UV-induced free radicals in the skin detected by ESR spectroscopy and imaging using nitroxides

Reactive free radicals and reactive oxygen species (ROS) induced by ultraviolet irradiation in human skin are strongly involved in the occurrence of skin damages like aging and cancer. In the present work an ex vivo method for the detection of free radicals/ROS in human skin biopsies during UV irradiation is presented. This method is based on the Electron Spin Resonance (ESR) spectroscopy and imaging and uses the radical trapping properties of nitroxides. The nitroxides 2,2,6,6-Tetramethylpiperidine-1-oxyl (TEMPO), 3-Carbamoyl-2,2,5,5-tetramethylpyrrolidine-1-oxyl (PCM), and 3-Carboxy-2,2,5,5-tetramethylpyrrolidine-1-oxyl (PCA), were investigated for their applicability of trapping reactive free radicals and reactive oxygen species in skin during UV irradiation. As a result of the trapping process the nitroxides were reduced to the EPR silent hydroxylamins. The reduction rate of TEMPO was due to both the UV radiation and the enzymatic activity of the skin. The nitroxides PCM and PCA are sufficiently stable in the skin and are solely reduced by UV-generated free radicals/ROS. The nitroxide PCA was used for imaging the spatial distribution of UV-generated free radicals/ROS. As a result of the homogeneous distribution of PCA in the skin, it was possible to estimate the penetration of UVA and UVB irradiation: The UV irradiation decreased the PCA intensity corresponding to its irradiance and penetration into the skin. This reduction was shown to be caused mainly by UVA radiation (320-400 nm).     

In vivo detection of free radicals induced by diethylnitrosamine in rat liver tissue

Diethylnitrosamine (DEN) is a well-known carcinogenic substance that requires microsomal activation before it can react with DNA to cause mutations and cancer. The aim of this study was to use in vivo spin trapping and spin probe techniques to investigate whether free radicals are generated in rat liver tissue during DEN activation. We used alpha-phenyl-n-tert-butylnitrone (PBN) as the spin trapping agent, which was delivered through an intraperitoneal injection before DEN administration. One hour after DEN administration, multicomponent PBN adducts in the bile were detected, and the intensities were diminished by the cytochrome P450 inhibitor SKF-525A. A computer simulation of the ESR signals revealed the presence of a lipid-derived radical. Using the in vivo spin probe/ESR technique, the signal decay rate of methoxycarbonyl-PROXYL was significantly increased in the DEN-treated group compared with the rate in the vehicle group. The enhanced signal decay rate was restored with PBN and/or SKF-525A pretreatment. These results suggested that lipid-derived free radicals were generated in the liver within 1 h after DEN administration.     

Evidence of in vivo Free Radical Generation by Spin Trapping with α-Phenyl N-Tert-Butyl Nitrone During Ischemia/Reperfusion in Rabbit Kidneys

By using α-phenyl N-tert-butyl nitrone (PBN) as spin trap molecule and the electron paramagnetic resonance (EPR) technique, we obtained the first direct evidence of in vivo intervention of free radicals during an ischemia (50 minutes) reperfusion phenomenon in kidney of an intact rabbit.

An EPR signal (triplet of doublets) characterized by coupling constants a_N = 14.75–15 G and a^H_s = 2.5–3 G was detected in blood samples. The signal was consistent with a nitroxyl-radical adduct resulting from the spin trapping by PBN of either oxygen-or carbon-centered radicals. Control experiments indicated that the EPR signal was not due to a toxic effect of the spin trap molecule.     

Estimation of free radical formation by beta-ray irradiation in rat liver

In vivo free radical reactions in rat liver as a result of exposure to low-dose beta-radiation was evaluated with electron paramagnetic resonance (EPR) spectroscopy by monitoring the reduction of the nitroxyl spin probe after intravenous administration. The EPR signal intensity of a nitroxyl probe as a function of time in bile flow was monitored by cannulating the bile duct through the cavity of an X-band EPR spectrometer. The results show that the rate of nitroxyl signal loss was higher in rats whose livers were exposed to beta-rays compared to unexposed rats. However, the rate of signal loss was lower in animals whose organs were exposed to air by opening the abdominal cavity. In vitro experiments also showed that the nitroxyl EPR signal loss was greater in an atmosphere of nitrogen than in air. Results suggest that under low levels of tissue oxygen, exposure to beta-rays results in nitroxyl signal loss, which may be mediated by free radical dependent pathways. When tissue oxygen were higher, hydrogen peroxide mediated oxidation of hydroxylamine may predominate resulting in a signal loss of smaller magnitudes. This study shows possible evidence of reactive oxygen species formation by low-dose beta-ray irradiation in a living animal.     

In vivo measurement and mapping of skin redox stress induced by ultraviolet light exposure

Exposure of skin to UV light presents a potent oxidative stress and this could alter the skin redox state. In this context, we evaluated the ability of electron paramagnetic resonance (EPR) imaging to provide noninvasive in vivo mapping of the redox status of the skin of living rats. The redox status was measured using a topically applied nitroxyl spin probe, (15)N-PDT. The nitroxyl intensity profile obtained across the skin layers showed that the concentration of the probe was higher in the epidermis and lower in the dermis and hypodermis. Skin permeability and reduction metabolism were evaluated in the skin exposed to UVB (312 nm) radiation. Exposure of skin to UVB decreased the overall reduction rate constant of the nitroxyl probe to 25 +/- 6% of the value obtained in the untreated skin. EPR imaging data showed that after the UVB treatment, the reduction rate constant decreased to 41 +/- 1% in epidermis, 28 +/- 1% in dermis, and 21 +/- 8% in hypodermis layers. The data suggested that UVB decreased the overall reducing capability of the skin with a larger decrease in the dermis and hypodermis. In summary, in vivo EPR imaging measurements showed significant alterations in the redox state of the skin exposed to UV light.     

Chemiluminescent detection and imaging of reactive oxygen species in live mouse skin exposed to UVA

The recent increase of ultraviolet (UV) rays on Earth due to the increasing size of the ozone hole is suggested to be harmful to life and to accelerate premature photoaging of the skin. The detrimental effects of UV radiation on the skin are associated with the generation of reactive oxygen species (ROS) such as superoxide anion radical (*O(-)(2)), hydrogen peroxide (H(2)O(2)), hydroxyl radical (*OH), and singlet oxygen ((1)O(2)). However, direct proof of such ROS produced in the skin under UV irradiation has been elusive. In this study, we report first in vivo detection and imaging of the generated ROS in the skin of live mice following UVA irradiation, in which both a sensitive and specific chemiluminescence probe (CLA) and an ultralow-light-imaging apparatus with a CCD camera were used. In addition, we found that *O(-)(2) is formed spontaneously and (1)O(2) is generated in the UVA-irradiated skin. This method should be useful not only for noninvasive investigation of the spatial distribution and quantitative determination of ROS in the skin of live animals, but also for in vivo evaluation of the protective ability of free radical scavengers and antioxidants.     

Synthesis and application of a novel sunscreen-antioxidant

Background information on the inefficacy of sunscreens to provide free radical protection in skin, despite their usefulness in preventing sunburn/erythema, prompted us to synthesize a compound which would display in the same molecule both UV-absorbing and antioxidant capacities. For this purpose, the UVB absorber, 2-ethylhexyl-4-methoxycinnamate (OMC) was combined with the piperidine nitroxide TEMPOL, which has antioxidant properties. The spectral properties of the new nitroxide-based sunscreen (MC-NO) as well as its efficacy to prevent photo-oxidative damage to lipids induced by UVA, natural sunlight and 4-tert-butyl-4-methoxydibenzoylmethane (BMDBM), a photo-unstable sunscreen which generates free radicals upon UV radiation, was studied. The results obtained demonstrate that MC-NO: (a) absorbs in the UVB region even after UVA irradiation; (b) acts as free radical scavenger as demonstrated by EPR experiments; (c) strongly reduces both UVA-, sunlight- and BMDBM-induced lipid peroxidation in liposomes, measured as reduced TBARS levels; and (d) has comparable antioxidant activity to that of commonly used vitamin E and BHT in skin care formulations. These results suggest that the use of the novel sunscreen-antioxidant or of other nitroxide-based sunscreens in formulations aimed at reducing photoinduced skin damage may be envisaged.     

Noninvasive study of radiation-induced oxidative damage using in vivo electron spin resonance

Nitroxyl radicals injected into a whole body indicate the disappearance of signal intensity of in vivo electron spin resonance (ESR). The signal decay rates of nitroxyl have reported to be influenced by various types of oxidative stress. We examined the effect of X-irradiation on the signal decay rate of nitroxyl in the upper abdomen of mice using in vivo ESR. The signal decay rates increased 1 h after 15 Gy irradiation, and the enhancement was suppressed by preadministration of cysteamine, a radioprotector. These results suggest that the signal decay of nitroxyl in whole mice is enhanced by radiation-induced oxidative damage. The in vivo ESR system probing the signal decay of nitroxyl could provide a noninvasive technique for the study of oxidative stress caused by radiation in a living body.     

Wavelength,dose, skin type and skin model related radical formation in skin

The exposure to sun radiation is indispensable to our health; however, a long-term and high exposure could lead to cell damage, erythema, premature skin aging, and promotion of skin tumors. An underlying pathomechanism is the formation of free radicals which may induce oxidative stress at elevated concentrations. Different skin models, such as porcine-, murine-, human- ex vivo skin, reconstructed human skin (RHS) and human skin in vivo, were investigated during and after irradiation using X- and L-band EPR spectroscopy within different spectral regions (UVC to NIR). The amount of radical formation was quantified with the spin probe PCA and the radical types were measured ex vivo with the spin trap DMPO. The radiation dose influences the types of radicals formed in the skin. While reactive oxygen species (ROS) are always pronounced at low doses, there is an increase in lipid oxygen species (LOS) at high doses. Furthermore, the radical types arise independent from the irradiation wavelength, whereas the general amount of radical formation differs with the irradiation wavelength. Heat pre-stressed porcine skin already starts with higher LOS values. Thus, the radical type ratio might be an indicator of stress and the reversal of ROS/LOS constitutes the point where positive stress turns into negative stress.Compared to light skin types, darker types produce less radicals in the ultraviolet, similar amounts in the visible and higher ones in the infrared spectral region, rendering skin type-specific sun protection a necessity.     

Photoprotective effect of vitamins A and E on polyamine and oxygenated free radical metabolism in hairless mouse epidermis

The purpose of this study was to confirm the photoprotective effect on skin of vitamins A and E, due to inhibition of polyamine synthesis and production of free radicals. These variables were measured in the lumbar epidermis of the female hairless mouse subjected to UVA + B irradiation. Polyamines were assayed in epidermal homogenate by HPLC, and production of oxygenated free radicals was determined by spectrofluorometric assay of malonyl dialdehyde. It was determined that butyl-hydroxy-toluene and vitamin E inhibited production of free radicals (56% and 60%, respectively) and caused a significant reduction in polyamine biosynthesis (P less than 0.01), whereas the inhibitory effect of malonyl dialdehyde induced by vitamin A (30%) had no associated effect on polyamine metabolism.     

Carotenoids as scavengers of free radicals in a Fenton reaction: antioxidants or pro-oxidants?

The spin trapping EPR technique was used to study the influence of carotenoids (beta-carotene, 8'-apo-beta-caroten-8'-al, canthaxanthin, and ethyl 8'-apo-beta-caroten-8'-oate) on the yield of free radicals in the Fenton reaction (Fe(2+) + H(2)O(2) --> Fe(3+) + .OH + -OH) in the organic solvents, DMSO, and methanol. DMPO and PBN were used as spin trapping agents. It was demonstrated that carotenoids could increase or decrease the total yield of free radicals depending on the oxidation potential of the carotenoids and the nature of the radicals. A reaction mechanism is suggested which includes the reduction of Fe(3+) to Fe(2+) by carotenoids. The effectiveness of this carotenoid-driven Fenton reaction increases with a decrease of the scavenging rates for free radicals and with decreasing oxidation potentials of carotenoids.     

Photo-Oxidation Products of Skin Surface Squalene Mediate Metabolic and Inflammatory Responses to Solar UV in Human Keratinocytes

The study aimed to identify endogenous lipid mediators of metabolic and inflammatory responses of human keratinocytes to solar UV irradiation. Physiologically relevant doses of solar simulated UVA+UVB were applied to human skin surface lipids (SSL) or to primary cultures of normal human epidermal keratinocytes (NHEK). The decay of photo-sensitive lipid-soluble components, alpha-tocopherol, squalene (Sq), and cholesterol in SSL was analysed and products of squalene photo-oxidation (SqPx) were quantitatively isolated from irradiated SSL. When administered directly to NHEK, low-dose solar UVA+UVB induced time-dependent inflammatory and metabolic responses. To mimic UVA+UVB action, NHEK were exposed to intact or photo-oxidised SSL, Sq or SqPx, 4-hydroxy-2-nonenal (4-HNE), and the product of tryptophan photo-oxidation 6-formylindolo[3,2-b]carbazole (FICZ). FICZ activated exclusively metabolic responses characteristic for UV, i.e. the aryl hydrocarbon receptor (AhR) machinery and downstream CYP1A1/CYP1B1 gene expression, while 4-HNE slightly stimulated inflammatory UV markers IL-6, COX-2, and iNOS genes. On contrast, SqPx induced the majority of metabolic and inflammatory responses characteristic for UVA+UVB, acting via AhR, EGFR, and G-protein-coupled arachidonic acid receptor (G2A). CONCLUSIONS/SIGNIFICANCE: Our findings indicate that Sq could be a primary sensor of solar UV irradiation in human SSL, and products of its photo-oxidation mediate/induce metabolic and inflammatory responses of keratinocytes to UVA+UVB, which could be relevant for skin inflammation in the sun-exposed oily skin.     

Oral administration is as effective as intraperitoneal administration of amifostine in decreasing nitroxide EPR signal decay in vivo

A rapid method to determine the systemic incorporation of amifostine has been sought in order to determine the effectiveness of different administration routes without the delay inherent in awaiting therapeutic results. Consistent changes in animal measurements of nitroxide signal decay were monitored using in vivo EPR at frequencies low enough to ensure uniform sensitivity to organs deep in 20-g C3H mice. Conditions included both co-administration of the amifostine with the carbamoyl-proxyl spin probe (CP) via i.p. injection (n=6) and oral administration (n=8) of the amifostine. These decreased the first order rate of decay of the CP EPR signal after a dose of 13.5 Gy radiation, by 23% and 18%, respectively. These changes were significantly different from the rate of decay of the CP EPR signal without amifostine, but were statistically indistinguishable from each other. These data demonstrate: (1) condition-dependent exponential decay of CP EPR signal allowing its use to determine systemic availability of a drug, and (2) that oral administration and i.p. injection of amifostine are both effective in affecting the CP EPR signal decay rate in a mouse model. This is a strong indicator of similar bioavailability in mice from both routes of administration.     

Inhibition of Fe2+- and Fe3+- induced hydroxyl radical production by the iron-chelating drug deferiprone

Deferiprone (L1) is an effective iron-chelating drug that is widely used for the treatment of iron-overload diseases. It is known that in aqueous solutions Fe²⁺ and Fe³⁺ ions can produce hydroxyl radicals via Fenton and photo-Fenton reactions. Although previous studies with Fe²⁺ have reported ferroxidase activity by L1 followed by the formation of Fe³⁺ chelate complexes and potential inhibition of Fenton reaction, no detailed data are available on the molecular antioxidant mechanisms involved. Similarly, in vitro studies have also shown that L1–Fe³⁺ complexes exhibit intense absorption bands up to 800 nm and might be potential sources of phototoxicity. In this study we have applied an EPR spin trapping technique to answer two questions: (1) does L1 inhibit the Fenton reaction catalyzed by Fe²⁺ and Fe³⁺ ions and (2) does UV–Vis irradiation of the L1–Fe³⁺ complex result in the formation of reactive oxygen species. PBN and TMIO spin traps were used for detection of oxygen free radicals, and TEMP was used to trap singlet oxygen if it was formed via energy transfer from L1 in the triplet excited state. It was demonstrated that irradiation of Fe³⁺ aqua complexes by UV and visible light in the presence of spin traps results in the appearance of an EPR signal of the OH spin adduct (TMIO–OH, a(N)=14.15 G, a(H)=16.25 G; PBN–OH, a(N)=16.0 G, a(H)=2.7 G). The presence of L1 completely inhibited the OH radical production. The mechanism of OH spin adduct formation was confirmed by the detection of methyl radicals in the presence of dimethyl sulfoxide. No formation of singlet oxygen was detected under irradiation of L1 or its iron complexes. Furthermore, the interaction of L1 with Fe²⁺ ions completely inhibited hydroxyl radical production in the presence of hydrogen peroxide. These findings confirm an antioxidant targeting potential of L1 in diseases related to oxidative damage.     

Photo-chemically induced DNA effects in the comet assay with epidermal cells of SKH-1 mice after a single oral administration of different fluoroquinolones and 8-methoxypsoralen in combination with exposure to UVA

Due to the need for in vivo photo-genotoxicity tests, the in vivo photo-comet assay was established in epidermal cells of the SKH-1 mouse. Groups of 10 male SKH-1 mice each were treated once orally with vehicle only, with three fluoroquinolones (25 mg/kg clinafloxacin, 20 mg/kg lomefloxacin, 200 mg/kg ciprofloxacin) or with 200mg/kg 8-methoxypsoralene (8-MOP). Thirty minutes after treatment half of the mice in each group were exposed to 23.8 J/cm2 UVA. Thereafter the mice were killed and their epidermal cells tested in the alkaline (pH >13) comet assay; at the same time after administration, compound-treated, non-irradiated mice were killed and analysed. A negative control group of ten male SKH-1 mice received the vehicle only; half of these animals were exposed to UVA, half were not. The comet tail lengths of epidermal cells of the mice were statistically significantly increased for all three fluoroquinolones (FQ) tested in combination with UV irradiation. Treatment with 8-methoxypsoralene+UV induced a significant reduction of comet tail length. Tail intensity and tail moment gave essentially the same results after combined exposure (compound+UV). Without irradiation, the tail lengths of controls and compound-treated mice were comparable under the conditions of this study. In contrast, tail intensity and tail moment were increased for all test compounds (including 8-MOP), without irradiation. Irradiated controls had a tail length comparable to non-irradiated controls, while tail intensity and tail moment were clearly increased in irradiated controls. In conclusion: under the present experimental conditions the in vivo photo-comet assay is able to detect photo-chemically induced DNA strand breaks as well as photo-chemically induced DNA cross-links.     

A novel ascorbic acid-resistant nitroxide in fat emulsion is an efficient brain imaging probe for in vivo EPR imaging of mouse

The loss of paramagnetism of nitroxide radicals due to reductant reactions in biological systems, places a fundamental time constraint on their application as an imaging probe in in vivo EPR imaging studies. However, in vitro studies of the newly synthesized tetraethyl-substituted piperidine nitroxide radical demonstrated high resistivity to paramagnetic reduction when exposed to ascorbic acid, a common reduction agent in biological systems. In this work we investigated the use of these nitroxides as an imaging probe in EPR imaging of small rodents. 2,2,6,6-Tetraethyl-piperidine nitroxide (TEEPONE) is not highly soluble in aqueous media, thus a lipid-based emulsion system of lecithin was used to solubilize TEEPONE. The obtained solution was homogenous and with low viscosity, allowing smooth intravenous injection into mice tail vein. Acquired three dimensional (3D) EPR images of mouse head clearly showed TEEPONE distributed in all tissues including brain tissues, with an average measurable signal half-life of more than 80 min, thus demonstrating high resistivity to reduction due to ascorbic acid in in vivo animal studies, and the potential for use of this compound in in vivo studies of animal model systems.     

An EPR Investigation of Human Methaemoglobin Oxidation by Hydrogen Peroxide: Methods to Quantify all Paramagnetic Species Observed in the Reaction

The method of Electron Paramagnetic Resonance (EPR) spectroscopy was used to study the reaction of human methaemoglabin (metHb) with hydrogen peroxide. The samples for EPR measurements were rapidly frozen in liquid nitrogen at different times after H₂O₂ was added at 3- and 10-fold molar excess to 100 μM metHb in 50 mM phosphate buffer, pH 7.4, 37°C. Precautions were taken to remove all catalase from the haemoglobin preparation and no molecular oxygen evolution was detected during the reaction. On addition of H₂O₂ the EPR signals (- 196°C) of both high spin and low spin metHb rapidly decreased and free radicals were formed. The low temperature (- 196°C) EPR spectrum of the free radicals formed in the reaction has been deconvoluted into two individual EPR signals, one being an anisotropic signal (g° = 2.035 and g° = 2.0053), and the other an isotropic singlet (g = 2.0042, AH = 20 G). The former signal was assigned to peroxyl radicals. As the kinetic Pehaviour of both peroxyl (ROO^*) and nonperoxyl (P^*) free radicals were similar, we concluded that ROO^* radicals are not formed from P^* radicals by addition of O₂. The time courses for both radicals showed a steady state during the time required for H₂O₂ to decompose. Once all peroxide was consumed, the radical decayed with a first order rate constant of 1.42 ± 10^-3 s^-1 (1:3 molar ratio). The level of the steady state was higher and its duration shorter at lower initial concentration of H₂O₂. The formation of the rhombic Fe(III) non-haemcentres with g = 4.35 was found. Their yield was proportional to the H₂O₂ concentration used and the centers were ascribed to haem degradation products. The reaction was also monitored by EPR spectroscopy at room temperature. The kinetics of the free radicals measured in the reaction mixture at room temperature was similar to that observed when the fast freezing method and EPR measurement at —196°C were used.     

EPR spectroscopic detection of free radical outflow from an isolated muscle bed in exercising humans.

There is no direct evidence to support the contention that contracting skeletal muscle and/or associated vasculature generates free radicals in exercising humans. The unique combination of isolated quadriceps exercise and the measurement of femoral arterial and venous free radical concentrations with the use of electron paramagnetic resonance (EPR) spectroscopy enabled this assumption to be tested in seven healthy men. Application of ex vivo spin trapping using alpha-phenyl-tert-butylnitrone (PBN) resulted in the detection of oxygen- or carbon-centered free radicals (a(N) = 1.38 +/- 0.01 mT and a(beta)(H) = 0.17 +/-0.01 mT, where a(N) and a(beta)(H) are the nitrogen and beta-hydrogen coupling constants, respectively) with consistently higher EPR signal intensities of the PBN spin adduct observed in the venous compared with the arterial circulation (P < 0.05). Incremental exercise further increased the venoarterial intensity difference [85 +/- 58 arbitrary units (AU) at 24 +/- 6% maximal work rate (WR(max)) vs. 387 +/- 214 AU at 69 +/- 7% WR(max); P < 0.05]. When combined with measured changes in femoral venous blood flow (Q), this resulted in a net adduct outflow of 130 +/- 118 and 1,146 +/- 582 AU/min (P < 0.05), which was positively associated with leg oxygen uptake (r(2) = 0.47, P < 0.05) and Q (r(2) = 0.47, P < 0.05). These results provide the first evidence for oxygen- or carbon-centered free radical outflow from an active muscle bed in humans.     

Radical Trapping and Inhibition of Iron-Dependent CNS Damage by Cyclic Nitrone Spin Traps

Abstract: Oxidative damage in the CNS is proposed to play a role in many acute and chronic neurodegenerative disorders. Accordingly, the nitrone spin trap α-phenyl- N - tert -butylnitrone (PBN), which reacts covalently with free radicals, has shown efficacy in a variety of animal models of CNS injury. We have synthesized a number of cyclic variants of PBN and examined their activity as radical traps and protectants against oxidative damage in CNS tissue. By using electron spin resonance spectroscopy, the cyclic nitrones MDL 101,002 and MDL 102,832 were shown to trap radicals in a manner similar to that of PBN. All cyclic nitrones tested prevented hydroxyl radical-dependent degradation of 2-deoxyribose and peroxyl radical-dependent oxidation of synaptosomes more potently than PBN. The radical scavenging properties of the cyclic nitrones contributed to a three- to 25-fold increase in potency relative to PBN against oxidative damage and cytotoxicity in cerebellar granule cell cultures. Similar to the phenolic antioxidant MDL 74,722, the nitrones minimized seizures and delayed the time to death in mice following central injection of ferrous iron. Although iron-induced lipid peroxidation was inhibited by MDL 74,722, the nitrones had no effect on this biochemical end point, indicating that iron-induced mortality does not result solely from lipid peroxidation and suggesting additional neuroprotective properties for the nitrones. These results indicate that cyclic nitrones are more potent radical traps and inhibitors of lipid peroxidation in vitro than PBN, and their ability to delay significantly iron-induced mortality in vivo suggests they may be useful in the treatment of acute and chronic neurodegeneration. Furthermore, the stability of the spin trap adducts of the cyclic nitrones provides a new tool for the study of oxidative tissue injury.     

Spin Trapping of Ibuprofen Radicals: Evidence That Ibuprofen is a Hydroxyl Radical Scavenger

The purpose of this study was to use electron paramagnetic resonance (EPR) spectroscopy to determine if ibuprofen, [2–(4-isobutylphenyl) propanoic acid], a potent nonsterodial anti-inflammatory agent, could modify hydroxyl radicals generation in vim. Ibuprofen (IBU; 0.1–50 mM) in water or water alone was added to EPR tubes containing ferrous sulfate (0.5–2.0mM). and either 5.5-dimethyl-l-pyrroline-N-oxide (DMPO; 40mM) or a-phenyl N-tert-butyl nitrone (PBN; 48 mM). Hydrogen peroxide (l mM) was added to inititate the Fenton reaction, and the systems were then analyzed by EPR spectroscopy to determine the type and relative quantity of free radical(s) produced. IBU caused a dose-dependent decrease of signal intensity of the hydroxyl radical adduct of DMPO (DMPO-OH) which is an indication that IBU either scavenges the hydroxyl radical and/or chelates iron. In addition, other radicals (presumably IBU radicals) produced in these systems were trapped by both DMPO (a_N = 16.1G, a^H_β = 24.0G) and PBN (a_N = 15.7G. a^H_β = 4.4G and a_N = 17.0G, a^H_β = 2.1 G). The signal height of these IBU radicals increased in systems containing ferrous sulfate (l mM), hydrogen peroxide (lmM), PBN (48mM), and increasing IBU concentrations. Therefore. we conclude that IBU scavenges the hydroxyl radical. If IBU chelated iron, then less hydroxyl radicals would be generated, less IBU radicals formed and the signal height of IBU radicals trapped by PBN would have decreased. However, these data do not fully exclude the possiblity that IBU may, to some extent. also chelate iron. Scavenging of hydroxyl radicals may be one of the mechanisms responsible for the beneficial action of IBU during the management of several rheumatic diseases. However, the IBU radicals produced when IBU scavenges hydroxyl radicals are reactive. and may be associated with the reported toxicity of this therapeutic agent.