Interaction of tert -butyl Hydroperoxide with Hypochlorous Acid. A Spin Trapping and Chemiluminescence Study

The formation of radical species during the reaction of tert-butyl hydroperoxide and hypochlorous acid has been investigated by spin trapping and chemiluminescence. A superposition of two signals appeared incubating tert-butyl hydroperoxide with hypochlorous acid in the presence of the spin trap &#102 -(4-pyridyl-1-oxide)-N-tert-butylnitrone (POBN). The first signal (a_N = 1.537mT, a^&#103_H = 0.148mT) was an oxidation product of POBN caused by the action of hypochlorous acid. The second spin adduct (a_N = 1.484mT, a^&#103_H = 0.233mT) was derived from a radical species that was formed in the result of reaction of tert-butyl hydroperoxide with hypochlorous acid. Similarly, a superposition of two signals was also obtained using the spin trap N-tert-butyl- &#102 -phenylnitrone (PBN). tert-Butyl hydroperoxide was also treated with Fe²⁺ or Ce⁴⁺ in the presence of POBN. Using Fe²⁺ a spin adduct with a _N= 1.633mT and a^&#103_H = 0.276mT was observed. The major spin adduct formed with Ce⁴⁺ was characterised by α_N = 1.480mT and a^&#103_H = 0.233mT. The reaction of tert-butyl hydroperoxide with hypochlorous acid was accompanied by a light emission, that time profile and intensity were identical to those emission using Ce⁴⁺. The addition of Fe²⁺ to tert-butyl hydroperoxide yielded a much smaller chemiluminescence. Thus, tert-butyl hydroperoxide yielded in its reaction with hypochlorous acid or Ce⁴⁺ the same spin adduct and the same luminescence profile. Because Ce⁴⁺ is known to oxidise organic hydroperoxides to peroxyl radical species, it can be concluded that a similar reaction takes place in the case of hypochlorous acid.     

The interaction of hypochlorite with fatty acid hydroperoxides results in the generation of free radicals

The interaction of hypochlorite with linoleic acid hydroperoxides was studied by the coumarin C-525-enhanced chemiluminescence and ESR spin trapping techniques. Linoleic acid hydroperoxide was obtained in the reaction of lipoxygenase and linoleic acid. Alpha-(4-pyridyl-1-oxyl)-N-tert Butylnitron was used as a spin trap. It was shown that the addition of hypochlorite to the incubation media containing linoleic acid and lipoxygenase resulted in an intensive chemiluminescence flash. The intensity of this flash correlated with the hydroperoxide concentration. The analysis of ESR spectra of spin adducts produced in the reaction of hypochlorite with linoleic acid hydroperoxide showed the presence of O-centered, most likely peroxyl, radical with the splitting constants alphabetaH = 0.260 mT aN = 1.662 mT and C-centered penthyl radical with the splitting constants alphabetaH = 0.260 mT; aN = 1.662 mT. These data suggest that hypochlorite produced by phagocytes in vivo can induce the generation of free O- and C-centered radicals, promoters of free radical processes.     

Detection of peroxyl and alkoxyl radicals produced by reaction of hydroperoxides with heme-proteins by electron spin resonance spectroscopy

ESR spin trapping using the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO) has been used to directly detect alkoxyl radicals (with hyperfine coupling constants aN 1.488, aH 1.600 mT and aN 1.488, aH 1.504 mT for the tBuO. and PhC(CH3)2O. adducts, respectively) and peroxyl radicals (aN 1.448, aH 1.088, aH 0.130 mT and aN 1.456, aH 1.064, aH 0.128 mT for the tBuOO. and PhC(CH3)2OO. adducts, respectively) produced from t-butyl or cumene hydroperoxides by a variety of heme-containing substances (purified cytochrome P-450, metmyoglobin, oxyhemoglobin, methemoglobin, cytochrome c, catalase, horseradish peroxidase) and the model compound hematin. The observed species exhibit a complicated dependence on reagent concentrations and time, with maximum concentrations of the peroxyl radical adducts being observed immediately after mixing of the hydroperoxide with low concentrations of the heme-compound. Experiments with inhibitors (CN-, N3-, CO, metyrapone and imidazole) suggest that the major mechanism of peroxyl radical production involves high-valence-state iron complexes in a reaction analogous to the classical peroxidase pathway. The production of alkoxyl radicals is shown to arise mainly from the breakdown of peroxyl radical spin adducts, with direct production from the hydroperoxide being a relatively minor process.     

Photodegradation of hyaluronic acid: EPR and size exclusion chromatography study.

Photochemically induced radical reactions involving the lateral sequences and the end macromolecular chain groups of hyaluronic acid in aqueous solutions at 293K were studied by EPR spin trapping technique with DMPO (5,5-dimethylpyrroline-1-oxide). In the first 1-10 minutes of irradiation EPR indicates spin adducts of two carbon centered radicals with the splitting constants of aN = 1.60 mT, aH = 2.51 mT and aN = 1.56 mT, aH = 2.28 mT. After longer irradiation time (over 10 minutes) dominate two further DMPO adducts of radicals centered on hetero-atoms with splitting constants of aN = 1.44 mT, aH = 1.60 mT and of aN = 1.49 mT, aH = 1.49 mT. Simultaneously, molecular weight followed by SEC decreases, suggesting that UV irradiation leads to the breaking of interglycosidic bonds of hyaluronic acid main macromolecular chain.     

Detection of lipid radicals by electron paramagnetic resonance spin trapping using intact cells enriched with polyunsaturated fatty acid.

Electron paramagnetic resonance (EPR) spin trapping was used to detect lipid-derived free radicals generated by iron-induced oxidative stress in intact cells. Using the spin trap alpha-(4-pyridyl 1-oxide)-N-tert-butylnitrone (POBN), carbon-centered radical adducts were detected. These lipid-derived free radicals were formed during incubation of ferrous iron with U937 cells that were enriched with docosahexaenoic acid (22:6n-3). The EPR spectra exhibited apparent hyperfine splittings characteristic of a POBN/alkyl radical, aN = 15.63 +/- 0.06 G and aH = 2.66 +/- 0.03 G, generated as a result of beta-scission of alkoxyl radicals. Spin adduct formation depended on the FeSO4 content of the incubation medium and the number of 22:6-enriched cells present; when the cells were enriched with oleic acid (18:1n-9), spin adducts were not detected. This is the first direct demonstration, using EPR, of a lipid-derived radical formed in intact cells in response to oxidant stress.     

Spin-trapping of sulfite radical anion, SO3-., by a water-soluble, nitroso-aromatic spin-trap

Sulfite radical anion, SO3-., which is generated either by non-enzymatic reaction of hydrogen peroxide (H2O2-) with sulfite (SO3(2-)) or by the oxidation of bisulfite (HSO3) with Ce4+ ion, can be trapped with a water-soluble, nitroso-aromatic spin-trap, sodium 3,5-dibromo-4-nitrosobenzenesulfonate (DBNBS, 1), yielding an ESR spectrum with coupling constants [aN (1) = 12.9 G, aH (2) = 0.8 G] and a g-value of 2.0063. The SO3- radical adduct (spin adduct) was observed even in the presence of the very low concentration of H2O2 (1.21 X 10(-2) mumol).     

The NoH value in EPR spin trapping: a new parameter for the identification of 5,5-dimethyl-1-pyrroline-N-oxide spin adducts.

The ratio of the nitrogen to hydrogen hyperfine splittings (aN/aH) of spin adducts derived from the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) has been found to be a useful parameter for adduct identification. For example, this parameter makes it possible to distinguish between the superoxide (aN/aH = 1.22-1.26) and peroxyl (aN/aH = 1.33-1.40) radical adducts of DMPO in aqueous solution. Since the aN to aH ratio corrects for minor differences in EPR spectrometer calibration, it is a more reproducible parameter than the aN and aH values themselves.     

Electron spin resonance and pulse radiolysis studies on the spin trapping of sulphur-centered radicals

Thiyl radicals are shown to be readily trapped with the spin traps 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) and 3,3,5,5-tetramethyl-1-pyrroline-N-oxide (TMPO) giving characteristic spin adducts with hyperfine coupling constants aN 1.52-1.58, aH 1.52-1.80 mT, and g values in the range 2.0065-2.0067 for the DMPO adducts and aN 1.50-1.56, aH 1.70-1.92 mT, g 20049-2.0051 for the TMPO adducts. Kinetic data obtained from pulse radiolysis studies show that, in general, thiyl radicals react rapidly with these spin traps with rate constants of the order of 10(7)-10(8) dm3 mol-1 s-1. The tetramethylated spin trap TMPO though giving slightly less intense electron spin resonance (ESR) spectra, produces longer lived adducts, and is suggested to be of greater utility due to the more characteristic nature of the coupling constants of the observed adducts; reaction of certain thiyl radicals with DMPO produces adducts which are superficially similar to the hydroxyl radical adduct to the same trap.     

Formation of acyl radical in lipid peroxidation of linoleic acid by manganese-dependent peroxidase from Ceriporiopsis subvermispora and Bjerkandera adusta.

Lipid peroxidation by managanese peroxidase (MnP) is reported to decompose recalcitrant polycyclic aromatic hydrocabon (PAH) and nonphenolic lignin models. To elucidate the oxidative process, linoleic acid and 13(S)-hydroperoxy-9Z,11E-octadecadienoic acid [13(S)-HPODE] were reacted with MnPs from Ceriporiopsis subvermispora and Bjerkandera adusta and the free radicals produced were analyzed by ESR. When the MnPs were reacted with 13(S)-HPODE in the presence of Mn(II), H2O2 and tert-nitrosobutane (t-NB), the ESR spectrum contained a sharp triplet of acyl radical (aN = 0.81 mT). Formation of acyl radical was also observed in the reactions of Mn(III)-tartrate with 13(S)-HPODE and with linoleic acid, but the latter reaction occurred explosively after an induction period of around 30 min. Reactions of MnP with linoleic acid in the presence of Mn(II), H2O2 and t-NB gave no spin adducts while addition of t-NB after preincubation of linoleic acid with MnP/Mn(II)/H2O2 for 2 h gave spin adducts of carbon-centered (aN = 1.53 mT, aH = 0.21 mT) and acyl (aN = 0.81 mT) radicals. In contrast to linoleic acid, methyl linoleate and oleic acid were not peroxidized by MnP and chelated Mn(III) within a few hours, indicating that structures containing both the 1,4-pentadienyl moiety and a free carboxyl group are necessary for inducing the peroxidation in a short reaction time. These results indicate that MnP-dependent lipid peroxidation is not initiated by direct abstraction of hydrogen from the bis-allylic position during turnover but proceeds by a Mn(III)-dependent hydrogen abstraction from enols and subsequent propagation reactions involving the formation of acyl radical from lipid hydroperoxide. This finding expands the role of chelated Mn(III) from a phenol oxidant to a strong generator of free radicals from lipids and lipid hydroperoxides in lignin biodegradation.     

Vanadyl-induced Fenton-like reaction in RNA. An ESR and spin trapping study.

Vanadyl (VO2+) complexed to RNA reacts with hydrogen peroxide in a Fenton-like manner producing hydroxyl radicals (.OH). The hydroxyl radicals can be spin trapped with 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) forming the DMPO-OH spin adduct. In addition, in the presence of ethanol the formation of the hydroxyethyl radical adduct of DMPO (DMPO-ETOH) confirms the production of hydroxyl radicals by the RNA/VO2+ complex. When the reaction between the RNA/VO2+ complex and H2O2 is carried out in the presence of the spin trap 2-methyl-2-nitrosopropane (MNP), radicals produced in the reaction of .OH with RNA are trapped. Base hydrolysis of the MNP-RNA adducts (pH 12) followed by a reduction in the pH to pH 7 after hydrolysis is complete, yields an MNP adduct with a well-resolved ESR spectrum identical to the ESR spectrum obtained from analogous experiments with poly U. The ESR spectrum consists of a triplet of sextets (aN = 1.48 mT, a beta N = 0.25 mT and a beta H = 0.14 mT), indicating that the unpaired nitroxide electron interacts with the nuclei of a beta-nitrogen and beta-hydrogen. The results suggest that the .OH generated in the RNA/VO2+ reaction with H2O2 add to the C(5) carbon of uracil forming a C(6) carbon centered radical. This radical is subsequently spin trapped by MNP.     

Peroxyl radical is produced upon the interaction of hypochlorite with tert-butyl hydroperoxide

As we reported previously, hypochlorite interacting with organic hydroperoxides causes their decomposition ((1995) Biochemistry (Moscow), 60, 1079-1086). This interaction was supposed to be a free-radical process and serve as a source of free radicals initiating lipid peroxidation (LP). The present study is the first attempt to detect and identify free radicals produced in the reaction of hypochlorite with tert-butyl hydroperoxide, (CH₃)₃COOH, which we have used as an example of organic hydroperoxides. We have used a direct method for free radical detection, EPR of spin trapping, and the following spin traps: N-tert-butyl--phenylnitrone (PBN) and -(4-pyridyl-1-oxyl)-N-tert-butylnitrone (4-POBN). When hypochlorite was added to (CH₃)₃COOH in the presence of a spin trap, an EPR spectrum appeared representing a superposition of two signals. One of them belonged to a spin adduct formed as a result of direct interaction of hypochlorite with the spin trap (hyperfine splitting constants were: _H H = 0.148 mT; a_N = 1.537 mT; and H_PP = 0.042 mT for 4-POBN and _H = 0.190 mT; a_N = 1.558 mT; and H_PP = 0.074 mT for PBN). The other signal was produced by hypochlorite interactions with (CH3)3COOH itself (hyperfine splitting constants were: _H = 0.233 mT; aN = 1.484 mT; H_PP = 0.063 mT and _H = 0.360 mT; a_N = 1.547 mT; H_PP = 0.063 mT for 4-POBN and PBN, respectively). Comparison of spectral characteristics of this spin adduct with those of tert-butoxyl or tert-butyl peroxyl radicals produced in known reactions of (CH₃)₃COOH with Fe²⁺ and Ce⁴⁺, respectively, showed that the radical (CH₃)₃COO. is produced from the interaction of hypochlorite with (CH₃)₃COOH^. Like Ce⁴⁺ but not Fe²⁺, hypochlorite addition to (CH₃)₃COOH was accompanied by a bright flash of chemiluminescence characteristic of the reactions in which peroxyl radicals are produced. Thus, all these results suggest peroxyl radical production in the reaction of hypochlorite with hydroperoxide. This reaction is one of the most possible ways for the initiation of free-radical LP that occurs in vivo, when hypochlorite interacts with unsaturated lipids comprising natural protein–lipid complexes, such as lipoproteins and biological membranes.     

Spin-trapping of superoxide ion by a water-soluble, nitroso-aromatic spin-trap

Spin-trapping of superoxide ion, O2-, which is produced from two different sources (OH(-)-DMSO and xanthine-xanthine oxidase systems), was investigated by use of a water-soluble, notroso-aromatic spin trap, sodium 3,5-dibromo-4-nitrosobenzene-sulfonate (DBNBS). It was found that O2- from all sources was easily trapped by DBNBS to yield the stable O2- adduct showing the ESR spectrum consisting of a triplet of a triplet [aN (1) = 12.63 G and aH (2) = 0.71 G]. Hydroperoxy radical (HO2.), which can be generated from the oxidation of hydrogen peroxide with Ce4+ ion, was not trapped by DBNBS. These results indicate that the trapped radical is O2-, but not HO2..     

The enzymatic reduction of actinomycin D to a free radical species

Actinomycin D is an antitumor antibiotic in current clinical use. The ability of this and other antitumor antibiotics to undergo a reductive metabolism to produce free radical species has raised considerable interest in the literature in the past few years. The ability of actinomycin D to undergo a reductive metabolism was investigated using a ferredoxin reductase/NADPH system. This enzyme system has been used by a number of authors as a model for an enzymatic drug reducing system. In this study radical production was measured using direct ESR spectroscopy, the spin trapping technique, and oxygen consumption. It was shown that under anaerobic conditions the ferredoxin reductase/NADPH system could reduce actinomycin D to produce a semiquinone-imine free radical (aN = 2.8 (2N); aH = 2.8 (3H)). This radical production was found to be both drug and NADPH dependent. The effect of DNA on the drug's metabolism was also investigated. This was thought to be important because the proposed therapeutic action of the drug is centered on the DNA. Addition of calf thymus DNA to the reaction system abolished the signal produced by the actinomycin D, suggesting that intercalated actinomycin D is not a suitable substrate for ferredoxin reductase. Under aerobic conditions the ferredoxin reductase/NADPH/actinomycin D system generated the superoxide anion radical by reducing molecular oxygen. Evidence for this was obtained by spin trapping with 5,5-dimethyl-1-pyrroline N-oxide (DMPO). The DMPO-superoxide radical adduct was produced (aN = 14.4 G; aH beta = 11.4 G; aH gamma = 1.3 G). Production of this adduct was drug and NADPH dependent, and was inhibited by superoxide dismutase. Superoxide production was also monitored by oxygen consumption studies.     

Interaction of tert-butyl hydroperoxide with hypochlorite induces peroxyl radicals. A chemiluminescence study

The interaction of hypochlorite (HOCl/OCl-) with tert-butyl hydroperoxide ((CH3)3COOH) was investigated by chemiluminescence. It was shown that the addition of HOCl/OCl- to (CH3)3COOH induces a fast chemiluminescent flash. The intensity of this flash increases with the increase in both HOCl/OCl- and (CH3)3COOH concentration. The chemiluminescence is quenched in a concentration-dependent manner in the presence of free radical spin traps N-tert-butyl nitrone and alpha-(4-pyridyl-1-oxyl)-N-tert-butyl nitrone. This fact proves that free radicals take part in the interaction of HOCl/OCl- and (CH3)3COOH. Hypochlorite yielded a very similar chemiluminescence spectrum in its reaction with (CH3)3COOH as Ce4+. It differed considerably from the spectrum in the system H2O2 and HOCl/OCl-. It is well known that the interaction of Ce4+ and (CH3)3COOH produces peroxyl radicals. These results confirm the hyothesis that the interaction of HOCl/OCl- and (CH3)3COOH is mediated by peroxyl radicals. Thus, organic hydroperoxides always present in unsaturated lipids can induce lipid peroxidation processes in the reaction with HOCl/OCl-.     

EPR detection of lipid-derived free radicals from PUFA, LDL, and cell oxidations

We have used the spin trap 5,5-dimethyl-pyrroline-1-oxide (DMPO) and EPR to detect lipid-derived radicals (Ld*) during peroxidation of polyunsaturated fatty acids (PUFA), low-density lipoprotein (LDL), and cells (K-562 and MCF-7). All oxygen-centered radical adducts of DMPO from our oxidizable targets have short lifetimes (<20 min). We hypothesized that the short lifetimes of these spin adducts are due in part to their reaction with radicals formed during lipid peroxidation. We proposed that stopping the lipid peroxidation processes by separating oxidation-mediator from oxidation-substrate with an appropriate extraction would stabilize the spin adducts. To test this hypothesis we used ethyl acetate to extract the lipid-derived radical adducts of DMPO (DMPO/Ld*) from an oxidizing docosahexaenioc acid (DHA) solution; Folch extraction was used for LDL and cell experiments. The lifetimes of DMPO spin adducts post-extraction are much longer (>10 h) than the spin adducts detected without extraction. In iron-mediated DHA oxidation we observed three DMPO adducts in the aqueous phase and two in the organic phase. The aqueous phase contains DMPO/HO* aN approximately aH approximately 14.8 G) and two carbon-centered radical adducts (aN1 approximately 15.8 G, aH1 approximately 22.6 G; aN2 approximately 15.2 G, aH2 approximately 18.9 G). The organic phase contains two long-chain lipid radical adducts (aN approximately 13.5 G, aH approximately 10.2 G; and aN approximately 12.8 G; aH approximately 6.85 G, 1.9 G). We conclude that extraction significantly increases the lifetimes of the spin adducts, allowing detection of a variety of lipid-derived radicals by EPR.     

Acute methanol intoxication generates free radicals in rats: an ESR spin trapping investigation

Electron spin resonance (ESR) spectroscopy has been used to investigate free radical generation in rats with acute methanol poisoning. The spin trapping technique was used where a spin trapping agent, alpha-(4-pyridyl 1-oxide)-N-tert-butylnitrone (POBN), reacted with the corresponding alcohol-derived or alcohol-dependent radical to form radical adducts. One radical adduct was detected in both bile and urine samples 2 h after acute methanol poisoning in male Sprague Dawley rats. The hyperfine coupling constants for the radical adduct from [(13)C]-labeled methanol detected in the bile were a(N) = 15.58, a(beta)(H) = 2.81 G, and a(beta)(13C) = 4.53 G, which unambiguously identified this species as POBN/*CH@OH. The same radical adduct was detected in urine. The identification of a methanol-derived radical adduct in samples from bile and urine provided strong direct evidence for the generation of the alcohol-derived radicals during acute intoxication by methanol. Simultaneous administration of the alcohol dehydrogenase inhibitor 4-methylpyrazole and methanol resulted in an increase in the generation of the free radical metabolite detected in the bile. This is the first ESR evidence of methanol-derived free radical generation in an animal model of acute methanol intoxication.     

Alkyl free radicals from the beta-scission of fatty acid alkoxyl radicals as detected by spin trapping in a lipoxygenase system

2-Methyl-2-nitrosopropane (tNB)-radical adducts from incubation mixtures of fatty acids and soybean lipoxygenase in borate buffer (pH 9.0) were measured by electron paramagnetic resonance (EPR). In addition to the previously reported six-line signal of secondary carbon-centered radicals (RCHR'), a weak signal submerged in the baseline was detected after the peroxidation phase was finished. We propose that this radical is a decomposition product formed via beta-scission of fatty acid alkoxyl radicals. EPR spectra of tNB-radical adducts formed in mixtures of either linoleic acid, arachidonic acid, or 15-hydroperoxyeicosatetraenoic acid with lipoxygenase exhibited hyperfine structure characteristic of tNB/.CH2CH2-R with hyperfine coupling constants: aN = 17.1 G; aH beta = 11.2 G (2H); and aH gamma = 0.6 G (2H). In the case of linolenic acid, this radical tNB/.CH=CH-R' with hyperfine coupling constants: aN = 17.1 G; aH beta = 10.9 G (2H); aH gamma = 1.1 G; and aH delta = 0.5 G. In accord with the decomposition scheme of hydroperoxides derived from unsaturated fatty acids, the radical adducts tNB/.CH2CH2-R and tNB/.CH2-CH=CH-R' were assigned as the pentyl and 2-pentenyl radicals, respectively.     

Identification of a radical formed in the reaction mixtures of oxidized phosphatidylcholine with ferrous ions using HPLC-ESR and HPLC-ESR-MS

Identification of free radicals was performed for the reaction mixtures of autoxidized 1,2-dilinoleoylphosphatidylcholine (DLPC) with ferrous ions (or DLPC hydroperoxide with ferrous ions) and of DLPC with soybean lipoxygenase using electron spin resonance (ESR), high performance liquid chromatography (HPLC)-ESR and HPLC-ESR-mass spectrometry (MS) combined use of spin trapping technique. ESR measurements of the reaction mixtures showed prominent signals with hyperfine coupling constants (a^N=1.58 mT and a^Hβ=0.26 mT). Outstanding peaks with almost same retention times (autoxidized DLPC, 36.9 min; DLPC hydroperoxide, 35.0 min; DLPC with soybean lipoxygenase, 37.1 min) were observed on the elution profile of the HPLC-ESR analyses of the reaction mixtures. HPLC-ESR-MS analyses of the reaction mixtures gave two ions at m/z 266 and 179, suggesting that 4-POBN/pentyl radical adduct forms in these reaction mixtures.     

Use of 3,3,5,5-tetramethyl-1-pyrroline-1-oxide spin trap for the continuous flow ESR monitoring of hydroxyl radical generation in the ischemic and reperfused myocardium

A new approach for in vivo spin trapping and quantitation of oxygen-derived free radicals has been developed using a continuous flow high speed ESR detection system. Spin adducts of OH. were detected as 1:1:1:1:1:1 sextets (aN=15.2 G, aH=16.8 G, g=2.0055) in the isolated rat heart when perfused with 3,3,5,5-tetramethyl-1-pyrroline-1-oxide (40 mM) during a 10-min control pretreatment (14 ml/min) followed by 50 min of low-flow ischemia (1 ml/min), 30 min of global ischemia and subsequent reperfusion at 14 ml/min. The ESR signals appeared within 15-20 min of low-flow ischemia and grew moderately during the remaining 30 min at a rate of 2-6 nmoles of spin adduct released per minute. Post-ischemic reperfusion was characterized by a burst of spin adduct formation at 30 s-1 min, corresponding to 51.8 nmoles of spin adduct released between 30 s and 1 min.     

Formation of aminoxyl radicals in the reaction between penicillins and hydrogen peroxide.

Aminoxyl radicals are formed in high yield in the reaction between penicillins and hydrogen peroxide in water solutions in the pH range between 7 and 8. The nine-line EPR spectrum, 3 x 3 (1:2:1), indicated an interaction of the unpaired electron with one 14N nucleus (aN = 1.44 mT) and two equivalent hydrogen nuclei (aH = 2.00 mT). The reaction involves an oxidative cleavage of the beta-lactam ring of the penicillins with the formation of a cyclic aminoxyl radical, in which the thiazolidine ring carries the nitroxide group (= N-O.). It is suggested that the reaction with the formation of aminoxyl radicals can also take place in vivo in the deactivation of penicillins by metabolically formed hydrogen peroxide.