Epr Spectra of Dmpo Spin Adducts of Superoxide and hydroxyl Radicals in Pyridine

Electron spin resonance spectroscopy and the spin trapping technique were used to study the formation of the superoxide radical in pyridine. 5,5-Dimethyl-1-pyrroline-N-oxide (DMPO) was employed as a trapping agent. Superoxide radical was generated using chemical (potassium superoxide) and photochemical methods with anthralin, benzanthrone, rose bengal, 1,8-dihydroxyanthraquinone and zinc tetraphenylporphyrine as photoactive pigments. Hyperfine coupling (hf) constants for DMPO/O₂- were determined to be a_N = 12.36 G, a^β_H= 9.85G, a^γ_H = 1.34 G. The a_N and a^β_H constants are in good agreement with values calculated from a previously determined relationship between hf constants and solvent acceptor number (Reszka et al., (1992) Free Radical Res. Commun., in press). When concentrated hydrogen peroxide was added to DMPO in pyridine a similar EPR spectrum was observed. It is suggested that in this case the DMPO/'O₂H adduct is formed by nucleophilic addition of H₂O₂ to DMPO to give a hydroxylamine, followed by oxidation to the respective nitroxide. The EPR spectrum observed when tetrapropylammonium hydroxide and H₂O₂ were added to DMPO in pyridine had hf couplings a_N = 13.53 G, a^β_H = 11.38 G, a^γ_H = 0.79 G and it was assigned to a DMPO/'OH adduct. This assignment was based on similarity of this spectrum to the one produced by UV photolysis of hydrogen peroxide and DMPO in aqueous solution and subsequent transfer to pyridine.     

Spin trapping endogenous radicals in MC-1010 cells: Evidence for hydroxyl radical and carbon-centered ascorbyl radical adducts

Incubation of MC-1010 cells with the spin-trapping agent 5,5-dimethyl-1-pyrroline 1-oxide (DMPO) followed by brief treatment with the solid oxidant lead dioxide (PbO₂) yielded, after filtration, a cell-free solution that contained two nitroxyl adducts. The first was the hydroxyl radical adduct, 5,5-dimethyl-2-hydroxypyrrolidine-1-oxyl (DMPO-OH), which formed immediately upon PbO₂ oxidation. The second had a 6-line EPR spectrum typical of a carbon-centered radical (A_N=15.9 G; A_H=22.4 G) and formed more slowly. No radical signals were detected in the absence of either cells or PbO₂ treatment. The 6-line spectrum could be duplicated in model systems that contained ascorbate, DMPO and DMPO-OH, where the latter was formed from hydroxyl radicals generated by sonolysis or the cleavage of hydrogen peroxide with Fe²⁺ (Fenton reaction). In addition, enrichment of MC-1010 cells with ascorbate prior to spin trapping yielded the 6-line EPR spectrum as the principal adduct following PbO₂ oxidation and filtration. These results suggest that ascorbate reacted with DMPO-OH to form a carbon-centered ascorbyl radical that was subsequently trapped by DMPO. The requirement for mild oxidation to detect the hydroxyl radical adduct suggests that DMPO-OH formed in the cells was reduced to an EPR-silent form (i.e., the hydroxylamine derivative). Alternatively, the hydroxylamine derivative was the species initially formed. The evidence for endogenous hydroxyl radical formation in unstimulated leukocytes may be relevant to the leukemic nature of the MC-1010 cell line. The spin trapping of the ascorbyl radical is the first report of formation of the carbon-centered ascorbyl radical by means other than pulse radiolysis. Unless it is spin trapped, the carbon-centered ascorbyl radical immediately rearranges to the more stable oxygen-centered species that is passive to spin trapping and characterized by the well-known EPR doublet of A_H4=1.8 G.Abbreviation EPR Electron Paramagnetic Resonance     

An Artifact in the ESR Spectrum Obtained by Spin Trapping with Dmpo

In order to overcome a common problem in spin trapping with high concentrations of 5.5-dimethyl-I-pyrroline-N-oxide (DMPO) where ESR spectra are obtained which include an unidentified set of lines composed of a triplet of doublets. commercial DMPO was analyzed for its impurities by high-performance liquid chromatography. mass spectrometry. and nuclear magnetic resonance spectroscopy. It has been determined that this undesirable ESR spectrum IS due to an impurity included in the spin trap. This compound has been assigned to the hydronylunine which is a DMPO-derivative having an epoxy ring located at the 2 and 3 positions.     

Superoxide Dismutase Enhanced the Formation of Hydroxyl Radicals in a Reaction Mixture Containing Xanthone under UVA Irradiation

To clarify the effect of superoxide dismutase (SOD) on the formation of hydroxyl radical in a standard reaction mixture containing 15 μM of xanthone, 0.1 M of 5,5-dimethyl-1-pyrroline N-oxide (DMPO), and 45 mM of phosphate buffer (pH 7.4) under UVA irradiation, electron paramagnetic resonance (EPR) measurements were performed. SOD enhanced the formation of hydroxyl radicals. The formation of hydroxyl radicals was inhibited on the addition of catalase. The rate of hydroxyl radical formation also slowed down under a reduced oxygen concentration, whereas it was stimulated by disodium ethylenediaminetetraacetate (EDTA) and diethyleneaminepentaacetic acid (DETAPAC). Above findings suggest that O₂, H₂O₂, and iron ions participate in the reaction. SOD possibly enhances the formation of the hydroxyl radical in reaction mixtures of photosensitizers that can produce O₂ ^?·.     

Spin Trapping of Free Radicals Formed During Peroxidation of Sarcolemmal Membranes (SLM)

The generation of free radicals in a superoxide (O₂-)driven Fe⁺³ catalysed reactions with isolated myocytic sarcolemma using electron spin resonance was investigated. Incubation of highly purified canine myocytic sarcolemma in the presence of the spin trap, 2-methyl-2-nitrosopropane (MNP). followed by the addition of dihydroxyfurmarate (DHF) and Fe⁺³-ADP resulted in the generation and detection of radical adducts of this spin trap. Spin trapping of the alkyl radicals with 2-methyl-2-nitrosopropane led to the identification of methyl radical adduct following exposure to DHF/Fe⁺³-ADP. With sarcolemma and the alkyl nitroso compound, the only radical product trapped was the methyl radical formed by β-scission of alkoxyl radical. The participation of hydroperoxide-derived radicals in this system verified that the decomposition of unsaturated hydroperoxy fatty acid does proceed via a free radical mechanism.     

Dmpo Spin Trapping in the Presence of Fe Ion

Aminoxyl radical formation from DMPO in the presence of Fe ion was studied to clarify the ambiguous ESR signals obtained by spin trapping with DMPO. It was found that when DMPO was used in a Fenton system, a Fe-DMPO complex was formed immediately. This complex was subsequently attacked by oxidative species originating from H₂O₂ and thus oxidative degradation of DMPO was induced in the Fenton system. On the other hand, in the case of M, PO, the degradation was found to be very slow, indicating that the 3 position of DMPO was favorably attacked by the oxidative species. Some of the degradation products are probably aminoxyl radicals. This series of the degradation products are probably aminoxyl radicals. This series of reactions may compete with spin trapping and make it difficult to analyze ESR spectra obtained in the presence of Fe ion.     

Solvent Effects in the Spin Trapping Of Lipid Oxyl Radicals

Studies documenting spin trapping of lipid radicals in defined model systems have shown some surprising solvent effects with the spin trap DMPO. In aqueous reactions comparing the reduction of H₂O₂ and methyl linoleate hydroperoxide (MLOOH) by Fe^z+, hydroxyl (HO·) and lipid alkoxyl (LO·) radicals produce identical four-line spectra with line intensities 1:2:2:1. Both types of radicals react with commonly-used HO· scavengers, e.g. with ethanol to produce ·C(CH₃)HOH and with dirnethylsulfoxide (DMSO)togive ·CH₃. However, DMSO radicals (either ·CH₃or ·OOCH₃) react further with lipids, and when radicals are trapped in these MLOOH systems, multiple adducts are evident. When acetonitrile is added to the aqueous reaction systems in increasing concentrations, ·CH₂CN radicals resulting from HO· attack on acetonitrile are evident, even with trace quantities of that solvent. In contrast, little, if any, reaction of LO· with acetonitrile occurs, even in 100% acetonitrile. A single four-line signal persists in the lipid systems as long as any water is present, although the relative intensity of the two center lines decreases as solvent-induced changes gradually dissociate the nitrogen and β-hydrogen splitting constants. Extraction of the aqueous-phase adducts into ethyl acetate shows clearly that the identical four-line spectra in the H₂0₂ and MLOOH systems arise from different radical species in this study, but the lack of stability of the adducts to phase transfer may limit the use of this technique for routine adduct identification in more complex systems. These results indicate that the four-line 1:2:2:1. a_N = a_H = 14.9G spectrum from DMPO cannot automatically be assigned to the HO· adduct in reaction systems where lipid is present, even when the expected spin adducts from ethanol or DMSO appear confirmatory for HO-. Conclusive distinction between HO· and LO· ultimately will require use of ¹³C-labelled DMPO or HPLC-MS separation and specific identification of adducts when DMPO is used as the spin trap.     

Solvent Effects in the Spin Trapping Of Lipid Oxyl Radicals

Studies documenting spin trapping of lipid radicals in defined model systems have shown some surprising solvent effects with the spin trap DMPO. In aqueous reactions comparing the reduction of H₂O₂ and methyl linoleate hydroperoxide (MLOOH) by Fe^z+, hydroxyl (HO·) and lipid alkoxyl (LO·) radicals produce identical four-line spectra with line intensities 1:2:2:1. Both types of radicals react with commonly-used HO· scavengers, e.g. with ethanol to produce ·C(CH₃)HOH and with dirnethylsulfoxide (DMSO)togive ·CH₃. However, DMSO radicals (either ·CH₃or ·OOCH₃) react further with lipids, and when radicals are trapped in these MLOOH systems, multiple adducts are evident. When acetonitrile is added to the aqueous reaction systems in increasing concentrations, ·CH₂CN radicals resulting from HO· attack on acetonitrile are evident, even with trace quantities of that solvent. In contrast, little, if any, reaction of LO· with acetonitrile occurs, even in 100% acetonitrile. A single four-line signal persists in the lipid systems as long as any water is present, although the relative intensity of the two center lines decreases as solvent-induced changes gradually dissociate the nitrogen and β-hydrogen splitting constants. Extraction of the aqueous-phase adducts into ethyl acetate shows clearly that the identical four-line spectra in the H₂0₂ and MLOOH systems arise from different radical species in this study, but the lack of stability of the adducts to phase transfer may limit the use of this technique for routine adduct identification in more complex systems. These results indicate that the four-line 1:2:2:1. a_N = a_H = 14.9G spectrum from DMPO cannot automatically be assigned to the HO· adduct in reaction systems where lipid is present, even when the expected spin adducts from ethanol or DMSO appear confirmatory for HO-. Conclusive distinction between HO· and LO· ultimately will require use of ¹³C-labelled DMPO or HPLC-MS separation and specific identification of adducts when DMPO is used as the spin trap.     

Detection of Free Radicals by Microdialysis/Spin Trapping Epr Following Focal Cerebral Ischemia-Reperfusion and a Cautionary Note on the Stability of 5,5-Dimethyl-1-Pyrroline N-Oxide (DMPO)

We have examined free radical production in a rat model of focal cerebral ischemia using microdialysis coupled with EPR analysis. A microdialysis probe was inserted 2 mm into the cerebral cortex, supplied by the right middle cerebral artery (MCA), and after a 2-hour washout period with artificial cerebral spinal fluid (ACSF), the perfusate solution was changed to ACSF containing the spin trapping agent, 5,5-dimethyl-1-pyrroline N-oxide (DMPO). No free radicals were detected by DMPO during the pre-ischemia period. Both common carotid arteries and the right MCA were then ligated for 90 minutes. Microdialysate collected every 15 min during the ischemic period demonstrated predominantly superoxide or peroxyl radical production. After release of the occlusive sutures, hydroxyl radical became apparent initially, then thiyl and carbon centered radicals appeared later in samples collected every 15 min for two hours following cortical reperfusion. Careful studies on the purification and stability of DMPO solution were performed to circumvent artifacts and spurious signals.     

A Kinetic and ESR Investigation of Iron(II) Oxalate Oxidation by Hydrogen Peroxide and Dioxygen as a Source of Hydroxyl Radicals

The reaction of Fe^II oxalate with hydrogen peroxide and dioxygen was studed for oxalate concentrations up to 20 mM and pH 2-5, under which conditions mono- and bis-oxalate comlexes (Fe^II(ox) and Fe^II(ox)₂^2-) and uncomplexed Fe²⁺ must be considered. The reaction of Fe^II oxalate with hydrogen peroxide (Fe²⁺ + H₂O₂ → Fe³⁺ + *OH + OH^-) was monitored in continuous flow by ESR with t-butanol as a radical trap. The reaction is much faster than for uncomplexed Fe²⁺ and a rate constant, k = 1 × 10⁴ M-¹ s^-1 is deduced for Fe^II(ox). The reaction of Fe^II oxalate with dioxygen is strongly pH dependent in a manner which indicates that the reactive species is Fe^II(ox)₂^2-, for which an apparent second order rate constant, k = 3.6 M^-1 s^-1, is deduced. Taken together, these results provide a mechanism for hydroxyl radical production in aqueous systems containing Fe^II complexed by oxalate. Further ESR studies with DMPO as spin trap reveal that reaction of Fe^II oxalate with hydrogen peroxide can also lead to formation of the carboxylate radical anion (CO₂^*-), an assignment confirmed by photolysis of Fe^III oxalate in the presence of DMPO.     

Oxygen Radical Formation in Well-Washed Rat Liver Microsomes: Spin Trapping Studies

The generation of hydroxyl radicals by rat liver microsomes was monitored by spin trapping with 5, 5-dimethylpyrroline N-oxide (DMPO). The results confirm and extend previous data which demonstrated that hydroxyl radicals are produced by microsomes in the presence of NADPH and O₂, and without the exogenous addition of iron. No EPR signals could be detected unless catalase activity which was associated with the microsomes could be substantially diminished. Addition of azide was the most effective means of eliminating catalase activity, but azide also reacted rapidly with hydroxyl radicals, forming azidyl radicals which were in turn trapped by DMPO. Extensive washing and preincubation of microsomes with 3-amino-1, 2,4-triazole in the presence of H₂O₂ were evaluated as alternative methods of decreasing the catalase contamination of microsomes. Although neither method completely eliminated microsomal catalase activity, addition of azide was no longer necessary for hydroxyl radical detection with DMPO. When highly washed microsomal preparations were tested, weak signals of the superoxide radical adduct of DMPO could also be detected. These data indicate that the sensitivity of spin trapping in microsomal systems can be improved substantially when care is taken to eliminate cytosolic contaminants such as catalase.     

Superoxide radicals are not the main promoters of acceptor-side-induced photoinhibitory damage in spinach thylakoids

Superoxide anion radical formation was studied with isolated spinach thylakoid membranes and oxygen evolving Photosystem II sub-thylakoid preparations using the reaction between superoxide and Tiron (1,2-dihydroxybenzene-3,5-disulphonate) which results in the formation of stable, EPR detectable Tiron radicals.We found that superoxide was produced by illuminated thylakoids but not by Photosystem II preparations. The amount of the radicals was about 70% greater under photoinhibitory conditions than under moderate light intensity. Superoxide production was inhibited by DCMU and enhanced 4–5 times by methyl viologen. These observations suggest that the superoxide in illuminated thylakoids is from the Mehler reaction occurring in Photosystem I, and its formation is not primarily due to electron transport modifications brought about by photoinhibition.Artificial generation of superoxide from riboflavin accelerated slightly the photoinduced degradation of the Photosystem II reaction centre protein D1 but did not accelerate the loss of oxygen evolution supported by a Photosystem II electron acceptor. However, analysis of the protein breakdown products demonstrated that this added superoxide did not increase the amount of fragments brought about by photoinhibition but introduced an additional pathway of damage.On the basis of the above observations we propose that superoxide redicals are not the main promoters of acceptor-side-induced photoinhibition of Photosystem II.Abbreviations DCBQ- 2,5-dichloro-p-benzoquinone - DCMU- 3- (3,4-dichlorophenyl)-1,1-dimethylurea - DMBQ- 2,5-dimethyl-p-benzoquinone - DMPO- 5,5-dimethyl-pyrrolin N-oxide - Hepes- N-(2-hydroxyethyl)-piperazine-N-(2-ethanesulfonic acid) - Mes- 2-(N-morpholino)-ethanesulfonic acid - methyl viologen- 1,1-dimethyl-4,4-bipyridinium dichloride - PS- Photosystem - SOD- Superoxide dismutase (EC 1.15.1.1) - Tiron- 1,2-dihydroxybenzene-3,5-disulphonate - Tris- 2-amino-2-hydroxymethylpropane-1,3-diol     

Superoxide anion radical scavenging property of catecholamines

The direct effect of the four catecholamines (adrenaline, noradrenaline, dopamine and isoproterenol) on superoxide anion radicals () was investigated. The reaction between 18‐crown‐6‐ether and potassium superoxide in dimethylsulfoxide was used as a source of . The reactivity of catecholamines with was examined using chemiluminescence, reduction of nitroblue tetrazolium and electron paramagnetic resonance spin‐trapping techniques. 5,5‐Dimethyl‐1‐pyrroline‐N‐oxide was included as the spin trap. The results showed that the four catecholamines were effective and efficient in inhibiting chemiluminescence accompanying the potassium superoxide/18‐crown‐6‐ether system in a dose‐dependent manner over the range 0.05–2 mm in the following order: adrenaline > noradrenaline > dopamine > isoproterenol, with, IC₅₀ = 0.15 ± 0.02 mm 0.21 ± 0.03 mm , 0.27 ± 0.03 mm and 0.50 ± 0.04 mm , respectively. The catecholamines examined also exhibited a strong scavenging effect towards when evaluated this property by the inhibition of nitroblue tetrazolium reduction (56–73% at 1 m concentration). A very similar capacity of scavenging was monitored in the 5,5‐dimethyl‐1‐pyrroline‐N‐oxide spin‐trapping assay. The results suggest that catecholamines tested may involve a direct effect on scavenging radicals. Copyright © 2013 John Wiley & Sons, Ltd.     

The Copper Complex of Captopril is not a Superoxide Dismutase Mimic. Artefacts in DMPO Spin Trapping

The effect of captopril and of its copper complex on several superoxide-dependent reactions used to detect and assay superoxide dismutase activity was studied, including pyrogallol and hematoxylin autoxidation and Nitro Blue Tetrazolium reduction. ln none of these systems were superoxide dismutase-like properties of captopril/Cu apparent. Captopril/Cu decreased the yield of DMPO-OH adducts generated by KO₂ but this effect may be due to the acceleration of the decay of the adduct by captopril/Cu.     

Spin-Trapping of the Superoxide Radical in Aprotic Solvents

The superoxide adduct of 5,5-dimethyl-l-pyrroline-N-oxide (DMPO) has been detected by EPR spectroscopy in aprotic solvents using KO₂ solubilized in 18-crown-6-ether as a source of superoxide. The EPR hyperfine splitting constants of the DMPO-superoxide adduct were as follows: benzene/toluene (a_N = 12.65 G; a^β_β = 10.4G; a_γ = 1.3G); heptane (a_N = 12.49G; a_β^β = 10.29G; a^γ_H = 1.2g); and acetone (a_N = 12.6G; a_β^β = 10.17 G; a_γ = 1.3 G). The EPR parameters for benzene, toluene and heptane differ significantly from previously reported values. A plot of the hyperfine splitting constants for the DMPO superoxide adduct as a function of solvent polarity (Kosower Z value) indicates that while a_N and a_β^β both decrease by about 1 G on going from water to ethanol, further decreases in polarity do not greatly affect these EPR parameters.     

Superoxide,Hydrogen Peroxide and Hydroxyl Radical in D1/D2/cytochrome b-559 Photosystem II Reaction Center Complex

Spin-trapping electron spin resonance (ESR) was used to monitor the formation of superoxide and hydroxyl radicals in D1/D2/cytochrome b-559 Photosystem II reaction center (PS II RC) Complex. When the PS II RC complex was strongly illuminated, superoxide was detected in the presence of ubiquinone. SOD activity was detected in the PS II RC complex. A primary product of superoxide, hydrogen peroxide, resulted in the production of the most destructive reactive oxygen species, *OH, in illuminated PS II RC complex. The contributions of ubiquinone, SOD and H(2)O(2) to the photobleaching of pigments and protein photodamage in the PS II RC complex were further studied. Ubiquinone protected the PS II RC complex from photodamage and, interestingly, extrinsic SOD promoted this damage. All these results suggest that PS II RC is an active site for the generation of superoxide and its derivatives, and this process protects organisms during strong illumination, probably by inhibiting more harmful ROS, such as singlet oxygen.     

Oxy Radicals in the Eye Tissues of Rabbits After Diquat In Vivo

It is our hypothesis that oxygen free radicals are the triggering agents in cataractogenesis. However, besides H₂O₂ there is no direct evidence of generation of oxy radicals in the eye tissues. Due to extremely short life of O^?₂, and OH. it is not possible to measure their cellular steady state levels. We found that indirect spectrophotometric techniques based on superoxide dismutase (SOD)-inhibitable cytochrome c reduction for estimation of O^?₂. salicylate hydroxylation for OH. and peroxidase catalysed reoxidation of 2,6-dichlorophenolindophenol for H₂O₂ were suitable, sensitive and reproducible for measurements of the reactive species of O₂ produced in the eye tissues by oxy radical enhancer, diquat in the rabbit eye in vivo, After a single intravitreal injection of 60,120 or 300 nmole diquat in the right eyes, there was a dose-dependent rise in O^?₂ levels, 106–265 fold in the aqueous humor, 34–87 fold in the vitreous humor, 6–19 fold in the lens, and 43–88 fold in the retina as compared to 0.16 μM. 0.21 μM, 2.47 nmole/g and 5.56 nmole/g in tissues of the normal eyes, respectively. There were similar increases of OH * in the eye tissues, and of H₂O₂ in the aqueous humor and vitreous humor after diquat injection.

We propose that endogenous reductants of the eye tissues univalently reduce diquat to its free radical which spontaneously reacts with O₂ generaiing O^?₂, in excessive amounts, further giving rise to H₂O₂ and OH triggering cataractogenesis.     

Free Radicals in the Atmosphere

Like the oxidation in a flame, the oxidation in the atmosphere is mediated by free radicals. Unlike a flame, however, atmospheric oxidation needs an external source of energy: the sun light. In fact the most important radical acting in the lower atmosphere, the hydroxyl radical, OH, is produced following the UV-photolysis of ozone, O,which yields an excited oxygen atom, O'D:

OH reacts with most atmospheric trace gases, in many cases as the first and rate determining step in the reaction chain leading to oxidation. In this way a host of various other radicals (e.g. peroxy radicals), most of them very short lived, are generated. Usually these oxidation reactions form chains which regenerate OH, thus maintaining OH at a relatively high concentration level on the order of 10⁶cm∼³ during the day. The reactions which control the OH concentration will be discussed in detail. During the night radical formation is greatly diminished. It proceeds, for example, through the reaction of defines with O, and. in dry air, through reaction of defines and aldehydes with the nitrate radical, NO,.     

Free Radicals in the Atmosphere

Like the oxidation in a flame, the oxidation in the atmosphere is mediated by free radicals. Unlike a flame, however, atmospheric oxidation needs an external source of energy: the sun light. In fact the most important radical acting in the lower atmosphere, the hydroxyl radical, OH, is produced following the UV-photolysis of ozone, O,which yields an excited oxygen atom, O'D:

OH reacts with most atmospheric trace gases, in many cases as the first and rate determining step in the reaction chain leading to oxidation. In this way a host of various other radicals (e.g. peroxy radicals), most of them very short lived, are generated. Usually these oxidation reactions form chains which regenerate OH, thus maintaining OH at a relatively high concentration level on the order of 10⁶cm～³ during the day. The reactions which control the OH concentration will be discussed in detail. During the night radical formation is greatly diminished. It proceeds, for example, through the reaction of defines with O, and. in dry air, through reaction of defines and aldehydes with the nitrate radical, NO,.     

Application of Spin Trapping to Human Phagocytic Cells: Insight Into Conditions for Formation and Limitation of Hydroxyl Radical

In recent years spin trapping techniques have been used extensively to better understand the free radical biology of phagocytic cells. These results demonstrate that spin trapping is of adequate sensitivity to detect superoxide and/or hydroxyl radical generated by these cells, and that spin trapping is capable of measuring phagosomal radicals as well. However. neither neutrophils. monocytes. nor monocyte derived macro-phages generate hydroxyl radical in the absence of exogenous iron. Furthermore. neutrophil lactoferrin and myeloperoxidase limit the magnitude (and in the case of lactoferrin the duration) of hydroxyl radical formed by neutrophils in an iron catalyzed system. Since monocytic phagocytes posxss no lactoferrin, and limited myeloperoxidase, hydroxyl radical may play an important role in the inflammatory behavior of mononuclear phagocytes.