Rapid on-site dual optical system to measure specific reactive oxygen species (O2-• and OCl-) in a tiny droplet of whole blood.

Oxidative stress has been implicated in various disorders and controlling it would be important for healthy life. We have developed a new optical system for easily and accurately measuring oxidative stress in whole blood. It is optimized for simultaneously detecting reactive oxygen species (ROS) and highly reactive ROS (hROS), elicited mostly by white blood cells in a few microliters of blood. Results obtained by using this system show at least four important findings. 1) chemiluminescence of MCLA was confirmed to be attributable to O2-•. 2) PMA-stimulated cells released O2-• longer and more slowly than fMLP-stimulated ones. 3) fluorescence produced by APF oxidation was confirmed to be attributable to hROS, mostly OCl-, produced by myeloperoxidase. 4) the generation of OCl- was found to be a slower process than the O2-• generation. We also conducted pilot studies of oxidative stress in healthy volunteers.

Isomer distribution of hydroxyoctadecadienoates (HODE) and hydroxyeicosatetraenoates (HETE) produced in the plasma oxidation mediated by peroxyl radical, peroxynitrite, hypochlorite, 15-lipoxygenase, and singlet oxygen.

Free and ester forms of unsaturated fatty acids and cholesterol are oxidized in vivo by multiple oxidants to give diverse products. Some lipid oxidation is mediated by enzymes to selectively give specific products, while others proceed randomly to produce mixtures of many kinds of regioisomers and stereoisomers. The efficacy of antioxidants against lipid oxidation depends on the nature of the oxidants and therefore the identification of oxidant is important for understanding the roles and effects of lipid oxidation and antioxidants in vivo. In the present study, the isomer distribution of hydro(pero)xyoctadecadienoates (H(p)ODEs) and hydro(pero)xyeicosatetraenoates (H(p)ETEs), the most abundant lipid oxidation products found in human plasma, produced in the oxidation of plasma by peroxyl radicals, peroxynitrite, hypochlorite, 15-lipoxygenase, and singlet oxygen were examined. It was shown that 9- and 13-(E,E)-HODEs, 13(S)-(Z,E)-HODE, and 10- and 12-(Z,E)-HODEs were specific lipid oxidation products by free radical, 15-lipoxygenase, and singlet oxygen, respectively. The isomer distribution of HODEs produced by peroxynitrite was similar to that by peroxyl radical, suggesting that the peroxynitrite mediated lipid oxidation proceeds by free radical mechanisms. The production of HODEs and HETEs by hypochlorite was very small. HODEs may be a better biomarker than HETEs since linoleates are oxidized by simpler mechanisms than arachidonates and all the HODEs isomers can be quantified more easily. These products may be used as specific biomarkers for the identification of responsible oxidants and for the assessment of oxidant-specific lipid oxidation levels and effects of antioxidants in vivo.

Real-Time Monitoring of Singlet Oxygen and Oxygen Partial Pressure During the Deep Photodynamic Therapy In Vitro.

Photodynamic therapy (PDT) is an effective noninvasive method for the tumor treatment. The major challenge in current PDT research is how to quantitatively evaluate therapy effects. To our best knowledge, this is the first time to combine multi-parameter detection methods in PDT. More specifically, we have developed a set of system, including the high-sensitivity measurement of singlet oxygen, oxygen partial pressure and fluorescence image. In this paper, the detection ability of the system was validated by the different concentrations of carbon quantum dots. Moreover, the correlation between singlet oxygen and oxygen partial pressure with laser irradiation was observed. Then, the system could detect the signal up to 0.5 cm tissue depth with 660 nm irradiation and 1 cm tissue depth with 980 nm irradiation by using up-conversion nanoparticles during PDT in vitro. Furthermore, we obtained the relationship among concentration of singlet oxygen, oxygen partial pressure and tumor cell viability under certain conditions. The results indicate that the multi-parameter detection system is a promising asset to evaluate the deep tumor therapy during PDT. Moreover, the system might be potentially used for the further study in biology and molecular imaging.

Rapid assessment of singlet oxygen-induced plasma lipid oxidation and its inhibition by antioxidants with diphenyl-1-pyrenylphosphine (DPPP).

Recent studies suggesting the involvement of singlet oxygen in the pathogenesis of multiple diseases have attracted renewed attention to lipid oxidation mediated by singlet oxygen. Although the rate constants for singlet oxygen quenching by antioxidants have been measured extensively, the inhibition of lipid oxidation mediated by singlet oxygen has received relatively less attention, partly because a convenient method for measuring the rate of lipid oxidation is not available. The objective of this study was to develop a convenient method to measure plasma lipid oxidation mediated by singlet oxygen which may be applied to a rapid assessment of the antioxidant capacity to inhibit this oxidation using a conventional microplate reader. Singlet oxygen was produced from naphthalene endoperoxide, and lipid hydroperoxide production was followed by using diphenyl-1-pyrenylphosphine (DPPP). Non-fluorescent DPPP reacts stoichiometrically with lipid hydroperoxides to give highly fluorescent DPPP oxide. It was found that plasma oxidation by singlet oxygen increased the fluorescence intensity of DPPP oxide, which was suppressed by antioxidants. Fucoxanthin suppressed the oxidation more efficiently than ß-carotene and α-tocopherol, while ascorbic acid and Trolox were not effective. The present method may be useful for monitoring lipid oxidation and also for rapid screening of the capacity of dietary antioxidants and natural products to inhibit lipid oxidation in a biologically relevant system.

Secondary reactive oxygen species production after PDT during pulmonary tumor growth in sera of nude mice.

Photodynamic therapy (PDT), mediated by a sensitizer exposed to light to produce singlet oxygen ((1)O2), induces tumor responses varying from one person to another. Cancer growth induces oxidative stress at any step of its development from induction to treatment, which could also modify response to PDT. After the initial amount of (1)O2 delivered, secondary oxidative species (SOS) are also generated inducing additional damages. Using an in vitro assay we saw variations among mice strains concerning their serum capability to generate SOS after (1)O2 production. Nude mice had a higher capability to generate SOS as compared to the non mutated strain. Capability to generate SOS evolved during growth of orthotopically-grafted pulmonary cancers (A549), with either values corrected for hemolysis or not. Immediately after graft SOS production decreased, then increased again, reaching a plateau phase after 10 days which lasted for 20 days and finally increased steeply during the last phase of tumor growth, preceding cachexia and death. This profile differed profoundly from the one observed after heterotopic tumor grafts for which hemolysis induced artifacts masking important variations in SOS production. Our results demonstrate experimentally a relationship between the general health status of an individual, cancer progression and serum capability to generate SOS during PDT. These findings could explain some PDT failures as well as some unexpected successes on large tumors and should be taken into account when determining treatment parameters. They may also explain why different effects are observed on different experimental models with similar sensitizers.

Activation level of JNK and Akt/ERK signaling pathways determinates extent of DNA damage in the liver of diabetic rats.

AIMS: Diabetes-related oxidative stress conditions lead to progressive tissue damage and disfunctionality. Mechanisms underlying liver pathophysiology during diabetes are not fully understood. The aim of this study was to find relationship between diabetes-related DNA damage in the rat liver and activities of prosurvival signaling pathways. METHODS: Effect of diabetes was analyzed two (development stage) and eight weeks (stable diabetes) after single intraperitoneal injection of streptozotocin. Extent of DNA damage, analysed by comet assay, was corelated with oxidative status (plasma level of ROS, liver antioxidant capacity) and activity/abundance of kinases (Akt, p38, ERK1, JNK, JAK) and transcription factors NF-κB p65 and STAT3. RESULTS: Significant DNA damage in development stage is accompanied by elevated plasma levels of O(2)(-) and H(2)O(2), decreased activities of CAT, MnSOD, and GST in the liver and increased activation of proapoptotic JNK signal pathway. Lower DNA damage in stable diabetes, is accompanied by elevated plasma level of O(2)(-), restored antioxidative liver enzyme activity, decreased activation of JNK and increased activation of prosurvival Akt and ERK signal pathways. CONCLUSION: These findings indicate that level of DNA damage in diabetic liver depends on the extent of oxidative stress, antioxidant activity and balance between JNK and Akt/ERK signal pathways activation .

Increased singlet oxygen-induced secondary ROS production in the serum of cancer patients.

Photodynamic therapy (PDT) generates singlet oxygen ((1)O(2)) and Reactive Oxygen Species (ROS) that are counteracted by patient's defenses. As cancer treatments are among the most important PDT applications the aim of this pilot study was to determine whether the serum of cancer patients produces more or less secondary ROS or peroxides after a photoreaction as compared to healthy persons. Fifty-three volunteers and 105 cancer patients were recruited. The capacity of (1)O(2) or secondary oxidant production was found to be increased in 6 healthy donors and 36 cancer patients (23/69 women and 13/31 men p<0.007 and p<0.04) with a mean value of 1.52 as compared to 1.29 in the healthy subjects (p<0.05) when considering values higher than the normal range (norm=1±10%) or 1.1 vs. 0.85 (p<0.01) in the whole cohort. This increase correlated with a poor prognosis, TNM and SBR classification. Serum (1)O(2) deactivation capacity was impaired and secondary ROS were more produced during cancer progression. Although it is currently unclear whether this is the cause or effect of cancer, this finding may hold interest as a potential marker of cancer severity. It would also support the interest of PDT as an adjuvant for cancer treatment, even for aggressive tumors particularly when associated to surgery for bulk removal.

Serum resistance to singlet oxygen in patients with diabetes mellitus in comparison to healthy donors.

Diabetes mellitus causes endothelial injury through oxidative stress involving reactive oxygen species and peroxides as well as inflammation, both of which consume antioxidant defenses. Singlet oxygen ((1)O(2)) is produced by leukocytes during inflammatory and biochemical reactions and deactivated by producing reactive oxygen species and peroxides. To determine whether serum was capable of deactivating (1)O(2), we triggered a photo reaction in sera from 53 healthy donors and 52 diabetic patients. Immediately after light delivery, dichlorofluorescein was added and then its fluorescence was recorded. The mean capacity of (1)O(2) or secondary oxidant deactivation was reduced in patients with diabetes mellitus. Hemolysis reduced deactivation of (1)O(2)-induced secondary oxidants in both healthy and diabetic patients. Body mass index, age, platelet counts, and blood cell numbers exerted a nonlinear influence. High levels of glycated hemoglobin were associated with an increased deactivation of oxidative species, whereas high-density lipoprotein cholesterol, total cholesterol, and the total cholesterol to high-density lipoprotein cholesterol ratio decreased the serum deactivation capacity. Oral antidiabetics bore no influence on deactivation, which was restored by insulin in women. Deactivation capacity was lower in women, who had half the complications found in men, suggesting that, with more severe diabetes mellitus, protection was maintained against complications. Resistance to (1)O(2) should be considered during the monitoring of diabetes mellitus.

Hidroperóxidos de lipídios como fontes de oxigênio molecular singlete (O2 [1 DELTA g]), detecção e danos em biomoléculas / Lipid hidroperoxides as singlet molecular oxygen precursors (O2 [1 DELTA g]), detection and damage to biomolecules

O estudo do processo da peroxidação de lipídios tem aumentado nos últimos anos, principalmente devido à implicação dos hidroperóxidos de lipídios (LOOH) em diversos processos patológicos. A decomposição destes LOOH é capaz de gerar subprodutos capazes de promover danos em biomoléculas, incluindo proteínas e DNA. No presente trabalho, utilizando hidroperóxidos de ácido linoléico isotopicamente marcado com átomo de oxigênio-18 (LA18O18OH), fomos capazes de demonstrar que estas moléculas gerararam oxigênio singlete marcado [18(1O2)] em células em cultura. A detecção de tal espécie foi possível através da utilização de uma nova metodologia utilizando um derivado antracenico. Para este propósito foi utilizado o derivado de antraceno 3,3'-(9,10-antracenodiil) bisacrilato (DADB), cujo produto especifico da reação com o 1O2 (o endoperóxido do DADB DADBO2) do pode ser facilmente detectado por HPLC-MS/MS. De forma a expandir a compreensão dos efeitos tóxicos desses LOOH, investigamos o efeito destes compostos gerados intracelularmente. Para tal, foi utilizado o Rosa bengala (RB), um fotosensibilizador que tem afinidade por espaços apolares como membranas e lisossomos. A fotosenssibilização deste composto foi capaz de induzir a morte celular, e esta morte estaria relacionada a uma maior formação de 1O2 e a um maior acumulo de peróxidos. Nestes estudos foi possível demonstrar que carotenóides e sistemas antioxidantes dependentes de glutationa foram capazes de proteger contra os efeitos tóxicos da fotosensibilização na presença de RB. Adicionalmente foram avaliados os efeitos da hemoglobina (Hb) e do hidroperóxido do ácido linoléico (LAOOH) em uma série de parâmetros toxicológicos, como citotoxicidade, estado redox, a peroxidação lipídica e dano ao DNA. Nós demonstramos que a pré-incubação das células com Hb e sua posterior exposição à LAOOH (Hb + LAOOH) levou a um aumento na morte celular, a oxidação do DCFH, formação de malonaldeído e fragmentação do DNA e que esses...

The study of the process of lipid peroxidation has increased in recent years, mainly due to the involvement of lipid hydroperoxide (LOOH) in a series of pathological processes. The decomposition of LOOH is able to generate products that can promote damage to biomolecules, including proteins and DNA. In the present work, using linoleic acid hydroperoxide isotopically labeled with 18O2 (LA18O18OH), we demonstrate that these molecules were able to generate labeled singlet oxygen [18(1O2)] in cultured cells. The detection of such species was possible using a new methodology using an anthracene derivative .For this purpose we used the anthracene derivative of 3,3'-(9,10-antracendiil) bisacrilate (DADB), whose specific reaction product with 1O2 (DADB endoperoxide DADBO2) can be easily detected by HPLC-MS/MS. In order to expand the understanding of the toxic effects of LOOH, we investigated the effect of these compounds generated intracellularly. For this porpoise, we used Rose Bengal (RB), a photosensitizer that has affinity for apolar spaces such as membranes and lysosomes. The photosensitization of this compound was able to induce cell death, and this death was related to increased formation of 1O2 and a higher accumulation of peroxides. In these studies we have shown that carotenoids and glutathione-dependent antioxidant systems were capable of protecting against the toxic effects of photosensitization in the presence of RB. Additionally, we evaluated the effects of hemoglobin (Hb) and linoleic acid hydroperoxide (LAOOH) in a series of toxicological endpoints such as cytotoxicity, redox status, lipid peroxidation and DNA damage. We demonstrated that preincubation of cells with Hb and its subsequent exposure to LAOOH (Hb + LAOOH) led to an increase in cell death, DCFH oxidation, formation of malonaldehyde and DNA fragmentation, and that these effects were related to the peroxide and the heme group. It was demonstrated that cells incubated with LAOOH and Hb showed...

Detection of singlet oxygen in blood serum samples of clinically healthy lambs and lambs suffering from alveld disease.

Alveld is a disease in lambs of domestic sheep (Ovis aries L.), characterized by a combination of photosensitivity and liver damage. Generation of singlet oxygen play a major role in phototoxicity reactions. The compound phylloerythrin (phytoporphyrin) is so far assumed to be the main photodynamic agent in hepatogenous photosensitivity diseases in sheep. Phylloerythrin is a potent photosensitizer and an efficient source of singlet oxygen. The compound accumulates in the peripheral circualtion upon liver damage. Liver dysfunction is also likely to cause an increase in the blood level of bilirubin. Formation of singlet oxygen by bilirubin is reported. In the present work the photosensitizing potential of serum has been measured and related to the bilirubin- and phylloerythrin levels in lambs suffering from alveld and in clinically healthy controls. The singlet oxygen level of the serum was taken as a measure of the photosensitizing potential. The observed singlet oxygen values in serum from alveld lambs were significantly higher than the corresponding values observed in clinically healthy control lambs. This indicates that the serum of the alveld lambs contains an elevated concentration of photosensitizer. The singlet oxygen level was not correlated to the concentration of bilirubin or phylloerythrin. The results indicate that the photosensitizing mechanism is quite complex and may involve other sensitizer(s) than phylloerythrin.

[Nitric oxide system in blood of newborn infants at elevated risk of perinatal pathology].

The study was designed to evaluate activity of the blood nitric oxide (NO) system in newborns at high risk of perinatal pathology. The observed rise in NO production should be regarded as a compensatory and adaptive reaction facilitating the maintenance of microcirculation and hemodynamics in organs and their systems of newborn infants. The inter-relation and inter-dependence between NO levels and enzymatic activities (NOS, HP, O2-, ONOO-, and SOD) make up an integral pathogenetic mechanism determining severity and progress of affection of vitally important organs and systems as well as associated clinical symptoms in full-term and premature infants at high perinatal risk.

Secondary oxidants in human serum exposed to singlet oxygen: the influence of hemolysis.

Singlet oxygen (1O2) is produced by leucocytes during inflammatory reactions, various biochemical reactions and during photoreactions. It deactivates by reacting with a number of targets to produce reactive oxygen species (ROS) and peroxides (that in turn produce ROS). To verify whether serum had the same capability to deactivate secondary oxidants after exposure to 1O2, we provoked a photoreaction using rose bengal added to sera of 53 healthy donors and, after light delivery, reduced 2',7'-dichlorofluorescein (DCFH) was added at the end of irradiation and fluorescence of the oxidized derivative (DCF) was recorded. To avoid optical artifacts, we analyzed the influence of hemolysis. Deactivation capability of secondary oxidants after exposure to (1)O(2) was stable over a long period of time, slightly different between men and women, but standard biochemistry parameters had little influence. Hemolysis, age and platelet number reduced deactivation of 1O2-induced secondary oxidants. Addition of lysed cancer cells had no influence. Blood sampling in clot act tubes gave a better signal than in heparinized tubes. Red blood cells (RBCs) loaded with antioxidants strongly decreased deactivation of secondary oxidants. Assays are in progress to evaluate the clinical implications of these findings.

Chemiluminescent analysis of plasma antioxidant capacity in uremic patients undergoing hemodialysis.

OBJECTIVE: Hemodialysis is a common therapeutic strategy for patients with end stage renal failure. During the hemodialytic process, the neutrophils are activated (neutrophil burst) due to the hemoincompatibility induced by hemodialysis. As a result, the activated neutrophils release reactive oxygen species (ROS), such as hydrogen peroxide, singlet oxygen, and hypochlorite, into the bloodstream and cause oxidative damage. METHODS: This study investigated the antioxidant alteration of plasma in uremic patients undergoing hemodialysis by chemiluminescent analysis. The antioxidant capacities of plasma in scavenging hydrogen peroxide, singlet oxygen, and hypochlorite were investigated in this experiment. In addition, investigation of the ferric-reducing ability of plasma (FRAP) would be covered in this study as well. RESULTS: This study found that after hemodialysis, the antioxidant capacities of plasma in scavenging hydrogen peroxide, singlet oxygen, and hypochlorite decreases 7.9%, 18.8%, and 18.9%, respectively. Moreover, the FRAP is reduced by 56%. We speculate that the loss of dialyzable solutes (such as uremic solutes and antioxidants with small molecular weight) in plasma resulted in its decrease in antioxidant capacity. CONCLUSION: We therefore suggest that the supplement of antioxidants with small molecular weight is capable of regaining antioxidant defense in plasma and preventing oxidative damage induced by hemodialysis.

Early diagnosis of cancer by detecting the chemiluminescence of hematoporphyrins in peripheral blood lymphocytes.

Early detection and optimal treatment are the most effective means to improve cancer mortality. Mass screening for cancer has yielded a marked reduction of cancer mortality in the United States. Simple and effective methods are expected for screening of malignancy. Hematoporphyrin derivatives (HPDs) are known to accumulate in cancer cells; thus, HPD has been used for local diagnosis and photodynamic therapy of cancer. The lymphocytes of cancer patients also demonstrate the active uptake of HPD and this phenomenon has been applied for the diagnosis of cancer. In the present study, we have developed a novel method for measurement of the chemiluminescence of HPD in peripheral blood lymphocytes. HPD is composed of hematoporphyrin and its oligomers. Seven cancer patients and seven controls were recruited for this study. The primary cancers included two prostate cancers (one without metastasis and the other with lung metastasis), a renal cancer, a lung adenocarcinoma with systemic metastasis, two gallbladder cancers with lung metastasis, and a colon cancer with liver metastasis. HPD in lymphocytes was measured using a highly sensitive chemiluminescence analyzer with laser light irradiation to detect photoemission by (1)O(2) from HPD. The intensity of chemiluminescence exhibited a linear correlation with the concentrations of HPD. In addition, the level of HPD in lymphocytes was significantly higher in cancer patients than that in healthy volunteers (p < 0.05). These results suggest that detection of the chemiluminescence of HPD in lymphocytes could be a sensitive and simple method for cancer diagnosis and screening.

Singlet oxygen enhances intrinsic thrombolysis: the intrinsic oxidative clot lysis assay (INOXCLA).

Granulocytes are important cells of inflammation and cellular thrombolysis. They produce urokinase (u-PA) and chloramines. In this study, u-PA/chloramine-mediated fibrinolysis is imitated in a microtiter-plate. Seventy-five microliters plasma are incubated with 50 microL 50% Pathromtin SL, 6% BSA, and 38 mM CaCl2 for 30 minutes (37 degrees C). Then, 50 microL 10 mM chloramine-T in PBS are added. After 30 minutes (37 degrees C), 50 microL 0, 100, or 10 IU/mL u-PA in 6% BSA-PBS are added and the turbidity is determined at 405 nm after 0, 3, or 16 hours. Clot lysis was increased more than tenfold by 0.5 to 1 micromoles chloramine (ED50 after 3h = about 0.25 micromoles = 2 mM final concentration). The normal range for the present intrinsic oxidative clot lysis assay (INOXCLA) is 100% +/- 25% (MV +/- SD; 100 relative % of norm; the normal lysis being 60 absolute %; CVs < 10%). Fifty percent lysis of adherent microclots occurred after 0.75 hours, 2 hours, 14 hours, 13 days, or 17 days when using 1000, 100, 10, 1, or 0 IU/mL u-PA reagent. If the u-PA activity is quenched by PAI-2, no clot lysis appears. Chloramines are important physiologic generators of nonradical excited singlet oxygen and enhance u-PA-mediated lysis of plasma clots. Based on the u-PA/chloramines coaction, a new global fibrinolysis assay has been derived.

Correlation of oxidative stress parameters and inflammatory markers in coronary artery disease patients.

OBJECTIVES: In addition to many traditional risk factors for coronary artery disease (CAD) development, enhanced oxidative stress and inflammation are serious conditions that may also be classified as novel risk factors. In the present study, we assessed the relationship between several parameters of oxidative stress status [malonaldehyde (MDA), superoxide anion (O(2)(-)) and plasma and erythrocyte superoxide dismutase (SOD) activities] with high sensitivity C-reactive protein (hsCRP) and fibrinogen as inflammation markers. DESIGN AND METHODS: Oxidative stress status parameters, inflammation markers and lipid status parameters were measured in 385 subjects [188 coronary heart disease (CHD) patients with angiographically diagnosed coronary artery disease (CAD), 141 patients with occlusion >50% in at least one major coronary artery (CAD+) and 47 patients with occlusion less than 50% (CAD-), and 197 CHD-free middle-aged subjects (the control group)]. RESULTS: The plasma MDA concentration and the level of O(2)(-) in plasma were significantly higher in combination with significantly lower SOD activity in the CAD+ group vs. the control group. By using multiple stepwise regression analysis, fibrinogen and hsCRP showed independent correlation with MDA. Binary logistic regression analysis indicated that both MDA and O(2)(-) were significantly associated with CAD development and adjustment for inflammatory markers weakened this association in the case of MDA. CONCLUSIONS: The relationship between oxidative stress parameters and inflammatory species suggest their strong mutual involvement in atherosclerosis development that leads to CAD progression.

Reduced intracellular oxygen radical production in whole blood leukocytes from COPD patients and asymptomatic smokers.

RATIONALE AND OBJECTIVES: COPD is characterized by irreversible airflow obstruction. It has, however, become clear that COPD also is a systemic disease. In the present study, we sought to investigate its impact on different peripheral leukocyte subpopulations that are recognized as important effector cells in the lung tissue. METHODS: We enrolled 20 patients with stable, moderate COPD (FEV1, 33 to 69%). Ten asymptomatic smokers and 10 nonsmokers served as control groups. Flow cytometry and whole blood analysis were used to minimize unwanted ex vivo modulation. Oxidative burst and adhesion molecule mobilization were analyzed on freshly drawn cells and after in vitro activation. MEASUREMENTS AND MAIN RESULTS: We found reduced oxidative burst in neutrophils, monocytes, and eosinophils after in vitro stimulation with tumor necrosis factor (TNF) and the bacterial peptide N-formyl-methionyl-leucyl-phenylalanine (fMLP) in both COPD patients and asymptomatic smokers as compared to nonsmoking control subjects. Vascular involvement was determined as increased soluble intercellular adhesion molecule-1 (sICAM-1) in the COPD group. There were no differences in adhesion molecule expression among the three groups. However, in COPD patients who had smoked the same morning prior to blood sampling, we found a reduced ability to mobilize adhesion molecule CD11b after TNF plus fMLP activation in all investigated cell types. "Acute" smoking did not significantly alter respiratory burst measurements. CONCLUSIONS: Both COPD patients and asymptomatic smokers have increased levels of sICAM-1 and a reduced intracellular oxidative burst in vitro, indicating a vascular endothelial activation and a possible state of refractoriness in circulating phagocytes in COPD. Although expression and mobilization of adhesion molecules were similar between groups, the acute smoke effect on CD11b points out the value of information on smoking behavior when analyzing function of peripheral inflammatory cells in a smoking population.

Direct measurement of free radicals in the brain cortex and the blood serum after nociceptive stimulation in rats.

The concentrations of ROS were measured in samples of the sensorimotor brain cortex and in the rat blood. We measured the following parameters: The six lines spectra, nitroxide radical, free hydroxyl radical and singleton oxygen. Their concentration was measured under physiological conditions, after the nociceptive stimulation and after the application of melatonin, both in normal and stimulated animals. In the brain cortex only the singleton oxygen decreased after the nociceptive stimulation, whereas the nitroxide radicals and six lines spectra increased. The free hydroxyl radicals did not change significantly. In the blood serum the six lines spectra and nitroxide radical increased, the concentration of the free hydroxyl radicals did not change. Melatonin increased both the hydroxyl and nitroxide radicals. There was a non-significant decrease in the six lines spectra. The estimation of ROS can be used as a tool for detecting metabolic changes and the consequences of different environmental influences, in our case the influence of nociception and melatonin.

Generation of singlet oxygen induces phospholipid scrambling in human erythrocytes.

Maintenance of phospholipid asymmetry of the plasma membrane is essential for cells to prevent phagocytic removal or acceleration of coagulation. Photodynamic treatment (PDT), which relies on the generation of reactive oxygen species to achieve inactivation of pathogens, might be a promising approach in the future for decontamination of red blood cell concentrates. To investigate whether PDT affects phospholipid asymmetry, erythrocytes were illuminated in the presence of 1,9-dimethyl-methylene blue (DMMB) as photosensitizer and subsequently labeled with FITC-labeled annexin V. This treatment resulted in about 10% annexin V positive cells, indicating exposure of phosphatidylserine (PS). Treatment of erythrocytes with N-ethylmaleimide (NEM) prior to illumination, to inhibit inward translocation of PS via the aminophospholipid translocase, resulted in enhanced PS exposure, while treatment with H(2)O(2) (previously shown to inhibit phospholipid scrambling) greatly diminished PS exposure, indicating the induction of phospholipid scrambling by PDT. Only erythrocytes illuminated in the presence of DMMB showed translocation of NBD-phosphatidylcholine (NBD-PC), confirming scrambling induction. Double label experiments indicated that PS exposure does not occur without concurrent scrambling activity. Induction of scrambling was only moderately affected by Ca(2+) depletion of the cells. In contrast, scavengers of singlet oxygen were found to prevent phospholipid scrambling induced by PDT. The results of this study show that phospholipid scrambling is induced in human erythrocytes by exposure to singlet oxygen.

Singlet oxygen quenching activity of human serum.

Singlet oxygen is regarded as contributing to the pathogenesis of various diseases including light-induced skin disorders and inflammatory response. In this study, the correlation between singlet oxygen quenching activity (SOQA) of human serum and blood biochemistry or life-style was evaluated. Healthy volunteers were recruited and carried out a measurement of SOQA by using electron paramagnetic resonance (EPR) and a questionnaire survey about a smoking. It was demonstrated that major quenchers of singlet oxygen in serum are proteins, and small molecular anti-oxidants relatively play a minor role. SOQA of whole sera showed no correlation with protein concentration, but positively correlated with SOQA of small molecular fraction. In vitro studies demonstrated that the decrease of sulfhydryl groups by NO or superoxide significantly attenuated SOQA of albumin. Together, these results may imply that the underlying oxidative condition in each individual influences both small molecular antioxidant states and the sulfhydryl content of serum proteins. SOQA of sera from women with a smoking history was significantly lower compared to non-smoking women, suggesting that the smoking habit impaired the defense mechanism against singlet oxygen.