Attaching a Dipeptide to Fullerene as an Antioxidant Hybrid against DNA Oxidation.

Emerging evidence has revealed that oxidative damages of DNA correlate with the pathogenesis of some diseases, and numerous investigations have also suggested that supplementation of antioxidants is beneficial for keeping health by rectifying in vivo redox status. Here, we construct antioxidative dipeptides with the Ugi four-component reaction (comprising p-aminobenzyl alcohol, benzaldehyde, or vanillin, a series of antioxidative carboxylic acids and isocyanides as reagents) and then attempt to attach the dipeptides to [60]fullerene by the Bingel reaction. However, this endeavor does not lead to the amelioration of the radical-scavenging property because abilities of fullerenyl dipeptides to trap 2,2'-diphenyl-1-picrylhydrazyl and galvinoxyl radicals are still dependent upon the phenolic hydroxyl group in the dipeptide scaffold rather than upon the fullerenyl group. Alternatively, when the obtained fullerenyl dipeptides are evaluated in a peroxyl radical-induced oxidation of DNA, it is found that introducing a fullerene moiety into dipeptide enables antioxidative effect to be enhanced 20-30% because the fullerene moiety facilitates the corresponding dipeptide to intercalate with DNA strands, and thus, to increase the antioxidative efficacy. Our results suggest that connecting an antioxidative skeleton with the hydrophobic fullerene moiety might lead to a series of novel antioxidant hybrids applied for the inhibition of DNA oxidation.

Multicomponent Reactions for Integrating Multiple Functional Groups into an Antioxidant.

A large number of convincing evidences has revealed the correlation of the pathogeny of diseases with the oxidative damages of DNA, protein, biomembrane, and other biological species, while supplementation of antioxidants is demonstrated to be a promising way to avoid, at least, rectify the unbalance redox status in vivo. Although many endeavors have focused on synthesis of antioxidants, a main hurdle still hinders the wide usages of synthetic antioxidants because of low bioavailability and potential cytotoxicity. The search for antioxidants with multiple functional groups being recognized by different receptors becomes a much sought by researchers, and multicomponent reactions (MCRs) provide with powerful tools for the construction of multifunctional antioxidants. Presented herein is a personal account on the application of MCRs for the synthesis of multifunctional antioxidants, while radical-induced oxidation of DNA acts as the experimental system for evaluating antioxidative effect. Concretely, the Biginelli three-component reaction (3CR) affords such a dihydropyrimidine scaffold that the tautomerization between C=S and C-SH leads to antioxidative effect. The Povarov 3CR is able to integrate multiple antioxidative groups, i. e., ferrocenyl and -N(CH3 )2 , into a quinoline scaffold, while the Groebke 3CR provides with imidazo[1,2-a]pyridine skeleton for inhibiting DNA oxidation. Additionally, the Knoevenagel-related MCRs also become efficient strategies for achieving radical-scavengers. On the other hand, the Ugi 4CR and Passerini 3CR result in the dipeptide and α-acyloxycarboxamide, respectively, with the benefit for the integration of antioxidative features by aliphatic chains. Therefore, MCRs have emerged as efficient tools for integrating multiple antioxidative features into one molecule in order to meet with complicated requirements from various biological surroundings.

Enhancing Antioxidant Effect against Peroxyl Radical-Induced Oxidation of DNA: Linking with Ferrocene Moiety!

As a major member in the family of reactive oxygen species, peroxyl radical is able to abstract hydrogen atom from 4-position of ribose, leading to the collapse of DNA strand. Thus, inhibiting oxidative stress with exogenous antioxidants acts as a promising strategy to protect the integrity of DNA structure and is thereby suggested to be a pathway against developments of related diseases. Ferrocene as an organometallic scaffold is widely applied in the design of organometallic drugs, and redox of Fe(II)/Fe(III) in ferrocene offers advantage for providing electron to radicals. Presented herein are our ongoing studies on ferrocene-appended antioxidants, including McMurry reaction applied to construct ferrocifen; Aldol condensation used to prepare ferrocenyl curcumin; Povarov reaction employed to prepare ferrocenyl quinoline; Biginelli reaction used to construct ferrocenyl dihydropyrimidine; Groebke reaction used to synthesize ferrocenyl imidazo[1,2-a]pyridine; and Passerini three-component reaction as well as Ugi four-component reaction applied to synthesize α-acyloxycarboxamide and bisamide, respectively. It is found that ferrocene moiety is able to enhance antioxidative effect of the aforementioned scaffolds even without the aid of phenolic hydroxyl group. The role of ferrocene in enhancing antioxidative effect can be attributable to trapping radicals, decreasing oxidative potential, and increasing the affinity toward DNA strand. Therefore, ferrocene is worthy to be taken into consideration in the design of drugs in relation to DNA oxidation.

Construction of 3D Antioxidants with Nucleosides as the Core: Inhibition of DNA Oxidation.

We herein attach ferulic and caffeic acids to -OH and -NH2 in cytidine, uridine, adenosine, or guanosine for achieving antioxidative hybrids with three-dimensional (3D) configuration. In the case of molecular docking computation, the nucleoside antioxidants with 3D configuration facilitate to bind with the groove of DNA and to cover the surface of a DNA helix. Experimentally, the antioxidative effects of nucleoside hybrids are measured in the inhibition of DNA oxidation caused by 2,2'-azobis(2-amidinopropane dihydrochloride) (AAPH), and the stoichiometric factor (n, the number of free radical propagations terminated by one molecule of antioxidant) can be selected as a quantitative index for expressing antioxidative effects. It is found that the effect of cytidine tetraferulate against AAPH-induced DNA oxidation is seven times better than that of ferulic acid, even though four ferulic acid moieties are involved and cytidine itself does not exhibit activity. Moreover, the antioxidative effect of cytidine tetracaffeate is almost 20 times higher than that of caffeic acid. The n values of nucleoside antioxidants against AAPH-induced DNA oxidation are found to correlate proportionally with the rate constants for quenching 2,2'-diphenyl-1-picrylhydrazyl and galvinoxyl radicals. Therefore, nucleoside linking with antioxidative carboxylic acid might be a promising way for constructing antioxidants against peroxyl radical-induced oxidation of DNA.

Hybrid of Resveratrol and Glucosamine: An Approach To Enhance Antioxidant Effect against DNA Oxidation.

Resveratrol exhibits various pharmacological activities, which are dependent upon phenolic hydroxyl groups. In this work, glucosamine, lipoic acid, or adamantanamine moiety was applied for attaching to ortho-position of hydroxyl group in resorcinol moiety of resveratrol (known as position-2). Antioxidant effects of the obtained hybrids were characterized using DNA oxidative systems mediated by •OH, Cu2+/glutathione (GSH), and 2,2'-azobis(2-amidinopropanehydrochloride) (AAPH), respectively. The glucosyl-appended imine and amine at position-2 of resveratrol were found to show higher inhibitory effects than other resveratrol derivatives against AAPH-induced DNA oxidation. The antioxidative effect was quantitatively expressed by stoichiometric factor ( n, the number of radical-propagation terminated by one molecule of antioxidant). The stoichiometric factors of glucosyl-appended imine and amine of resveratrol increased to 4.74 (for imine) and 4.97 (for amine), respectively, higher than that of resveratrol (3.70) and glucoside of resveratrol (3.49). It was thereby concluded that the combination of resveratrol with glucosamine at position-2 represented a novel pathway for modifying resveratrol structure in the protection of DNA against peroxyl radical-mediated oxidation.

Tetramer as efficient structural mode for organizing antioxidative carboxylic acids: The case in inhibiting DNA oxidation.

To overcome the problem on the relationship of antioxidative effect with the branch number in a tetramer, we herein designed a series of antioxidants with pentaerythritol, glycerol, and ethylene glycol as the cores, and gallic, ferulic, caffeic, and p-hydroxybenzoic acids as the antioxidative moieties. In the case of DNA oxidation mediated by 2,2'-azobis(2-amidinopropane hydrochloride, AAPH), it was found that the stoichiometric factor (n) of a carboxylic acid increased rapidly when the acid was esterified with ethylene glycol, glycerol, and pentaerythritol to form a dimer, trimer, and tetramer, respectively. Interestingly, the coefficient in the equation of n∼{branch} ({branch} referred to the number of branches) was higher than one, indicating that the antioxidative effect was enhanced more promptly than the increase of the number of branches. Meanwhile, tetramer exhibited high intercalation effect with DNA strand. Therefore, additionally antioxidative effect was ascribed to the tethering effect resulting from tetrameric structure and strong intercalation with DNA strand generated by tetramer.

Ferrocenyl-appended aurone and flavone: which possesses higher inhibitory effects on DNA oxidation and radicals?

The aim of the present work was to compare the antioxidative effect of the ferrocenyl-appended aurone with that of ferrocenyl-appended flavone; therefore, nine aurones together with the flavone-type analogues were synthesized by using chalcone as the reactant. The radical-scavenging property was evaluated by reacting with the 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate) cationic radical (ABTS(+·)), 2,2'-diphenyl-1-picrylhydrazyl radical (DPPH), and galvinoxyl radical, respectively. The cytotoxicity was estimated by inhibiting 2,2'-azobis(2-amidinopropane hydrochloride) (AAPH)-induced oxidation of DNA. It was found that the introduction of the ferrocenyl group remarkably increased the radical-scavenging activities of aurone and flavone. Especially, the ferrocenyl group in flavones can quench radicals even in the absence of the phenolic hydroxyl group, while ferrocenyl-appended aurones can efficiently protect DNA against AAPH-induced oxidation. Therefore, the antioxidative effect was generated by the ferrocenyl group and enhanced by the electron-donating group attaching to the para-position of the ferrocenyl group. Introducing the ferrocenyl group into natural compounds may be a useful strategy for increasing the antioxidative effectiveness.

Is it still worth renewing nucleoside anticancer drugs nowadays?

Nucleoside has situated the convergence point in the discovery of novel drugs for decades, and a large number of nucleoside derivatives have been constructed for screening novel pharmacological properties at various experimental platforms. Notably, nearly 20 nucleosides are approved to be used in the clinic treatment of various cancers. Nevertheless, the blossom of synthetic nucleoside analogs in comparison with the scarcity of nucleoside anticancer drugs leads to a question: Is it still worth insisting on the screening of novel anticancer drugs from nucleoside derivatives? Hence, this review attempts to emphasize the importance of nucleoside analogs in the discovery of novel anticancer drugs. Firstly, we introduce the metabolic procedures of nucleoside anticancer drug (such as 5-fluorouracil) and summarize the designing of novel nucleoside anticancer candidates based on clinically used nucleoside anticancer drugs (such as gemcitabine). Furthermore, we collect anticancer properties of some recently synthesized nucleoside analogs, aiming at emphasizing the availability of nucleoside analogs in the discovery of anticancer drugs. Finally, a variety of synthetic strategies including the linkage of sugar moiety with nucleobase scaffold, modifications on the sugar moiety, and variations on the nucleobase structure are collected to exhibit the abundant protocols in the achievement of nucleoside analogs. Taken the above discussions collectively, nucleoside still advantages for the finding of novel anticancer drugs because of the clearly metabolic procedures, successfully clinic applications, and abundantly synthetic routines.

Ugi multicomponent reaction product: the inhibitive effect on DNA oxidation depends upon the isocyanide moiety.

The hydroxyl-substituted benzoic acid (as phenyl group A in the product), aniline (as phenyl group B in the product), benzaldehyde (as phenyl group C in the product), and four isocyanides are employed to synthesize bis-amide via an Ugi four-component reaction. The effects of the obtained 20 bis-amides on quenching radicals and inhibiting DNA oxidation are estimated. It is found that the antioxidant effectiveness of bis-amide generated by hydroxyl groups is markedly influenced by the structural feature derived from isocyanide. The phenolic hydroxyl group attaching to phenyl group A plays a major role in scavenging radicals, and the radical-scavenging property is reinforced by the structural moiety introduced from ferrocenylmethyl isocyanide. The same conclusion is also obtained when bis-amides are used to inhibit DNA oxidation. It is still found that the ferrocenylmethyl moiety enhances the antioxidant effect of hydroxyl group at phenyl group A in protecting DNA against the oxidation. Moreover, when the bis-amide is prepared by the same isocyanide, e.g. ethyl isocyanoacetate, it is found that the hydroxyl group at phenyl group C plays the major role in inhibiting DNA oxidation, followed by the hydroxyl groups attaching to phenyl groups B and A.

Potentiality of Nucleoside as Antioxidant by Analysis on Oxidative Susceptibility, Drug Discovery, and Synthesis.

Nucleosides are sensitive sites towards oxidations caused by endogenous and exogenous oxidative resources, and a large number of the produced DNA lesions behave as pathogenesis event1ually. We herein analyze oxidative modes of nucleosides and structure-activity relationships of some clinical nucleoside drugs. Together with our previous findings on the inhibitory effects of nucleoside derivatives against DNA oxidation, all these results imply a possibility for nucleoside to be a new member in the family of antioxidants. Then, some novel synthetic routines of nucleoside analogs are collected to reveal the applicability in the construction of nucleoside antioxidants. Therefore, it is reasonable to envision that the nucleoside antioxidant will be a novel topic in the research of both nucleosides and antioxidants.

Solvent-free and catalyst-free Biginelli reaction to synthesize ferrocenoyl dihydropyrimidine and kinetic method to express radical-scavenging ability.

Benzoyl and ferrocenoyl 3,4-dihydropyrimidin-2(1H)-ones (-thiones) (DHPMs) were synthesized in modest yields via catalyst-free and solvent-free Biginelli condensation of 1-phenylbutane-1,3-dione or 1-ferrocenylbutane-1,3-dione, hydroxyl benzaldehyde, and urea or thiourea. This synthetic protocol revealed that catalysts may not be necessary for the self-assembling Biginelli reaction. The radical-scavenging abilities of the obtained 11 DHPMs were carried out by reacting with 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate) cationic radical (ABTS(+•)), galvinoxyl radical, and 2,2'-diphenyl-1-picrylhydrazyl radical (DPPH), respectively. The variation of the concentration of these radicals with the reaction time (t) followed exponential function, [radical] = Ae(-t/a) + Be(-t/b) + C. Then, the differential style of this equation led to the relationship between the reaction rate (r) and the reaction time (t), -d[radical]/dt = (A/a)e(-t/a) + (B/b)e(-t/b), which can be used to calculate the reaction rate at any time point. On the basis of the concept of the reaction rate, r = k[radical][antioxidant], the rate constant (k) can be calculated with the time point being t = 0. By the comparison of k of DHPMs, it can be concluded that phenolic ortho-dihydroxyl groups markedly enhanced the abilities of DHPMs to quench ABTS(+•), but the introduction of ferrocenoyl group made DHPMs efficient ABTS(+•) scavengers even in the absence of phenolic hydroxyl group. This phenomenon was also found in DHPM-scavenging galvinoxyl radical. In contrast, the ferrocenoyl group cannot enhance the abilities of DHPMs to scavenge DPPH, and phenolic ortho-dihydroxyl groups still played the key role in this case.

Why natural antioxidants are readily recognized by biological systems? 3D architecture plays a role!

A great deal of investigations has convincingly outlined the correlation of pathogenesis of various fatal diseases with the damages caused by reactive oxygen species (ROS) in vivo. Not surprisingly, natural antioxidants play pivotal roles in the decreasing of these diseases by their hydrophilicity, permeability, multi-factored interactions with biological surroundings, while the antioxidative effects are dependent upon the bond energies, donors or acceptors of hydrogen bonds as well as other physical properties of the functional groups. However, in comparison with natural antioxidants the synthetic antioxidants sometimes exhibit potentially deleterious effects, viz., pro-oxidative properties, and it is thereby worth exploring the structures of natural antioxidants with the aim of achieving valuable information for the antioxidative structures. Here, more than 70 natural antioxidants are collected from recent publications, and their configurations are optimized at MM2 level for summarizing the common characteristics from their structures. It is found that all the natural phenols, flavonoids, anthraquinones, alkaloids, terpenoids, and steroids exert three-dimensional (3D) architectures rather than a merely planar conjugation system. Hence, this 3D conformation might be beneficial for the natural antioxidants being recognized by biological surroundings. This deduction has been demonstrated by some synthetic antioxidants, in which their structures have been conformed to be 3D architecture. The 3D architecture will become a direction for the designing of antioxidative structures, and the testing of antioxidative effect is encouraged to employ signaling pathways, protein targets, and cell lines rather than individual radical-scavenging evaluation.

What about the progress in the synthesis of flavonoid from 2020?

Flavonoids are a well-known family of natural polyphenols because of their prevalent properties in the physiological and medicinal field. In addition to a plethora of natural flavonoids, the construction of flavonoid skeletons still situates at the convergence point in the medicinal chemistry. Not surprisingly, amplification in the organic synthetic protocols showcases an expected avenue for accessing to abundant flavonoid scaffolds with special pharmacological activities. Hence, it is necessary to address the recent progresses in the synthesis of flavonoids by using organic strategies, and some typical protocols on the construction of flavonoids are thereby collected from recent publications (from 2020). The synthetic strategies presented herein are mainly cataloged as the cyclization of 4-chromanone, the glycosylation on the flavonoid scaffold, and the application of flavonoids in the pharmacological researches, aiming at providing with a current picture for depicting the recent progress on the synthesis of flavonoids. Therefore, it is expected to be a reference for the further exploration on the designing of synthetic routines for flavonoids.

Synthesis of hydroxyferrocifen and its abilities to protect DNA and to scavenge radicals.

The aim of this work was to clarify the effect of the position of the hydroxyl group on the antioxidant capacity of hydroxyferrocifen by means of a chemical kinetic method. Propionylferrocene and benzoylferrocene condensed with 4-hydroxydiphenylketone, 3,4-dihydroxydiphenylketone, and 4,4'-dihydroxydiphenylketone to form FP3, FP4, FB3, and FB4 with a single hydroxyl group and FP34, FP44, FB34, and FB44 with two hydroxyl groups. These hydroxyferrocifens were applied in Cu(2+)/glutathione (GSH)-induced, hydroxyl radical (·OH)-induced, and 2,2'-azobis(2-amidinopropane hydrochloride) (AAPH)-induced oxidation of DNA, and in trapping 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate) cationic radical (ABTS(+·)). It was found that these hydroxyferrocifens acted as prooxidants in Cu(2+)/GSH-induced oxidation of DNA and exhibited very weak effects on ·OH-induced oxidation of DNA. FP3, FP4, FB3, and FB4 can only retard the rate of AAPH-induced oxidation of DNA, whereas FP44, FB44, FB34, and FP34 can trap 11.9, 7.1, 6.2, and 4.9 radicals, respectively, in AAPH-induced oxidation of DNA. The ability to trap ABTS(+·) followed the order FB4 > FP44 > FB34 > FB44 > FP34. It was concluded that two hydroxyl groups at the para position of two benzene rings rather than at the ortho position in the same benzene ring were beneficial for hydroxyferrocifen to increase the antioxidant capacity.

Radical-scavenging properties of ferrocenyl chalcones.

The radical-scavenging capacities of ferrocenyl group and phenolic hydroxyl group in ferrocenyl chalcone were identified in this work. 1,1'-Diacetylferrocene was applied to condense with benzaldehyde, vanillin, and protocatechualdehyde to produce ferrocenyl chalcones, which were employed to interact with 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate) cationic radical (ABTS(+)), 2,2'-diphenyl-1-picrylhydrazyl radical (DPPH), and galvinoxyl radical, respectively. It was found that ferrocenyl chalcones as well as diacetylferrocene can trap these radicals effectively, and thus, concluded that both iron atom in ferrocene and phenolic hydroxyl group played the radical-scavenging role, and the radical-scavenging capacity of iron atom in ferrocene was even higher than that of phenolic hydroxyl group.

Comparison of antioxidant effectiveness of lipoic acid and dihydrolipoic acid.

The abilities of dihydrolipoic acid (DHLA) to scavenge peroxynitrite (ONOO(-) ), galvinoxyl radical, 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate) cation radical (ABTS(+•) ), and 2,2'-diphenyl-1-picrylhydrazyl radical (DPPH) were higher than those of lipoic acid (LA). The effectiveness of DHLA to protect methyl linoleate against 2,2'-azobis(2-amidinopropane hydrochloride) (AAPH)-induced oxidation was about 2.2-fold higher than that of LA, and DHLA can retard the autoxidation of linoleic acid (LH) in the ß-carotene-bleaching test. DHLA can also trap ∼0.6 radicals in AAPH-induced oxidation of LH. Moreover, DHLA can scavenge ∼2.0 radicals in AAPH-induced oxidation of DNA and AAPH-induced hemolysis of erythrocytes, whereas LA can scavenge ∼1.5 radicals at the same experimental conditions. DHLA can protect erythrocytes against hemin-induced hemolysis, but accelerate the degradation of DNA in the presence of Cu(2+) . Therefore, the antioxidant capacity of -SH in DHLA is higher than S-S in LA.

Bridging free radical chemistry with drug discovery: A promising way for finding novel drugs efficiently.

Many diseases have been regarded to correlate with the in vivo oxidative damages, which are caused by overproduced free radicals from metabolic process or reactive oxygen species (ROS). This background motivates chemists to explore free radical reactions and to design a number of antioxidants, but whether free radical chemistry can be applied to accelerate the efficacy of the drug discovery is still underrepresented. Herein, in light of recent findings as well as kinetics on free radical reaction, the discipline of free radical chemistry is introduced to be a novel tool for finding potential drugs from antioxidant libraries accumulated during the study on free radical chemistry. These antioxidants provide with such abundant types of structural skeleton that might be employed to inhibit oxidations in different biological microenvironments. Although the in vitro characterization on the antioxidative property exerts a potential role of an antioxidant as a prodrug, the in vivo investigation on the property for quenching free radicals will make a final decision for the antioxidant whether it is worthy to be further explored pharmacologically. Therefore, it is reasonable to expect that bridging free radical chemistry with the pharmacological research will provide with a succinct way for finding novel drugs efficiently.

Indole and its alkyl-substituted derivatives protect erythrocyte and DNA against radical-induced oxidation.

The antioxidant properties of 1,2,3,4-tetra-hydrocarbazole, 6-methoxy-1,2,3,4-tetrahydrocar-bazole (MTC), 2,3-dimethylindole, 5-methoxy-2,3-dimethylindole, and indole were investigated in the case of hemolysis of human erythrocytes and oxidative damage of DNA induced by 2,2'-azobis(2-amidinopropane hydrochloride) (AAPH), respectively. The aim of this work was to explore the influence of methoxy, methyl, and cyclohexyl substituents on the antioxidant activities of indole derivatives. These indole derivatives were able to protect erythrocytes and DNA in a concentration-dependent manner. The alkyl-substituted indole can protect erythrocytes and DNA against AAPH-induced oxidation. Especially, the structural features of cyclohexyl and methoxy substituents made MTC the best antioxidant among the indole derivatives used herein. Finally, the interaction between these indole derivatives and 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate) radical cation and 2,2'-diphenyl-1-picrylhydrazyl, respectively, provided direct evidence for these indole derivatives to scavenge radicals and emphasized the importance of electron-donating groups for the free radical-scavenging activity of indole derivatives.

Lidocaine: an inhibitor in the free-radical-induced hemolysis of erythrocytes.

Lidocaine was reported to protect erythrocytes from hemolysis induced by 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH). Since AAPH-induced hemolysis was a convenient in vitro experimental system to mimic erythrocytes undergoing peroxyl radicals attack, the aim of this work was to investigate the antioxidant effect of lidocaine on AAPH-induced hemolysis by chemical kinetics. As a result, one molecule of lidocaine can only trap 0.37 radical, much lower than melatonin. Meanwhile, lidocaine cannot protect erythrocytes from hemolysis induced by hemin, which the mechanism of hemolysis was due to the erythrocyte membrane destroyed by hemin. Accordingly, lidocaine protected erythrocytes by scavenging radicals preferentially rather than by stabilizing membrane. Moreover, the interactions of lidocaine with two radical species, including 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate) radical cation (ABTS(+*)) and 2,2'-diphenyl-1-picrylhydrazyl (DPPH), indicated that lidocaine can reduce ABTS(+*) with 260 microM as the 50% inhibition concentration (IC(50)) and cannot react with DPPH. Thus, lidocaine served as a reductant rather than a hydrogen donor to interact with radicals. Finally, the quantum calculation proved that, compared with the melatonin radical, the stabilization of N-centered radical of lidocaine was higher than the amide-type N-centered radical but lower than the indole-type N-centered radical in melatonin. These results provided basic information for lidocaine to be an antiradical drug.