A unique, inexpensive, and abundantly available adsorbent: composite of synthesized silver nanoparticles (AgNPs) and banana leaves powder (BLP).

The purpose of this study is to investigate the development of a new and inexpensive adsorbent by immobilization synthesized silver nanoparticles (AgNPs) onto banana leaves powder (BLP), and the prepared composite (BLP)/(AgNPs) was used as an adsorbent for Zn(II), Pb(II), and Fe(III) ion removal from aqueous solutions under the influence of various reaction conditions. (BLP)/(AgNPs) demonstrated remarkable sensitivity toward Zn (II), Pb (II), and Fe (III) ions; metal ions eliminations increased with increasing contact time, agitation speed, adsorbent dose, and temperature, yielding adequate selectivity and ideal removal efficiency of 79%, 88%, and 91% for Zn (II), Pb (II), and Fe (III) ions, respectively, at pH = 5 for Zn(II) and pH = 6 for Pb(II), and Fe(III). The equilibrium contact time for elimination of Zn (II), Pb (II), and Fe (III) ions was reaches at 40 min. Langmuir, Freundlich, and Temkin equations were used to test the obtained experimental data. Langmuir isotherm model was found to be more accurate in representing the data of Zn(II), Pb(II), and Fe(III) ions adsorption onto (BLP)/(AgNPs), with a regression coefficient (R2 = 0.999) and maximum adsorption capacities of 190, 244, and 228 mg/g for Zn(II), Pb(II), and Fe(III) ions, respectively. The thermodynamic parameters proved that adsorption of metal ions is spontaneous, feasible, and endothermic, whereas Kinetic studies revealed that the process was best described by a pseudo second order kinetics.

Antioxidant mobilization in response to oxidative stress: a dynamic environmental-nutritional interaction.

In today's society, human activities and lifestyles generate numerous forms of environmental oxidative stress. Oxidative stress is defined as a process in which the balance between oxidants and antioxidants is shifted toward the oxidant side. This shift can lead to antioxidant depletion and potentially to biological damage if the body has an insufficient reserve to compensate for consumed antioxidants. This report focuses on the observation that oxidative stress resulting from inhalation of oxidant air pollutants mobilized vitamin E to the lung. A review of the literature showed that this mobilization is not limited to the lung; rather, a variety of situations in which oxidative stress occur can mobilize antioxidants. This antioxidant mobilization shows that a high antioxidant capacity in the body must be maintained for it to cope efficiently with environmental oxidative stress. Maintaining a high-antioxidant capacity in the body with the use of dietary supplementation was a convenient and acceptable method by test subjects, human or non-human. One mechanism that might explain the antioxidant mobilization is a dynamic interaction between environment and nutrition. In that mechanism, oxidative stress would alter certain bioactive molecules, followed by activation of signal transduction pathways that in turn would mobilize antioxidants to the target organ of the oxidant attack.

Diet restriction modulates lung response and survivability of rats exposed to ozone.

Ozone (O(3)) is a powerful oxidant component of photochemical smog polluting the air of urban cities. Exposure to low-level O(3) causes lung injury and increased morbidity of the sensitive segment of population, and exposure to high levels can be lethal to experimental animals. Injury from O(3) exposure is generally associated with free radical formation and oxidative stress. Because diet restriction is proposed to enhance antioxidant status, we examined whether it would influence the response to inhaled O(3). Twenty-four Sprague-Dawley rats, 1 month old, weighing 150 g, were divided into two dietary regimens (12 rats/regimen); one was freely-fed (FF), and the second was diet-restricted (DR) to 20% the average daily intake of the FF. After 60 days of dietary conditioning, the body weight of DR rats was reduced to 50% that of FF rats. Then, in one experiment, two groups (six rats/group), one FF and the other DR, were exposed to 0.8+/-0.1 p.p.m. (1570+/-196 microg/m(3)) O(3), continuously for 3 days. Another two similar groups of rats were exposed to filtered room air and served as matched controls. After exposure, all rats were euthanized and the lungs analyzed for biochemical markers of oxidative stress. In a second experiment, 24 rats were divided into two groups (12 rats/group), one FF and the other DR, then exposed to high-level O(3) for 8 h (4 p.p.m., 7848+/-981 microg/m(3)) and the mortality noted during exposure and for 16 h post-exposure. Following low-level O(3), inhalation, greater alterations were observed in FF rats compared with DR rats. With high-level O(3) exposure, DR rats exhibited a much greater survivability compared with FF rats (90% versus 8%, respectively). These observations suggest that diet restriction leading to significant reduction of body weight is beneficial, and may play a role in the resistance to the adverse effects of O(3).

Antioxidant loading reduces oxidative stress induced by high-energy impulse noise (blast) exposure.

Detonation of explosives, firing of large caliber weapons and occupational explosions, professional or accidental, produce high-energy impulse noise (blast) waves characterized by a rapid rise in atmospheric pressure (overpressure) followed by gradual decay to ambient level. Exposure to blast waves causes injury, predominantly to the hollow organs such as ears and lungs. We have previously reported that blast exposure can induce free radical-mediated oxidative stress in the lung characterized by antioxidant depletion, lipid peroxidation, and hemoglobin (Hb) oxidation. In this study, we examined whether pre-loading, adequately fed rats, with pharmacological doses of antioxidants would reduce the response to blast. Sprague-Dawley rats weighing 300-350 g were loaded with either 800 IU vitamin E (VE), 1000 mg vitamin C (VC) or 25 mg lipoic acid (LA) for 3 consecutive days by gavage before exposure to blast. Both VE, and LA were dissolved in 2 ml corn oil, but VC in 2 ml water. After the 3-day antioxidant loading, the rats were divided into six groups (five rats per group), deeply anesthetized with sodium pentobarbital (60 mg/kg body weight), then exposed to a low-level blast (62+/-2 kPa peak pressure and 5 ms duration). A matched number of groups were sham exposed and served as controls. One hour after exposure, all rats were euthanized then blood, and lung tissue was analyzed. We found that antioxidant loading resulted in restored Hb oxygenation, and reduced lipid peroxidation. Lung tissue VE content was elevated after loading but VC did not change possibly due to their different bioavailability and saturation kinetics. These observations, suggest that brief antioxidant loading with pharmacological doses can reduce blast-induced oxidative stress, and may have occupational and clinical implications.

Nitric oxide protects cardiomyocytes against tert-butyl hydroperoxide-induced formation of alkoxyl and peroxyl radicals and peroxidation of phosphatidylserine.

We studied protective effects of nitric oxide against tert-butyl hydroperoxide-induced oxidative damage to cardiac myocytes. Two distinct free radicals species--alkoxyl radicals associated with non-heme iron catalytic sites and myoglobin protein-centered peroxyl radicals--were found in low-temperature EPR spectra of cardiac myocytes exposed to t-BuOOH. The t-BuOOH-induced radical formation was accompanied by site-specific oxidative stress in membrane phospholipids (peroxidation of phosphatidylserine) assayed by fluorescence HPLC after metabolic labeling of cell phospholipids with oxidation-sensitive cis-parinaric acid. An NO-donor, (Z)-1-[N-(3-ammonio-propyl)-N-(n-propyl) amino]-diazen-1-ium-1,2-diolate], protected cardiac myocytes against tert-butyl hydroperoxide-induced: (i) formation of non-protein- and protein-centered free radical species and (ii) concomitant peroxidation of phosphatidylserine. Thus nitric oxide can act as an effective antioxidant in live cardiomyocytes.

Vitamin E and lipoic acid, but not vitamin C improve blood oxygenation after high-energy IMPULSE noise (BLAST) exposure.

Exposure to high energy impulse noise (BLAST) caused by explosions, result in structural and functional damage to the hollow organs, especially to the respiratory and auditory systems. Lung damage includes alveolar wall rupture, edema and hemorrhage, and may be fatal. Previous observations at the molecular level using the rat model, suggested that secondary free radical-mediated oxidative stress occurs post exposure resulting in antioxidant depletion and hemoglobin (Hb) oxidation. This study examined whether a short period of pre-exposure supplementation with antioxidants would protect Hb from the effects of BLAST exposure. Six groups of male Sprague-Dawley rats (8/group) were gavaged with 800 IU vitamin E (VE) in 2 ml corn oil, 1000 mg vitamin C (VC) in 2 ml distilled water or 25 mg or (-lipoic acid (LA) in 2 ml corn oil for 3 days. Matched control groups were gavaged with the respective vehicles. On day 4, rats were deeply anesthetized and exposed to a simulated BLAST wave with an average peak pressure of 62 +/- 2 kPa. Rats were euthanized one hour post exposure and blood samples were obtained by cardiac puncture and analyzed using a hemoximeter. Post exposure oxygenation states (HbO2, O2 saturation, and O2 content) were markedly decreased, while reduced-Hb was increased. Supplementation with VE and LA reversed the trend and increased Hb oxygenation, but VC did not. This suggests that a brief dietary loading with pharmacological doses of VE or LA, but not VC shortly before BLAST exposure may be beneficial. Moreover, measurement of blood oxygenation may function as a simple semi-invasive biomarker of BLAST-induced injury applicable to humans.

Toxicology of blast overpressure.

Blast overpressure (BOP) or high energy impulse noise, is the sharp instantaneous rise in ambient atmospheric pressure resulting from explosive detonation or firing of weapons. Blasts that were once confined to military and to a lesser extent, occupational settings, are becoming more universal as the civilian population is now increasingly at risk of exposure to BOP from terrorist bombings that are occurring worldwide with greater frequency. Exposure to incident BOP waves can cause auditory and non-auditory damage. The primary targets for BOP damage are the hollow organs, ear, lung and gastrointestinal tract. In addition, solid organs such as heart, spleen and brain can also be injured upon exposure. However, the lung is more sensitive to damage and its injury can lead to death. The pathophysiological responses, and mortality have been extensively studied, but little attention, was given to the biochemical manifestations, and molecular mechanism(s) of injury. The injury from BOP has been, generally, attributed to its external physical impact on the body causing internal mechanical damage. However, a new hypothesis has been proposed based on experiments conducted in the Department of Respiratory Research, Walter Reed Army Institute of Research, and later in the Department of Occupational Health, University of Pittsburgh. This hypothesis suggests that subtle biochemical changes namely, free radical-mediated oxidative stress occur and contribute to BOP-induced injury. Understanding the etiology of these changes may shed new light on the molecular mechanism(s) of injury, and can potentially offer new strategies for treatment. In this symposium. BOP research involving auditory, non-auditory, physiological, pathological, behavioral, and biochemical manifestations as well as predictive modeling and current treatment modalities of BOP-induced injury are discussed.

Visual system degeneration induced by blast overpressure.

The effect of blast overpressure on visual system pathology was studied in 14 male Sprague-Dawley rats weighing 360-432 g. Blast overpressure was simulated using a compressed-air driven shock tube, with the aim of studying a range of overpressures causing sublethal injury. Neither control (unexposed) rats nor rats exposed to 83 kiloPascals (kPa) overpressure showed evidence of visual system pathology. Neurological injury to brain visual pathways was observed in male rats surviving blast overpressure exposures of 104-110 kPa and 129-173 kPa. Optic nerve fiber degeneration was ipsilateral to the blast pressure wave. The optic chiasm contained small numbers of degenerated fibers. Optic tract fiber degeneration was present bilaterally, but was predominantly ipsilateral. Optic tract fiber degeneration was followed to nuclear groups at the level of the midbrain, midbrain-diencephalic junction, and the thalamus where degenerated fibers arborized among the neurons of: (i) the superior colliculus, (ii) pretectal region, and (iii) the lateral geniculate body. The superior colliculus contained fiber degeneration localized principally to two superficial layers (i) the stratum opticum (layer III) and (ii) stratum cinereum (layer II). The pretectal area contained degenerated fibers which were widespread in (i) the nucleus of the optic tract, (ii) olivary pretectal nucleus, (iii) anterior pretectal nucleus, and (iv) the posterior pretectal nucleus. Degenerated fibers in the lateral geniculate body were not universally distributed. They appeared to arborize among neurons of the dorsal and ventral nuclei: the ventral lateral geniculate nucleus (parvocellular and magnocellular parts); and the dorsal lateral geniculate nucleus. The axonopathy observed in the central visual pathways and nuclei of the rat brain are consistent with the presence of blast overpressure induced injury to the retina. The orbital cavities of the human skull contain frontally-directed eyeballs for binocular vision. Humans looking directly into an oncoming blast wave place both eyes at risk. With bilateral visual system injury, neurological deficits may include loss or impairments of ocular movements, and of the pupillary and accommodation reflexes, retinal hemorrhages, scotomas, and general blindness. These findings suggest that the retina should be investigated for the presence of traumatic or ischemic cellular injury, hemorrhages, scotomas, and retinal detachment.

A proposed biochemical mechanism involving hemoglobin for blast overpressure-induced injury.

Blast overpressure (BOP) is the abrupt, rapid, rise in atmospheric pressure resulting from explosive detonation, firing of large-caliber weapons, and accidental occupational explosions. Exposure to incident BOP waves causes internal injuries, mostly to the hollow organs, particularly the ears, lungs and gastrointestinal tract. BOP-induced injury used to be considered of military concern because it occurred mostly in military environments during military actions or training, and to a lesser extent during civilian occupational accidents. However, in recent years with the proliferation of indiscriminate terrorist bombings worldwide involving civilians, blast injury has become a societal concern, and the need to understand the biochemical and molecular mechanism(s) of injury, and to find new and effective methods for treatment gained importance. In general, past BOP research has focused on the physiological and pathological manifestations of incapacitation, thresholds of safety, and on predictive modeling. However, we have been studying the molecular mechanism of BOP-induced injury, and recently began to have an insight into that mechanism, and recognize the role of hemoglobin released during hemorrhage in catalyzing free radical reactions leading to oxidative stress. In this report we discuss the biochemical changes observed after BOP exposure in rat blood and lung tissue, and propose a biochemical mechanism for free radical-induced oxidative stress that can potentially complicate the injury. Moreover, we observed that some antioxidants can interact with Hb oxidation products (oxy-, met- and oxoferrylHb) and act as prooxidants that can increase the damage rather than decrease it.

Nitric oxide prevents oxidative damage produced by tert-butyl hydroperoxide in erythroleukemia cells via nitrosylation of heme and non-heme iron. Electron paramagnetic resonance evidence.

We studied protective effects of NO against tert-butylhydroperoxide (t-BuOOH)-induced oxidations in a subline of human erythroleukemia K562 cells with different intracellular hemoglobin (Hb) concentrations. t-BuOOH-induced formation of oxoferryl-Hb-derived free radical species in cells was demonstrated by low temperature EPR spectroscopy. Intensity of the signals was proportional to Hb concentrations and was correlated with cell viability. Peroxidation of phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine, phosphatidylinositol, and cardiolipin metabolically labeled with oxidation-sensitive cis-parinaric acid was induced by t-BuOOH. An NO donor, (Z)-1-[N-(3-ammoniopropyl)-N-(n-propyl)amino]-diazen-1-iu m-1, 2-diolate], produced non-heme iron dinitrosyl complexes and hexa- and pentacoordinated Hb-nitrosyl complexes in the cells. Nitrosylation of non-heme iron centers and Hb-heme protected against t-BuOOH-induced: (a) formation of oxoferryl-Hb-derived free radical species, (b) peroxidation of cis-parinaric acid-labeled phospholipids, and (c) cytotoxicity. Since NO did not inhibit peroxidation induced by an azo-initiator of peroxyl radicals, 2, 2'-azobis(2,4-dimethylvaleronitrile), protective effects of NO were due to formation of iron-nitrosyl complexes whose redox interactions with t-BuOOH prevented generation of oxoferryl-Hb-derived free radical species.

Air blast-induced pulmonary oxidative stress: interplay among hemoglobin, antioxidants, and lipid peroxidation.

Blast overpressure (BOP) is a phenomenon that describes the instantaneous rise in atmospheric pressure above ambient, resulting from the firing of large caliber weapons or from military or civilian explosions. Exposure to BOP results in injury to the gas-filled organs, such as the lungs, which exhibit a contusion-type injury. We examined the effects of BOP in rats at 5 and 60 min after exposure to a low-level BOP (62 +/- 3 kPa). The exposure was found to cause oxidative stress in the lung that was characterized by 1) a 3.5-fold decrease in total antioxidant reserves, 2) a depletion of the major water-soluble antioxidants ascorbate and glutathione (GSH) by 50 and 75%, respectively, 3) a depletion of lipid-soluble antioxidant vitamin E by 30%, 4) a 2.5-fold increase of fluorescent end products of lipid peroxidation, and 5) an increased methemoglobin (metHb) content at 60 min after exposure. To elucidate the role of released hemoglobin (Hb) in blast-induced oxidative stress, we studied the interactions of oxyhemoglobin (oxyHb), metHb, and the oxoferryl from of Hb free radical species with two physiologically important reductants, ascorbate and GSH. We found that both ascorbate and GSH were able to convert oxyHb to metHb in a reaction that yielded the one-electron oxidation intermediates semidehydroascorbyl radical and glutathionyl radical, respectively. This reaction did not occur under anaerobic conditions, suggesting that oxyHb-bound O2 acted as the electron acceptor. OxyHb induced peroxidation of cis-parinaric acid in the presence but not absence of ascorbate or GSH. Thus the prooxidant action of water-soluble antioxidants via redox cycling of oxyHb and metHb may promote oxidative stress rather than prevent it.

Nitric oxide/carbon monoxide. A molecular switch for myocardial preservation during ischemia.

BACKGROUND: In heart, NO is produced from L-arginine catalyzed by NO synthase, and CO is formed during the conversion of bilirubin from heme by the action of heme oxygenase. NO, which exerts its biological actions through cGMP and heme, has recently been implicated in myocardial protection during ischemia and reperfusion. We hypothesized that the intracellular signaling by NO may be modulated by heme oxygenase. METHODS AND RESULTS: To test this hypothesis, isolated rat hearts were perfused for 10 minutes with one of the following: (1) buffer alone; (2) 3 mmol/L L-arginine, a precursor for NO; (3) 650 mumol/L zinc protoporphyrin, a heme oxygenase inhibitor; (4) 3 mmol/L L-arginine plus 650 mumol/L zinc protoporphyrin; (5) 15 mumol/L methylene blue, a cGMP inhibitor; or (6) 3 mmol/L L-arginine plus 15 mumol/L methylene blue. Hearts were then made ischemic for 30 minutes, followed by 30 minutes of reperfusion. L-Arginine afforded significant myocardial protection, as evidenced by increased developed pressure (DP) (53.3 +/- 4.3 versus 35.4 +/- 1.8 for control), dP/dtmax (2405 +/- 125 versus 1758 +/- 117 for control), aortic flow (23 +/- 1.5 versus 9.4 +/- 1.6 for control), and coronary flow (CF) (23.0 +/- 0.8 versus 19.0 +/- 1.6 for control) at the end of reperfusion. Protoporphyrin tended to reduce these values compared with L-arginine alone (DP, 27.5 +/- 1.4; dP/dtmax, 1400 +/- 78; CF, 17 +/- 0.5), suggesting a contribution of heme oxygenase in addition to NO for myocardial preservation. Increased mRNAs for the heme oxygenase were noticed in the ischemic reperfused myocardium. Contents of cGMP, the second messenger for NO signaling, increased in the L-arginine group (1.6 +/- 0.1 versus 1.1 +/- 0.1 for control) and were reduced by protoporphyrin. cGMP was completely inhibited by methylene blue, which also retarded postischemic myocardial functional recovery. Malonaldehyde formation, a presumptive marker for free radical generation, was decreased in the L-arginine group (0.053 +/- 0.003) compared with control (0.089 +/- 0.005) but was increased in the protoporphyrin group (0.09 +/- 0.003) compared with the L-arginine group. In vitro studies demonstrated that NO was able to reduce the reactive oxygen species produced by myoglobin, especially oxoferrylmyoglobin, which either are present in heart or are formed in high concentrations during the reperfusion of ischemic myocardium. CONCLUSIONS: The results suggest that NO contributes to myocardial preservation by both cGMP-dependent and cGMP-independent mechanisms, the former being modulated by CO signaling and the latter by virtue of its antioxidant action.

Antioxidant depletion, lipid peroxidation, and impairment of calcium transport induced by air-blast overpressure in rat lungs.

Exposure to blast overpressure, or the sudden rise in atmospheric pressure after explosive detonation, results in damage mainly of the gas-filled organs. In addition to the physical damage, in the lung, injury may proceed via a hemorrhage-dependent mechanism initiating oxidative stress and accumulation of lipid peroxidation products. Massive rupture of capillaries and red blood cells, release of hemoglobin, its oxidation to met-hemoglobin and degradation sets the stage for heme-catalyzed oxidations. The authors hypothesized that lipid hydroperoxides interact with met-hemoglobin in the lungs of exposed animals to produce ferryl-hemoglobin, an extremely potent oxidant that induces oxidative damage by depleting antioxidants and initiating peroxidation reactions. Oxidation-induced disturbance of Ca2+ homeostasis facilitates further amplification of the damage. To test this hypothesis, groups of anesthetized rats (6 rats/group) were exposed to blast at 3 peak pressures: low (61.2 kPa), medium (95.2 kPa), high (136 kPa). One group served as an unexposed control. Immediately after exposure, the rats were euthanized and the lungs were analyzed for biochemical parameters. Blast overpressure caused: (1) depletion of total and water-soluble pulmonary antioxidant reserves and individual antioxidants (ascorbate, vitamin E, GSH), (2) accumulation of lipid peroxidation products (conjugated dienes, TBARS), and (3) inhibition of ATP-dependent Ca2+ transport. The magnitude of these changes in the lungs was proportional to the peak blast overpressure. Inhibition of Ca2+ transport strongly correlated with both depletion of antioxidants and enhancement of lipid peroxidation. In model experiments, met-hemoglobin/H2O2 produced damage to Ca2+ transport in the lungs from control animals similar to that observed in the lungs from blast overpressure-exposed animals. Ascorbate, which is known to reduce ferryl-hemoglobin, protected against met-hemoglobin/H2O2-induced damage of Ca2+ transport. If ferryl-hemoglobin is the major reactive oxygen species released by hemorrhage, then its specific reductants (e.g., nitric oxide) along with other antioxidants may be beneficial protectants against pulmonary barotrauma.

NO-redox paradox: direct oxidation of alpha-tocopherol and alpha-tocopherol-mediated oxidation of ascorbate.

Nitric-oxide (NO) can act as both a pro- or an antioxidant, yielding either cytotoxic or protective effects, respectively. The previously unrecognized redox interactions of NO with antioxidants, and not solely its well-known reactions with oxygen radicals, peroxyl radicals and transition metal centers, may be essential for its dual mechanisms in cells. Since the alpha-tocopherol/ascorbate redox cycle is central to antioxidant protection, we studied the direct effects of NO on alpha-tocopherol, ascorbate and combinations thereof in aqueous, micellar environments using ESR spectral and HPLC quantitative techniques. We found that NO does not directly oxidize ascorbate under anaerobic conditions. alpha-Tocopherol, however, in the presence of NO and under anaerobic conditions, was oxidized to the alpha-tocopheroxyl radical. Under conditions where NO oxidized alpha-tocopherol, the subsequent production of the alpha-tocopheroxyl radical depleted ascorbate, yielding the semidehydroascorbyl radical and regenerating alpha-tocopherol. Thus, NO interacts with the redox cycle involving alpha-tocopherol and ascorbate in a pro-oxidant manner.

Reduction of ferrylmyoglobin and ferrylhemoglobin by nitric oxide: a protective mechanism against ferryl hemoprotein-induced oxidations.

The reactions of metmyoglobin (metMb) and methemoglobin (metHb), oxidized to their respective oxoferryl free radical species (.Mb-FeIV = O/.Hb-4FeIV = O) by tert-butyl hydroperoxide (t-BuOOH), with nitric oxide (NO.) were studied by a combination of optical, electron spin resonance (ESR), ionspray mass (MS), fluorescence, and chemiluminescence spectrometries to gain insight into the mechanism by which NO. protects against oxidative injury produced by .Mb-FeIV = O/.Hb-4FeIV = O. Oxidation of metMb/metHb by t-BuOOH in a nitrogen atmosphere proceeded via the formation of two protein electrophilic centers, which were heme oxoferryl and the apoprotein radical centered at tyrosine (for the .Mb-FeIV = O form, the g value was calculated to be 2.0057), and was accompanied by the formation of t-BuOOH-derived tert-butyl(per)oxyl radicals. We hypothesized that NO. may reduce both oxoferryl and apoprotein free radical electrophilic centers of .Mb-FeIV = O/.Hb-4FeIV = O and eliminate tert-butyl(per)oxyl radicals, thus protecting against oxidative damage. We found that NO. reduced .Mb-FeIV = O/.Hb-4FeIV = O to their respective ferric (met) forms and prevented the following: (i) oxidation of cis-parinaric acid (PnA) in liposomes, (ii) oxidation of luminol, and (iii) formation of the tert-butyl(per)oxyl adduct with the spin trap DMPO. NO. eliminated the signals of tyrosyl radical detected by ESR and oxoferryl detected by MS in the reaction of t-BuOOH with metMb. As evidenced by MS of apomyoglobin, this effect was due to the two-electron reduction of .Mb-FeIV = O by NO. at the oxoferryl center rather than to nitrosylation of the tyrosine residues. Results of our in vitro experiments suggest that NO. exhibits a potent, targetable antioxidant effect against oxidative damage produced by oxoferryl Mb/Hb.

Toxicity of nitrogen dioxide: an introduction.

Many questions, needed to advance our understanding of the mechanism of injury from high-level NO2, remain unanswered to date. This is partly due to the limited interest in the toxicity of high-level exposures, and partly due to the public pressure and interest to study the effects of low- (environmental) levels. However, the effects of exposure to high-level NO2 are of great interest to the military since high levels of NO2 may be found in combat situations. It is also important to the civilian section in occupational settings where accidents may occur as in silo filler accidents. To fill this gap in knowledge, the Department of Respiratory Research, Division of Medicine at Walter Reed Army Institute of Research took the initiative and convened a panel of experts in a symposium to discuss in depth the effects of exposure to high-level nitrogen dioxide. The symposium goals were to address the issues beginning from the chemistry of NO2 molecule, to the dosimetry of its uptake (isolated lung), to the biological effects of exposure in vivo in small animals (rats), large animals (sheep), and finally in the most relevant species, humans.

Measurement of uric acid as a marker of oxygen tension in the lung.

Changes in O2 tension such as those associated with hypoxic ischemia or hyperoxia may potentially modulate purine nucleotide turnover and production of associated catabolites. We used an isolated perfused rat lung preparation to evaluate the effect of O2 tension on pulmonary uric acid production. Three O2 concentrations (21%, normoxia; 95%, hyperoxia; 0%, hypoxia) were utilized for both pulmonary ventilation and equilibration of recirculating perfusate. All gas mixtures contained 5% CO2 and were balanced with N2. We used Certified Virus Free Sprague-Dawley male rats weighting 250-300 g, four to five rats in each exposure regimen. After a 10-min equilibration period, we measured uric acid levels at 0 and 60 min in lung perfusate and at 60 min in lung tissue. After 60 min of ventilation/perfusion, we observed significant uric acid accumulation in both lung tissue (25-60%) and perfusate (8- to 10-fold) for all three O2 regimens. However, hypoxia produced substantially greater net uric acid concentrations (net = the difference between zero and 60 min) than either normoxia or hyperoxia (1.5-fold in lung tissue, and 2-fold in perfusate, respectively). The data suggest that pulmonary hypoxia results in greater purine catabolism leading to increased uric acid production. Vascular space uric acid, as measured in the recirculating perfusate, was proportional to lung weight changes (r = 0.99) with hypoxia exhibiting the greatest values, possibly reflecting a linkage between tissue perturbation and uric acid release. Thus, measurement of uric acid may serve as a useful marker of adenine nucleotide turnover and lung injury.