia ficus-indica), Important Inhibitors of Free Radicals' Formation.

Nopal (Opuntia ficus indica) belonging to the Cactacea family has many nutritional benefits attributed to a wide variety of phenolic and flavonoid compounds. Coumaric acid (COA), ferulic acid (FLA), protocatechuic acid (PRA), and gallic acid (GAA) are the phenolic acids (PhAs) present in nopal. In this study, the role of these PhAs in copper-induced oxidative stress was investigated using the density functional theory (DFT). The PhAs form 5 thermodynamically favorable complexes with Cu(II), their conditional Gibbs free energies of reaction (ΔG', at pH = 7.4, in kcal/mol) are from -23 kcal/mol to -18 kcal/mol. All of them are bi-dentate complexes. The complexes of PRA and GAA are capable of inhibiting the Cu(II) reduction by both O2•- and Asc-, their reactions with the chelated metal are endergonic having rate constants about ~10-5-102 M-1 s-1, PhAs can prevent the formation of hydroxyl free radicals by chelating the copper ions. Once the hydroxyl radicals are formed by Fenton reactions, the complexes of PhAs with Cu(II) can immediately react with them, thus inhibiting the damage that they can cause to molecules of biological interest. The reactions between PhAs-Cu(II) complexes and hydroxyl free radical were estimated to be diffusion-limited (~108 M-1s-1). Thus, these chelates can reduce the harmful effects caused by the most reactive free radical existent immediately after it is formed by Fenton reactions.

Capsaicin, a Powerful •OH-Inactivating Ligand.

Oxidative conditions are frequently enhanced by the presence of redox metal ions. In this study, the role of capsaicin (8-methyl-N-vanillyl-6-nonenamide, CAP) in copper-induced oxidative stress was investigated using density functional theory simulations. It was found that CAP has the capability to chelate Cu(II), leading to complexes that are harder to reduce than free Cu(II). CAP fully turns off the Cu(II) reduction by Asc-, and slows down the reduction in this cation by O2•-. Therefore, CAP is proposed as an •OH-inactivating ligand by impeding the reduction in metal ions (OIL-1), hindering the production of •OH via Fenton-like reactions, at physiological pH. CAP is also predicted to be an excellent antioxidant as a scavenger of •OH, yielded through Fenton-like reactions (OIL-2). The reactions between CAP-Cu(II) chelates and •OH were estimated to be diffusion-limited. Thus, these chelates are capable of deactivating this dangerous radical immediately after being formed by Fenton-like reactions.

The antioxidant capacity of an imidazole alkaloids family through single-electron transfer reactions.

The single-electron transfer (SET) reactions from the neutral and mono-anion species of five imidazole alkaloids (lepidines A, B, C, D, and E) against hydroperoxyl radicals have been studied using the density functional theory and the Marcus theory. The deprotonated species of three alkaloids were found to have free radical scavenging activity. The antioxidant activity was studied via single-electron transfer (SET) under physiological conditions. The SET reactions for lepidines B, D, and E were found to have rate constants ranging from 105 to 106 M-1 s-1. Therefore, they are predicted to be able to deactivate hydroperoxyl radicals and therefore the damage caused by them to polyunsaturated fatty acids. It is important to mention that the acid-base equilibrium plays an important role in their free radical scavenging activity. Graphical abstract Lepidines are predicted to be able to deactivate hydroperoxyl radicals and the damage caused by them to polyunsaturated fatty acids.

Melatonin and its metabolites as chemical agents capable of directly repairing oxidized DNA.

Oxidative stress mediates chemical damage to DNA yielding a wide variety of products. In this work, the potential capability of melatonin and several of its metabolites to repair directly (chemically) oxidative lesions in DNA was explored. It was found that all the investigated molecules are capable of repairing guanine-centered radical cations by electron transfer at very high rates, that is, diffusion-limited. They are also capable of repairing C-centered radicals in the sugar moiety of 2'-deoxyguanosine (2dG) by hydrogen atom transfer. Although this was identified as a rather slow process, with rate constants ranging from 1.75 to 5.32 × 102  M-1 s-1 , it is expected to be fast enough to prevent propagation of the DNA damage. Melatonin metabolites 6-hydroxymelatonin (6OHM) and 4-hydroxymelatonin (4OHM) are also predicted to repair OH adducts in the imidazole ring. In particular, the rate constants corresponding to the repair of 8-OH-G adducts were found to be in the order of 104  M-1 s-1 and are assisted by a water molecule. The results presented here strongly suggest that the role of melatonin in preventing DNA damage might be mediated by its capability, combined with that of its metabolites, to directly repair oxidized sites in DNA through different chemical routes.

Comprehensive Investigation of the Antioxidant and Pro-oxidant Effects of Phenolic Compounds: A Double-Edged Sword in the Context of Oxidative Stress?

Oxidative stress (OS) is a health-threatening process that is involved, at least partially, in the development of several diseases. Although antioxidants can be used as a chemical defense against OS, they might also exhibit pro-oxidant effects, depending on environmental conditions. In this work, such a dual behavior was investigated for phenolic compounds (PhCs) within the framework of the density functional theory and based on kinetic data. Multiple reaction mechanisms were considered in both cases. The presence of redox metals, the pH, and the possibility that PhCs might be transformed into benzoquinones were identified as key aspects in the antioxidant versus pro-oxidant effects of these compounds. The main virtues of PhCs as antioxidants are their radical trapping activity, their regeneration under physiological conditions, and their behavior as OH-inactivating ligands. The main risks of PhCs as pro-oxidants are predicted to be the role of phenolate ions in the reduction of metal ions, which can promote Fenton-like reactions, and the formation of benzoquinones that might cause protein arylation at cysteine sites. Although the benefits seem to overcome the hazards, to properly design chemical strategies against OS using PhCs, it is highly recommended to carefully explore their duality in this context.

Radical-trapping and preventive antioxidant effects of 2-hydroxymelatonin and 4-hydroxymelatonin: Contributions to the melatonin protection against oxidative stress.

BACKGROUND: Melatonin is well known for its antioxidant capacity, which has been attributed to the combined protective effects of the parent molecule and its metabolites. However, the potential role of 2-hydroxymelatonin (2OHM) and 4-hydroxymelatonin (4OHM) in such protection has not been previously investigated. METHODS: The calculations were performed using the Density Functional Theory, with the M05-2X and M05 functionals, the 6-311+G(d,p) basis set and the solvation model based on density (SMD). RESULTS: 4OHM shows excellent antioxidant activity via radical-trapping, reacting with peroxyl radicals faster than Trolox and melatonin. 4OHM can be moderately efficient as a preventing antioxidant by inhibiting Cu(II). This effect would lower the Cu(I) availability, which is the redox state required for the OH to be formed, via Fenton-like reactions. 4OHM turns off the oxidant effects of copper-ascorbate mixtures. The presence of a phenolic group was identified as the key structural feature in the antioxidant activity of 4OHM. On the other hand, 2OHM does not present a phenolic group, despite its formal name. Its keto tautomer was identified as the most abundant one (~100%). This may explain the relative low antioxidant protection of 2OHM. CONCLUSIONS: 4OHM significantly contributes to the overall antioxidant activity exhibited by melatonin, while the effects of 2OHM in this context are predicted to be only minor. This low reactivity might justify the relatively large abundance of 2OHM in biological systems. GENERAL SIGNIFICANCE: Hydroxylated melatonin metabolites, such as 4OHM, may play an important role in the protective effects of melatonin against oxidative stress.

Direct and cluster-assisted dehydrogenation of methane by Nb+ and Ta+: a theoretical investigation.

DFT calculations have been performed to examine both direct and cluster-assisted methane C-H bond activation by Nb+ and Ta+ cations. The commonly accepted dehydrogenation pathways, that are oxidative addition and reductive elimination, have been studied in detail for methane ligated clusters M(CH4)n+ (M = Nb, Ta and n = 1-4). For the second H atom transfer to the metal in the presence of additional CH4 molecules (n > 1) two alternative routes have been explored. Energy profiles for ground quintet and excited triplet and singlet spin states of both Nb+ and Ta+ cations have been calculated. Spin crossings occur for all the examined pathways. Clustering of methane ligands appears to favorably affect the process stabilizing all the intercepted minima and transition states and bringing all the calculated PESs below the reference energy of the separated reactants. The direct activation of methane (n = 1) can proceed efficiently only for Ta+, whereas dehydrogenation is endothermic for Nb+ by 9.0 kcal mol-1. When assisted by additional methane ligands, the dehydrogenation process becomes exothermic for both cations whatever the number of coordinated molecules.

Phenolic Melatonin-Related Compounds: Their Role as Chemical Protectors against Oxidative Stress.

There is currently no doubt about the serious threat that oxidative stress (OS) poses to human health. Therefore, a crucial strategy to maintain a good health status is to identify molecules capable of offering protection against OS through chemical routes. Based on the known efficiency of the phenolic and melatonin (MLT) families of compounds as antioxidants, it is logical to assume that phenolic MLT-related compounds should be (at least) equally efficient. Unfortunately, they have been less investigated than phenols, MLT and its non-phenolic metabolites in this context. The evidence reviewed here strongly suggests that MLT phenolic derivatives can act as both primary and secondary antioxidants, exerting their protection through diverse chemical routes. They all seem to be better free radical scavengers than MLT and Trolox, while some of them also surpass ascorbic acid and resveratrol. However, there are still many aspects that deserve further investigations for this kind of compounds.

Empirically Fitted Parameters for Calculating pKa Values with Small Deviations from Experiments Using a Simple Computational Strategy.

Two empirically fitted parameters have been derived for 74 levels of theory. They allow fast and reliable pKa calculations using only the Gibbs energy difference between an acid and its conjugated base in aqueous solution (ΔGs(BA)). The parameters were obtained by least-squares fits of ΔGs(BA) vs experimental pKa values for phenols, carboxylic acids, and amines using training sets of 20 molecules for each chemical family. Test sets of 10 molecules per family-completely independent from the training set-were used to verify the reliability of the fitting parameters method. It was found that, except for MP2, deviations from experiments are lower than 0.5 pKa units. Moreover, mean unsigned errors lower than 0.35 pKa units were found for the 98.6%, 98.6%, and 94.6% of the tested levels of theory for phenols, carboxylic acids and amines, respectively. The parameters estimated here are expected to facilitate computationally based estimations of pKa values of species for which this magnitude is still unknown, with uncertainties similar to the experimental ones. However, the present study deals only with molecules of modest complexity, thus the reliability of the FP method for more complex systems remains to be tested.

Free-radical scavenging by tryptophan and its metabolites through electron transfer based processes.

Free-radical scavenging by tryptophan and eight of its metabolites through electron transfer was investigated in aqueous solution at physiological pH, using density functional theory and the Marcus theory. A test set of 30 free radicals was employed. Thermochemical and kinetic data on the corresponding reactions are provided here for the first time. Two different pathways were found to be the most important: sequential proton loss electron transfer (SPLET) and sequential double proton loss electron transfer (SdPLET). Based on kinetic analyses, it is predicted that the tryptophan metabolites kynurenic acid and xanthurenic acid are the best free-radical scavengers among the tested compounds; they were estimated to be at least 24 and 12 times more efficient than Trolox for scavenging (•)OOH. These findings are in line with previous reports suggesting that the antioxidant activity that has been attributed to tryptophan is actually due to its metabolites, and they demonstrate the particular importance of phenolic metabolites to such activity. Graphical Abstract Kynurenic acid (KNA) and xanthurenic acid (XNA) are the major contributors to the free-radical scavenging activity of tryptophan.

On the chemical behavior of C60 hosting H2O and other isoelectronic neutral molecules.

The density functional theory (DFT) was used to investigate the chemical behavior of C60 hosting neutral guest molecules (NGM). The deformed atoms in molecules (DAM) allowed identifying the regions of electron density depletion and accumulation. The studied NGM are CH4, NH3, H2O, and HF. Based on dipole moment and polarizabilities analyses it is predicted that the NGM@C60 should be more soluble in polar solvents than C60. The deformations on the surface electron density of the fullerenes explain this finding, which might be relevant for further applications of these systems. It was found that the intrinsic reactivity of studied NGM@C60 is only moderately higher than that of C60. This trend is supported by the global reactivity indexes and the frontier orbitals analyses. The free radical scavenging activity of the studied systems, via single electron transfer, was found to be strongly dependent on the chemical nature of the reacting free radical. The presence of the studied NGM inside the C60 influences only to some extent the reactivity of C60 toward free radicals. The distortion of the electron density on the C60 cage, caused by the NGM, is directly related to the electron withdrawing capacity of the later.

Vertical ionization energies of free radicals and electron detachment energies of their anions: a comparison of direct and indirect methods versus experiment.

The performance of several direct and indirect computational strategies for the calculation of the first ionization energies (IEs) of free radicals and adiabatic detachment energies of their anions has been tested using experimental data as references. The outer valence Green's function and the partial third-order approximations, which are based on electron propagator theory, have been identified as the most accurate. They were in turn used to estimate the IEs of a large set of free radicals for which these data have not been previously reported. The calculated data also have been used to assess the possible oxidation of nucleosides by these radicals, as well as the potential, antioxidant-protection effects of phenol, catechol, ascorbic acid, and Trolox in their neutral and deprotonated forms, via electron transfer.

Ellagic acid: an unusually versatile protector against oxidative stress.

Several aspects related to the antioxidant activity of ellagic acid were investigated using the density functional theory. It was found that this compound is unusually versatile for protecting against the toxic effects caused by oxidative stress. Ellagic acid, in aqueous solution at physiological pH, is able of deactivating a wide variety of free radicals, which is a desirable capability since in biological systems, these species are diverse. Under such conditions, the ellagic acid anion is proposed as the key species for its protective effects. It is predicted to be efficiently and continuously regenerated after scavenging two free radicals per cycle. This is an advantageous and unusual behavior that contributes to increase its antioxidant activity at low concentrations. In addition, the ellagic acid metabolites are also capable of efficiently scavenging a wide variety of free radicals. Accordingly, it is proposed that the ellagic acid efficiency for that purpose is not reduced after being metabolized. On the contrary, it provides continuous protection against oxidative stress through a free radical scavenging cascade. This is an uncommon and beneficial behavior, which makes ellagic acid particularly valuable to that purpose. After deprotonation, ellagic acid is also capable of chelating copper, in a concentration dependent way, decreasing the free radical production. In summary, ellagic acid is proposed to be an efficient multiple-function protector against oxidative stress.

On the outstanding antioxidant capacity of edaravone derivatives through single electron transfer reactions.

The single electron transfer (SET) reactions from the neutral and anionic forms of 27 edaravone derivatives to 11 free radicals have been studied using density functional theory and the Marcus theory. All of the studied compounds were found to be able to efficiently scavenge at least some of the studied radicals. More than half of them were found to be excellent free radical scavengers, via SET, under physiological conditions. Their SET reactions with all the studied radicals were found to have rate constants ranging from 10(6) to 10(9) M(-1) s(-1) (diffusion limited). Therefore, they are predicted to be versatile scavengers, able to deactivate free radicals of different nature. Functionalizing the R1 and R3 sites of the pyrazol-5-one ring with the NO group is not recommended for edaravone derivatives designed as free radical scavengers through the SET mechanism. In general, this family of compounds was found to be exceptionally good for scavenging free radicals by transferring one electron. Moreover they are predicted to be outstanding scavengers, even if they would only react by SET. In addition, the acid-base equilibrium was found to play an important role in their activity.

Ionization energies, proton affinities, and pKa values of a large series of edaravone derivatives: implication for their free radical scavenging activity.

The electron-donating capability (EDC) and the ease of deprotonation (ED) of 26 edaravone derivatives have been evaluated. Their first ionization energies have been used to assess their EDC. Four different approaches to obtain vertical ionization energies were tested, using a set of structurally related compounds. Those based on the electron propagator theory (EPT) were identified as the best ones. In particular, the partial third order (P3) approximation led to the lowest mean unsigned error (MUE = 0.10 eV). Two descriptors were used to evaluate ED: the proton affinity (PA) and the pK(a). It was found that pK(a) values are better descriptors than PA values. Ideal candidates to perform as efficiently as, or even better than, edaravone itself are proposed. The recommendations were based on the simultaneous analyses of EDC and ED, and they should be particularly valid when the electron transfer mechanism plays an important role in the antioxidant activity of the studied compounds.

OH radical scavenging activity of Edaravone: mechanism and kinetics.

The reactions of OH radicals with the neutral and anionic forms of Edaravone (3-methyl-1-phenyl-2-pyrazolin-5-one, EDA) have been studied using Density Functional Theory. Different mechanisms and reaction sites have been considered. The overall rate constant was found to be diffusion-limited (1.35 × 10(10) M(-1) s(-1), in aqueous solution), and in excellent agreement with the experimental results. Therefore, the present work supports previous evidence that EDA is an excellent (•)OH scavenger. The anionic form of EDA is predicted to react 8.6 times faster than its neutral form. The preponderant mechanism was found to be different depending on the form of EDA reacting with the radical. For the anionic form, the single electron transfer mechanism was found to be the one contributing the most to the overall reactivity toward (•)OH (∼ 44%), closely followed by radical adduct formation (∼40%). For the neutral form, the latter was found to be the main mechanism, with contributions larger than 98%, regardless of the polarity of the environment. For the global reactivity of EDA toward OH radicals, at physiological pH, the main mechanism of reaction is proposed to be the sequential electron proton transfer. A detailed analysis of the UV-vis spectra is also provided. The excellent agreement with the available experimental data supports the reliability of the new information provided in the present work.