Breath ethane as a marker of reactive oxygen species during manipulation of diet and oxygen tension in rats

Breath ethane, O2 consumption, and CO2 production were analyzed in 24-mo-old female Fischer 344 rats that had been fed continuously ad libitum (AL) or restricted 30% of AL level (DR) diets since 6 wk of age. Rats were placed in a glass chamber that was first flushed with air, then with a gas mixture containing 12% O2. After equilibration, a sample of the outflow was collected in gas sampling bags for subsequent analyses of ethane and CO2. The O2 and CO2 levels were also directly monitored in the outflow of the chamber. O2 consumption and CO2 production increased for DR rats. Hypoxia decreased O2 consumption and CO2 production for the AL-fed and DR rats. These changes reflect changes in metabolic rate due to diet and PO2. A significant decrease in ethane generation was found in DR rats compared with AL-fed rats. Under normoxic conditions, breath ethane decreased from 2.20 to 1.61 pmol ethane/ml CO2. During hypoxia the levels of ethane generation increased, resulting in a DR-associated decrease in ethane from 2.60 to 1.90 pmol ethane/ml CO2. These results support the hypothesis that DR reduces the level of oxidative stress.     

Importance of reactive oxygen species in rheumatoid arthritis

Free radical oxidation--peroxidation products, superoxide dismutase (SOD) activity--and nonproteic thiols were measured in blood from 10 normal subjects and 10 patients with rheumatoid arthritis (RA). Peroxidation products and SOD activity have been found significantly elevated, while blood nonproteic thiols have been found significantly lower in RA patients, as compared to normal controls. Also, plasmatic concentration of ceruloplasmin has been found significantly higher in RA patients than in controls.     

The role of reactive oxygen species in atherosclerosis

Reactive oxygen species (ROS) are probably not only unintended, toxic side-products of oxygen metabolism in mammalian cells, they also have several important physiologic functions including antimicrobial killing, regulation of cellular proliferation and growth, and regulation of vascular tone. ROS are generated within the vessel wall by several mechanisms, including a vascular type of a NAD(P)H oxidase. ROS formation can be stimulated by mechanical stress, environmental factors, the peptide angiotensin II, cytokines, native low-density lipoproteins (LDL), and in the presence of catalytic metal ions. Their ability to modify LDL, react with endothelial-derived nitric oxide subsequently forming peroxynitrite, and amplify the expression of various genes important for leukocyte recruitment within the arterial wall are the basis of the oxidant injury theory of atherosclerosis. In animal studies, antioxidant therapy (probucol, butylated hydroxytoluene, N', N'-diphenylenediamide, vitamin E, superoxide dismutase) have been successfully used to prevent fatty streak formation, and to restore impaired nitric oxide-dependent vasorelaxation. In man, antioxidant therapy (e.g., supplementation with vitamin E) clearly increased the resistance of LDL to oxidative modification. Case-controlled and prospective clinical studies suggest a relation between baseline antioxidant plasma levels and/or antioxidant supplementation and risk of cardiovascular events. In one secondary prevention trial (randomized, blinded, placebo-controlled), vitamin E supplementation reduced significantly the risk for non-fatal myocardial infarctions. Before general recommendations can be made, results of further large-scale trials should be awaited.     

Involvement of reactive oxygen species in kidney damage

There is considerable evidence suggesting that reactive oxygen species (ROS) are implicated in the pathogenesis of ischemic, toxic, and immunologically-mediated renal injury. In experimental renal ischemia, ROS sources include the electron transport chain, oxidant enzymes (xanthine oxidase), phagocytes, and auto-oxidation of epinephrine. ROS cause lipid peroxidation of cell and organelle membranes and, hence, disruption of the structural integrity and capacity for cell transport and energy production, especially in the proximal tubule segment. In experimental immune glomerulonephritis, ROS are generated by both infiltrating blood-borne cells (polymorphonuclear leukocytes and monocytes) and resident glomerular cells, mainly mesangial cells. Their formation results in morphologic lesions and in modifications of glomerular permeability to proteins through activation of proteases and reduction of proteoglycan synthesis. Additionally, they promote a reduction in glomerular blood flow and glomerular filtration rate through liberation of vasoconstrictory bioactive lipids (prostaglandins, thromboxane, and platelet activating factor) and, possibly, inactivation of relaxing nitric oxide. Further studies are needed to address the role of ROS in human glomerular diseases.     

Scavenging of reactive oxygen species by melatonin

Monocytes adherent to implanted biomaterials differentiate into macrophages while synthesizing large amounts of degradative enzymes, including cholesterol esterase (CE), which previously has been shown to degrade poly(urethane)s. Human peripheral blood monocytes were cultured on tissue culture grade polystyrene (PS), and two model poly(urethane)s were synthesized from (1) polycaprolactone (PCL) and (2) polytetramethylene oxide (PTMO), both with 2,4-toluene diisocyanate (TDI) and ethylene diamine (ED). The increase in CE and total protein per cell were measured on days 8 and 28 in culture and normalized to the DNA content per cell. At day 8 there consistently were fewer cells remaining on the PTMO-based polymer than on the PCL-based polymer or the PS (p < 0.05). When comparing day 28 to day 8, there was more CE activity and protein per cell on all materials. However, there was a disproportionate synthesis of CE per mg of total protein on PS and TDI/PCL/ED whereas on PTMO there was not. Significantly, there was more protein and CE per cell on PTMO than on PS or TDI/PCL/ED (p < 0.05). This in vitro model system of the chronic phase of inflammation has shown that it is possible to culture monocytes for a month and assess the material surface itself as a potent activator of the differentiation into macrophages without secondary stimulation. Since CE has been shown to degrade poly(ether and ester)-based poly(urethane)s, the differential production of this enzyme relative to the total protein on different surfaces may impact on the potential long-term biostability of an implanted material.     

UV-induced reactive oxygen species in photocarcinogenesis and photoaging

The increase in UV irradiation on earth due to the stratospheric ozone depletion represents a major environmental threat to the skin increasing its risk of photooxidative damage by UV-induced reactive oxygen species (ROS). Increased ROS load has been implicated in several pathological states including photoaging and photocarcinogenesis of the skin. Large efforts have been made to better define the involvement of distinct ROS in photocarcinogenesis and photoaging. Both pathological processes share common features; however, they reveal unique molecular characteristics which finally determine the fate of the cell and its host. As well as causing permanent genetic changes involving protooncogenes and tumor suppressor genes, ROS activate cytoplasmic signal transduction pathways that are related to growth differentiation, senescence, transformation and tissue degradation. This review focuses on the role of UV-induced ROS in the photodamage of the skin resulting in biochemical and clinical characteristics of photocarcinogenesis and photoaging. A decrease in the ROS load by efficient sunscreens and/or otherwise protective agents may represent a promising strategy to prevent or at least minimize ROS induced cutaneous pathological states.     

Space deformation as a separation mechanism of DNA double helix strands

Cortex cells of the root meristem of Cucurbita pepo (0.0-0.5 mm from the cap junction), in the 3-4, 5-6 and 7-8 mm segments above the root tip, and the cells of the first three layers of lateral part of root cap were the object of the present study. The volume of cortex cells increases more than 20 times in the 7-8 mm segment as compared with meristematic cells, and the volume of cytoplasm about sevenfold. The largest increment of the cytoplasmic volume occurs between 0.5-6.0 mm. In consecutive root segments the sustained increase of the volume of nuclei takes place. By applying autoradiography the following processess have been investigated: DNA synthesis (3H thymidine uptake), template activity of DNA (3H actinomycin D(3H AMD)-binding), RNA synthesis (3H uridine incorporation), and protein synthesis (3H leucine). In the root cap cells and in segments where meristematic activity is over, DNA is replicated by endomitosis. On the basis of nuclear labelling it appears that nuclei in the 3-4 mm segment reach 4C ploidy state, but in the 7-8 mm segment half of the nuclei reach the 8C ploidy state. Most of the root cap cells are 4C, the remaining cells are 8C. Considering the uptake of 3H thymidine into nucleoli one may suppose that in the root cap cells nucleolar DNA is underreplicated, and to a lesser degree in 5-6 and 7-8 mm segments, while in 3-4 mm segment DNA is overreplicated as compared to meristem cells. Measurements of nucleolar volume, 3H uridine uptake, 3H AMD binding and quantity of granular component, indicate that the most noticeable nucleolar activity takes place in meristematic zone and in root parts showing the highest increase of cytoplasmic volume (3-4 and 5-6 mm segments). 3H leucine is still incorporated intensely into 7-8 mm segment, in which the concentration of ribosomes is low, however they are present in the form of polysomes. Comparison of 3H thymidine uptake into nuclear DNA with 3H AMD binding and 3H uridine incorporation into nuclei indicates that endomitotic DNA replication results in an increase of DNA template activity in root cap cells as well as in 3-4 and 5-6 mm segments; in the 7-8 mm segment binding of 3H AMD slightly decreases, while 3H uridine incorporation is considerably reduced. Divergence between the ploidy state, 3H AMD binding and 3H uridine incorporation can be due to the increment of the condensed chromatin area in differentiated cells. Plastids and mitochondria reach full maturity in 3-4 mm segment. The increasing volume density of ER and diminishing volume density of Golgi structures is accompanied by differentiation of cortex cells.     

Molecular mechanisms of cellular injury produced by neurotoxic amino acids that generate reactive oxygen species

There is now strong experimental evidence that the basic precursors for the synthesis of catechol(amine) and indolamine neurotransmitters, tyrosine and tryptophan can act as generators of ROS (reactive oxygen species): peroxides, superoxide and peroxyradicals. The consequences of free radicals formation from precursors during oxidative degradation process, their possible participation in electron transfer/addition reactions and chain processes involving cell antioxidant defense system were presented and discussed. Although the generation of neurotoxic ROS by tyrosine and tryptophan is accepted to occur in the presented model systems, doubts can exist as to the situation in vivo, which may be completely different and remain to be explored. The relevance of the present findings with regard to a variety of neurological diseases cannot be ignored.     

Induction of reactive oxygen species in neurons by haloperidol

Haloperidol (HP) is widely prescribed for schizophrenia and other affective disorders but has severe side effects such as tardive dyskinesia. Because oxidative stress has been implicated in the clinical side effects of HP, rat primary cortical neurons and the mouse hippocampal cell line HT-22 were used to characterize the generation of reactive oxygen species (ROS) and other cellular alterations caused by HP. Primary neurons and HT-22 cells are equally sensitive to HP with an IC50 of 35 microM in the primary neurons and 45 microM in HT-22. HP induces a sixfold increase in levels of ROS, which are generated from mitochondria but not from the metabolism of catecholamines by monoamine oxidases. Glutathione (GSH) is an important antioxidant for the protection of cells against HP toxicity because (1) the intracellular GSH decreases as the ROS production increases, (2) the exogenous addition of antioxidants, such as beta-estradiol and vitamin E, lowers the level of ROS and protects HT-22 cells from HP, and (3) treatments that result in the reduction of the intracellular GSH potentiate HP toxicity. The GSH decrease is followed by the increase in the intracellular level of Ca2+, which immediately precedes cell death. Therefore, HP causes a sequence of cellular alterations that lead to cell death and the production of ROS is the integral part of this cascade.     

Mechanisms of bradykinin-induced cerebral vasodilatation in rats. Evidence that reactive oxygen species activate K+ channels

BACKGROUND AND PURPOSE: Relatively little is know regarding mechanisms by which reactive oxygen species produce dilatation of cerebral arterioles. The goal of this study was to test the hypothesis that vasodilator responses of cerebral arterioles to bradykinin, which produces endogenous generation of reactive oxygen species, involve activation of calcium-dependent potassium channels. METHODS: We used a cranial window in anesthetized rats to examine effects of catalase (which degrades hydrogen peroxide) on responses to bradykinin. In addition, we examined effects of tetraethylammonium (TEA) and iberiotoxin, inhibitors of calcium-dependent potassium channels, on responses of cerebral arterioles to hydrogen peroxide, bradykinin, and papaverine. RESULTS: In cerebral arterioles (baseline diameter = 40 +/- 1 microns) (mean +/- SE), hydrogen peroxide (10 and 100 mumol/L) produced concentration-dependent dilatation. TEA (1 mmol/L), an inhibitor of calcium-dependent potassium channels, produced marked inhibition of vasodilatation in response to hydrogen peroxide. For example, 100 mumol/L hydrogen peroxide dilated arterioles by 13 +/- 2% in the absence and 4 +/- 1% (P < .05 versus control) in the presence of TEA. Bradykinin (10 nmol/L to 1 mumol/L) also produced concentration-dependent dilatation of cerebral arterioles that was inhibited completely by catalase (100 U/mL). TEA or iberiotoxin markedly inhibited vasodilatation in response to bradykinin. For example, 100 nmol/L bradykinin dilated arterioles by 21 +/- 3% in the absence and 2 +/- 2% (P < .05 vs control) in the presence of iberiotoxin (50 nmol/L). CONCLUSIONS: These findings suggest that dilatation of cerebral arterioles in the rat in response to hydrogen peroxide, or hydrogen peroxide produced endogenously in response to bradykinin, is mediated by activation of calcium-dependent potassium channels. Thus, activation of potassium channels may be a major mechanism of dilatation in response to reactive oxygen species in the cerebral microcirculation.     

Cholinergic-induced production of reactive oxygen species in human neuroblastoma cells

Stimulation of human SH-SY5Y neuroblastoma cells by a muscarinic receptor agonist, carbachol (CCh; 1 mM), elevated levels of free intracellular calcium and subsequently increased the production of reactive oxygen species (ROS). Quinuclidinylbenzilate (QNB) binding increased at 1 h after CCh, but returned back to the control level at 3 h. Production of ROS increased, however, during the 3 h time period. CCh also increased the translocation of protein kinase C (PKC) to the membrane. ROS production was completely blocked by atropine and a PKC inhibitor, Ro 31-8220. These results show that increased ROS production was a result of muscarinic receptor stimulation, and that PKC had an active role in this cellular stimulation. ROS production upon cellular stimulation by CCh was completely inhibited also by superoxide dismutase, and partially by catalase, indicating that the formation of superoxide anion dominated in cholinergic-induced generation of ROS in human neuroblastoma cells. These results also show that muscarinic stimulation causes sustained ROS production in human neuroblastoma cells. The slow increase in ROS production by CCh suggest a stepwise cascade of events leading to oxidative stress with a triggering role of cholinergic muscarinic receptors in this process.     

Formation of reactive oxygen species following bioactivation of gentamicin

The present study investigated the ability of gentamicin to catalyze free radical reactions and probed the underlying mechanisms by hydroethidine imaging, oxygen consumption, and reduction of cytochrome c. In Epstein-Barr virus-transformed lymphoblastoid cells, a respiratory burst was induced by phorbol ester and detected by hydroethidine, a fluorescent indicator of superoxide radical. The addition of gentamicin increased the fluorescence two-fold while gentamicin did not produce fluorescence in the absence of phorbol ester. In membrane preparations, gentamicin did not enhance NADPH consumption ruling out a direct activation of NADPH oxidase. The formation of reactive oxygen species by gentamicin was additionally supported by experiments that showed gentamicin increased oxygen consumption two-fold in intact cells and a cell-free system. In addition, generation of superoxide was indicated by the gentamicin-stimulated reduction of cytochrome c. The stimulation by gentamicin depended upon the presence of iron (FeII/FeIII) and of arachidonic acid as an electron donor. These results support the hypothesis that an iron-gentamicin complex can increase reactive oxygen species in nonenzymatic and in biological systems. The requirement for a reductive activation in intact cells (e.g., by a respiratory burst) is interpreted as the conversion of an inactive FeIII-gentamicin to a redox-active FeII-gentamicin complex.     

Intracellular signaling by reactive oxygen species during hypoxia in cardiomyocytes

Cardiomyocytes suppress contraction and O2 consumption during hypoxia. Cytochrome oxidase undergoes a decrease in Vmax during hypoxia, which could alter mitochondrial redox and increase generation of reactive oxygen species (ROS). We therefore tested whether ROS generated by mitochondria act as second messengers in the signaling pathway linking the detection of O2 with the functional response. Contracting cardiomyocytes were superfused under controlled O2 conditions while fluorescence imaging of 2, 7-dichlorofluorescein (DCF) was used to assess ROS generation. Compared with normoxia (PO2 approximately 107 torr, 15% O2), graded increases in DCF fluorescence were seen during hypoxia, with responses at PO2 = 7 torr > 20 torr > 35 torr. The antioxidants 2-mercaptopropionyl glycine and 1,10-phenanthroline attenuated these increases and abolished the inhibition of contraction. Superfusion of normoxic cells with H2O2 (25 microM) for >60 min mimicked the effects of hypoxia by eliciting decreases in contraction that were reversible after washout of H2O2. To test the role of cytochrome oxidase, sodium azide (0.75-2 microM) was added during normoxia to reduce the Vmax of the enzyme. Azide produced graded increases in ROS signaling, accompanied by graded decreases in contraction that were reversible. These results demonstrate that mitochondria respond to graded hypoxia by increasing the generation of ROS and suggest that cytochrome oxidase may contribute to this O2 sensing.     

Relationship between the intracellular reactive oxygen species and the induction of oxidative DNA damage in human neutrophil-like cells

To clarify the mechanisms of intracellular induction of oxidative DNA damage, we have investigated the concentrations of intracellular reactive oxygen species and the amounts of 8-hydroxydeoxyguanosine (8OHdG), a mutagenic oxidative DNA damage, in human neutrophil-like cells, dimethylsulfoxide-differentiated HL60 (DMSO-HL60). We determined intracellular concentrations of hydrogen peroxide and superoxide by flow cytometry with dichlorofluorescein diacetate and hydroethidine, respectively. We determined the 8OHdG amounts with an electrochemical detector connected to HPLC after anaerobic sample processing. DMSO-HL60 releases superoxide upon stimulation with phorbol myristate acetate, and the released superoxide dismutates to hydrogen peroxide. Stimulation of DMSO-HL60 with 100 nM phorbol myristate acetate increased intracellular hydrogen peroxide, superoxide and 8OHdG (control). Addition of 1000 U/ml catalase decreased hydrogen peroxide (31.3% of control) and 8OHdG (20.3%). Addition of 100 U/ml SOD decreased superoxide (18.7%) and 8OHdG (41.6%). Addition of 1 mM deferoxamine decreased 8OHdG (30.4%), but increased hydrogen peroxide (129.6%). Addition of 200 microM 4-acetamido-4'- isothiocyanostilbene-2,2'-disulfonic acid decreased superoxide (59.9%) and 8OHdG (42.0%). Addition of 0.4% ethanol had no effect on superoxide concentration (102.2%), but tended to decrease hydrogen peroxide (83.5%) and 8OHdG (84.3%). Pretreatment of DMSO-HL60 with 0.1 mM FeSO4 increased 8OHdG (117.3%), but decreased hydrogen peroxide (75.8%). These findings indicate that the extracellularly released superoxide and hydrogen peroxide diffuse into the cell, but that such reactive oxygen species are not the direct molecules to induce 8OHdG. Our results suggest that 8OHdG is induced by the hydroxyl radical which is generated from intracellular hydrogen peroxide and superoxide-reduced Fe.     

Cobalt-mediated generation of reactive oxygen species and its possible mechanism

Electron spin resonance spin trapping was utilized to investigate free radical generation from cobalt (Co) mediated reactions using 5,5-dimethyl-1-pyrroline (DMPO) as a spin trap. A mixture of Co with water in the presence of DMPO generated 5,5-dimethylpyrroline-(2)-oxy(1) DMPOX, indicating the production of strong oxidants. Addition of superoxide dismutase (SOD) to the mixture produced hydroxyl radical (.OH). Catalase eliminated the generation of this radical and metal chelators, such as desferoxamine, diethylenetriaminepentaacetic acid or 1,10-phenanthroline, decreased it. Addition of Fe(II) resulted in a several fold increase in the .OH generation. UV and O2 consumption measurements showed that the reaction of Co with water consumed molecular oxygen and generated Co(II). Since reaction of Co(II) with H2O2 did not generate any significant amount of .OH radicals, a Co(I) mediated Fenton-like reaction [Co(I) + H2O2-->Co(II) + .OH + OH-] seems responsible for .OH generation. H2O2 is produced from O2.- via dismutation, O2.- is produced by one-electron reduction of molecular oxygen catalyzed by Co. Chelation of Co(II) by biological chelators, such as glutathione or beta-ananyl-3-methyl-L-histidine alters, its oxidation-reduction potential and makes Co(II) capable of generating .OH via a Co(II)-mediated Fenton-like reaction [Co(II) + H2O2-->Co(III) + .OH + OH-]. Thus, the reaction of Co with water, especially in the presence of biological chelators, glutathione, glycylglycylhistidine and beta-ananyl-3-methyl-L-histidine, is capable of generating a whole spectrum of reactive oxygen species, which may be responsible for Co-induced cell injury.     

Demyelination: the role of reactive oxygen and nitrogen species

This review summarises the role that reactive oxygen and nitrogen species play in demyelination, such as that occurring in the inflammatory demyelinating disorders multiple sclerosis and Guillain-Barré syndrome. The concentrations of reactive oxygen and nitrogen species (e.g. superoxide, nitric oxide and peroxynitrite) can increase dramatically under conditions such as inflammation, and this can overwhelm the inherent antioxidant defences within lesions. Such oxidative and/or nitrative stress can damage the lipids, proteins and nucleic acids of cells and mitochondria, potentially causing cell death. Oligodendrocytes are more sensitive to oxidative and nitrative stress in vitro than are astrocytes and microglia, seemingly due to a diminished capacity for antioxidant defence, and the presence of raised risk factors, including a high iron content. Oxidative and nitrative stress might therefore result in vivo in selective oligodendrocyte death, and thereby demyelination. The reactive species may also damage the myelin sheath, promoting its attack by macrophages. Damage can occur directly by lipid peroxidation, and indirectly by the activation of proteases and phospholipase A2. Evidence for the existence of oxidative and nitrative stress within inflammatory demyelinating lesions includes the presence of both lipid and protein peroxides, and nitrotyrosine (a marker for peroxynitrite formation). The neurological deficit resulting from experimental autoimmune demyelinating disease has generally been reduced by trial therapies intended to diminish the concentration of reactive oxygen species. However, therapies aimed at diminishing reactive nitrogen species have had a more variable outcome, sometimes exacerbating disease.     

Susceptibility of cloned K+ channels to reactive oxygen species

Free radical-induced oxidant stress has been implicated in a number of physiological and pathophysiological states including ischemia and reperfusion-induced dysrhythmia in the heart, apoptosis of T lymphocytes, phagocytosis, and neurodegeneration. We have studied the effects of oxidant stress on the native K+ channel from T lymphocytes and on K+ channels cloned from cardiac, brain, and T-lymphocyte cells and expressed in Xenopus oocytes. The activity of three Shaker K+ channels (Kv1.3, Kv1.4, and Kv1.5), one Shaw channel (Kv3.4), and one inward rectifier K+ channel (IRK3) was drastically inhibited by photoactivation of rose bengal, a classical generator of reactive oxygen species. Other channel types (such as Shaker K+ channel Kv1.2, Shab channels Kv2.1 and Kv2.2, Shal channel Kv4.1, inward rectifiers IRK1 and ROMK1, and hIsK) were completely resistant to this treatment. On the other hand tert-butyl hydroperoxide, another generator of reactive oxygen species, removed the fast inactivation processes of Kv1.4 and Kv3.4 but did not alter other channels. Xanthine/xanthine oxidase system had no effect on all channels studied. Thus, we show that different types of K+ channels are differently modified by reactive oxygen species, an observation that might be of importance in disease states.     

Aerobic glycolysis by proliferating cells: a protective strategy against reactive oxygen species

The effects of pentobarbital on electroencephalogram (EEG) and auditory brain-stem response (ABR) were evaluated in 13 Japanese white male rabbits, divided into two groups, 7 and 6, respectively. After baseline evoked responses were obtained, pentobarbital was infused intravenously at 60 mg/kg/h in both groups. EEGs and ABR were recorded with 15 min intervals. When the blood concentration of pentobarbital reached therapeutic levels (2.0-5.0 mg/dL), cortical and hippocampal EEGs became isoelectric. Although the appearance of ABR waves was significantly delayed, each wave was clearly observed in spite of isoelectric EEG levels. The rabbits in one group were killed at that time, and their brains were removed to determine the concentration of pentobarbital in the brain tissue. In another group, pentobarbital was additionally infused at the rate of 120 mg/kg/h. Although the waves (II-IV) of the ABR gradually disappeared with increasing dosage, wave I was present until just prior to cardiac arrest. It is considered that the persistency of ABR at high doses of barbiturates is characteristic of patients in deep barbiturate coma. Therefore, at the diagnosis of brain death, there is no necessity to consider the half-life of the barbiturate, even if an excessive amount of barbiturate remains in the brain. In this study, pentobarbital concentration in the brain was nearly equal to the concentration in the blood. However, it is estimated that a large amount of barbiturate is accumulated in the brain of a patient after brain death because the blood flow in the brain is stagnant.     

Mutagenicity of arsenic in mammalian cells: role of reactive oxygen species

Arsenite, the trivalent form of arsenic present in the environment, is a known human carcinogen that lacked mutagenic activity in bacterial and standard mammalian cell mutation assays. We show herein that when evaluated in an assay (AL cell assay), in which both intragenic and multilocus mutations are detectable, that arsenite is in fact a strong dose-dependent mutagen and that it induces mostly large deletion mutations. Cotreatment of cells with the oxygen radical scavenger dimethyl sulfoxide significantly reduces the mutagenicity of arsenite. Thus, the carcinogenicity of arsenite can be explained at least in part by it being a mutagen that depends on reactive oxygen species for its activity.