Multiassay analysis of the toxic potential of hydrogen peroxide on cultured neurons

Hohnholt, Michaela C.; Blumrich, Eva M.; Dringen, Ralf

doi:10.1002/jnr.23502

Cited by 16 publications

(4 citation statements)

References 61 publications

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“…It is well known that H 2 O 2 as a medical disinfectant is used in much higher concentrations (3% vol., i.e., 0.98 M). H 2 O 2 is also often considered as the key antibacterial or antitumor agent of PAW in synergy with other RONS [61]. However, in our studied maximum concentration of 10 mM H 2 O 2 diluted in DW, we did not observe any antibacterial effect (Figure 6) by H 2 O 2 itself, nor H 2 O 2 combined with PEF.…”

Section: Pef Only and H 2 O 2 Onlycontrasting

confidence: 67%

Coupled Antibacterial Effects of Plasma-Activated Water and Pulsed Electric Field

Mentheour

Machala

2022

Front. Phys.

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In the biomedical applications of cold plasma, the dominant biological effect is most typically attributed to the reactive oxygen and nitrogen species (RONS), while the physical effect of electric fields is sometimes overlooked. Here, we investigated the antibacterial effect of RONS in plasma-activated water (PAW) on the inactivation of E. coli bacteria, coupled with a mild 200-nanosecond pulsed electric field (PEF) treatment. By using transient spark discharge plasma in open atmospheric air and closed air reactors, and by adding hydrogen peroxide (H2O2) into the PAW, different chemical compositions of RONS were obtained. We measured the time evolution of the concentrations of key species in the PAW post-discharge: nitrites (NO2−) and H2O2. PAW rich in both NO2− and H2O2 showed an antibacterial effect, which was enhanced by the PEF, whereas PAW rich in NO2− and poor in H2O2 showed an enhancement of the antibacterial effect by the PEF only when H2O2 was externally added. The presence of sufficient concentrations of both NO2− and H2O2 optimized the formation of peroxynitrous acid (ONOOH), which caused a strong peroxidation of the cell membranes leading to the cell death, but it also made them more vulnerable to the PEF treatment. The results suggest that the interaction with radicals during the bacteria exposure to PAW leads to an antibacterial effect reinforced by the pulsed electric field, hence showing a synergy of the chemical and physical plasma agents. This opens new perspectives for applications both plasma and PEF areas of research.

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Section: Pef Only and H 2 O 2 Onlycontrasting

confidence: 67%

Coupled Antibacterial Effects of Plasma-Activated Water and Pulsed Electric Field

Mentheour

Machala

2022

Front. Phys.

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“…H 2 O 2 clearance results primarily from catalase activity and the glutathione system and exhibits characteristic times ranging from 0.1 s to minutes. − Nevertheless, the slower removal rates of H 2 O 2 can lead to not only higher sensor signals in vivo than expected from calibrations in vitro (as mentioned above), but also to a moderate accumulation of H 2 O 2 in the brain in the vicinity of the sensor. However, this H 2 O 2 accumulation is not expected to show any toxic effects unless it well exceeds 10 μM . For moderate rates of H 2 O 2 clearance (5 s –1 ), the highest accumulation of H 2 O 2 for the simulated sensor responses shown in Figure is 10 μM (faster and slower expected clearance rates result in peak concentrations of 7.25 and 13.5 μM, respectively) for Glut release at 1 μm, and in all cases, this value drops by ∼60% or more for release 3 μm or greater from the sensor surface.…”

Section: Resultsmentioning

confidence: 86%

“…However, this H 2 O 2 accumulation is not expected to show any toxic effects unless it well exceeds 10 μM. 26 For moderate rates of H 2 O 2 clearance (5 s −1 ), the highest accumulation of H 2 O 2 for the simulated sensor responses shown in Figure 2 is 10 μM (faster and slower expected clearance rates result in peak concentrations of 7.25 and 13.5 μM, respectively) for Glut release at 1 μm, and in all cases, this value drops by ∼60% or more for release 3 μm or greater from the sensor surface. The sensor response scales with H 2 O 2 concentration at the electrode surface, which can be elevated for Glut release events closest to the sensor surface that give rise to local H 2 O 2 accumulation.…”

Section: Model Development and Simulated Sensor Response To Glut Conc...mentioning

confidence: 92%

Simulated Performance of Electroenzymatic Glutamate Biosensors In Vivo Illuminates the Complex Connection to Calibration In Vitro

Clay

Monbouquette

2021

ACS Chem. Neurosci.

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Detailed simulations show that the relationship between electroenzymatic glutamate (Glut) sensor performance in vitro and that modeled in vivo is complicated by the influence of both resistances to mass transfer and clearance rates of Glut and H 2 O 2 in the brain extracellular space (ECS). Mathematical modeling provides a powerful means to illustrate how these devices are expected to respond to a variety of conditions in vivo in ways that cannot be accomplished readily using existing experimental techniques. Through the use of transient model simulations in one spatial dimension, it is shown that the sensor response in vivo may exhibit much greater dependence on H 2 O 2 mass transfer and clearance in the surrounding tissue than previously thought. This dependence may lead to sensor signals more than double the expected values (based on prior sensor calibration in vitro) for Glut release events within a few microns of the sensor surface. The sensor response in general is greatly affected by the distance between the device and location of Glut release, and apparent concentrations reported by simulated sensors consistently are well below the actual Glut levels for events occurring at distances greater than a few microns. Simulations of transient Glut concentrations, including a physiologically relevant bolus release, indicate that detection of Glut signaling likely is limited to events within 30 μm of the sensor surface based on representative sensor detection limits. It follows that important limitations also exist with respect to interpretation of decays in sensor signals, including relation of such data to actual Glut concentration declines in vivo. Thus, the use of sensor signal data to determine quantitatively the rates of Glut uptake from the brain ECS likely is problematic. The model is designed to represent a broad range of relevant physiological conditions, and although limited to one dimension, provides much needed guidance regarding the interpretation in general of electroenzymatic sensor data gathered in vivo.

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“…Previous studies revealed the 50% effective concentrations (EC 50 ) of hydrogen peroxide that caused toxicity (viability, cell death, or apoptosis) in mammalian cells: EC 50 values of 100 and 500 μM in mouse endothelial cell lines [39], <100 μM in rat neuronal B50 cells [40], 1 mM in human neuroblastoma SH-SY5Y cells [41], and 30-500 μM (depending on the exposure duration) in rat C6 glioma cells [42]. It has been reported that adverse effects in neurons were induced by 12−500 μM hydrogen peroxide [43], and 25−50 μM hydrogen peroxide led to apoptosis in human Jurkat T-lymphocytes [44]. Our reporter assays can detect 30−50 μM hydrogen peroxide at the lowest concentrations covering the EC 50 values mentioned above.…”

Section: Plos Onementioning

confidence: 99%

Sensing chemical-induced genotoxicity and oxidative stress via yeast-based reporter assays using NanoLuc luciferase

Shichinohe,

Ohkawa,

Hirose

et al. 2023

PLoS ONE

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Mutagens and oxidative agents damage biomolecules, such as DNA; therefore, detecting genotoxic and oxidative chemicals is crucial for maintaining human health. To address this, we have developed several types of yeast-based reporter assays designed to detect DNA damage and oxidative stress. This study aimed to develop a novel yeast-based assay using a codon-optimized stable or unstable NanoLuc luciferase (yNluc and yNluCP) gene linked to a DNA damage- or oxidative stress-responsive promoter, enabling convenient sensing genotoxicity or oxidative stress, respectively. End-point luciferase assays using yeasts with a chromosomally integrated RNR3 promoter (PRNR3)-driven yNluc gene exhibited high levels of chemiluminescence via NanoLuc luciferase and higher fold induction by hydroxyurea than a multi-copy plasmid-based assay. Additionally, the integrated reporter system detected genotoxicity caused by four different types of chemicals. Oxidants (hydrogen peroxide, tert-butyl hydroperoxide, and menadione) were successfully detected through transient expressions of luciferase activity in real-time luciferase assay using yeasts with a chromosomally integrated TRX2 promoter (PTRX2)-linked yNlucCP gene. However, the luciferase activity was gradually induced in yeasts with a multi-copy reporter plasmid, and their expression profiles were notably distinct from those observed in chromosomally integrated yeasts. The responses of yNlucCP gene against three oxidative chemicals, but not diamide and zinc oxide suspension, were observed using chromosomally integrated reporter yeasts. Given that yeast cells with chromosomally integrated PRNR3-linked yNluc and PTRX2-linked yNlucCP genes express strong chemiluminescence signals and are easily maintained and handled without restrictive nutrient medium, these yeast strains with NanoLuc reporters may prove useful for screening potential genotoxic and oxidative chemicals.

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Multiassay analysis of the toxic potential of hydrogen peroxide on cultured neurons

Cited by 16 publications

References 61 publications

Coupled Antibacterial Effects of Plasma-Activated Water and Pulsed Electric Field

Coupled Antibacterial Effects of Plasma-Activated Water and Pulsed Electric Field

Simulated Performance of Electroenzymatic Glutamate Biosensors In Vivo Illuminates the Complex Connection to Calibration In Vitro

Sensing chemical-induced genotoxicity and oxidative stress via yeast-based reporter assays using NanoLuc luciferase

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