Refine
Document Type
- Article (3)
- Doctoral Thesis (2)
Language
- English (5)
Has Fulltext
- yes (5)
Is part of the Bibliography
- no (5)
Keywords
- hydrogen peroxide (5) (remove)
Institute
Publisher
- MDPI (2)
- IOP Publishing (1)
Cold physical plasma is a partially ionized gas expelling many reactive oxygen and nitrogen
species (ROS/RNS). Several plasma devices have been licensed for medical use in dermatology, and
recent experimental studies suggest their putative role in cancer treatment. In cancer therapies with
an immunological dimension, successful antigen presentation and inflammation modulation is a
key hallmark to elicit antitumor immunity. Dendritic cells (DCs) are critical for this task. However,
the inflammatory consequences of DCs following plasma exposure are unknown. To this end,
human monocyte-derived DCs (moDCs) were expanded from isolated human primary monocytes;
exposed to plasma; and their metabolic activity, surface marker expression, and cytokine profiles
were analyzed. As controls, hydrogen peroxide, hypochlorous acid, and peroxynitrite were used.
Among all types of ROS/RNS-mediated treatments, plasma exposure exerted the most notable
increase of activation markers at 24 h such as CD25, CD40, and CD83 known to be crucial for T cell
costimulation. Moreover, the treatments increased interleukin (IL)-1α, IL-6, and IL-23. Altogether,
this study suggests plasma treatment augmenting costimulatory ligand and cytokine expression in
human moDCs, which might exert beneficial effects in the tumor microenvironment.
The leading hypothesis of why organisms age is the “Free Radical Theory of Aging”, which states that the accumulation of reactive oxygen species (ROS), such as superoxide (O2•-) and hydrogen peroxide (H2O2), causes protein, lipid and DNA damage and leads to the observed age-related decline of cells and tissues. A major obstacle in analyzing the role of oxidative stress in aging organisms is the inability to precisely localize and quantify the oxidants, to identify proteins and pathways that might be affected, and ultimately, to correlate changes in oxidant levels with the lifespan of the organism. To directly monitor the onset and extent of oxidative stress during the lifespan of Caenorhabditis elegans, we utilized the fluorescent H2O2 sensor protein HyPer, which enabled us to quantify endogenous peroxide levels in different tissues of living animals in real time. We made the surprising observation that wildtype C. elegans is exposed to very high peroxide levels during development. Peroxide levels drop rapidly as the animals mature, and low peroxide levels then prevail throughout the reproductive age, after which an age-accompanying increase of peroxide level is observed. These results were in excellent agreement with findings obtained by using the highly quantitative redox proteomic technique OxICAT, which monitors the oxidation status of redox-sensitive proteins as read-out for onset, localization, and protein targets of oxidative stress. By using OxICAT, we detected increased protein thiol oxidation during the development of C. elegans and in aging animals. Many processes in C. elegans might potentially contribute to the elevated peroxide levels observed during development, including cuticle formation, apoptosis, proliferation, gametogenesis, or ROS signaling. The finding that all investigated C. elegans mutants regardless of their lifespan are exposed to high developmental peroxide levels argues for ROS accumulation to be a universal and necessary event. Yet, recovery from the early oxidative boost might determine the subsequent adult lifespan, as we found that long-lived daf-2 mutants transition faster to reducing conditions than short-lived daf-16 mutants, which retain higher peroxide levels throughout their mature life. These results suggest that changes in the cellular oxidant homeostasis, encountered at a very early stage in life, might determine subsequent redox levels and potentially the lifespan of organisms. Manipulation of developmental oxidant levels using glucose restriction or a short bolus of superoxide caused a disruption in developmental growth, a delay in reproduction, and a shortened lifespan. These results suggest that developmental oxidant levels are fine-tuned and optimized. Future experiments are aimed to investigate the sources of developmental hydrogen peroxide, and to elucidate whether active down-regulation of antioxidant enzymes during the larval period might foster peroxide accumulation. Preliminary results indicate that this might indeed be the case for peroxiredoxin 2, whose expression was significantly lower during development than at later stages in life. Finally, we investigated whether the observed variances in the developmental peroxide levels of individual worms within a synchronized wildtype population might be responsible for the observed significant variances in lifespan, and hence could serve as a predictor for adult lifespan. Preliminary results revealed that neither too low nor too high peroxide levels during development are beneficial for the lifespan of wildtype worms, suggesting that ROS level during development might be optimized for maximized lifespan. Future experiments aim to reveal the processes that are affected by ROS and which might influence the individual’s lifespan early in life.
The term diabetes mellitus comprises a group of metabolic diseases all distinguished by their main characteristic hyperglycaemia. With a steadily increasing prevalence diabetes displays an enormous burden for patients and health systems and is therefore of special interest for research. The development of the two main types of diabetes, type 1 and type 2, is closely linked to the formation of reactive species, especially hydrogen peroxide, inside different compartments of pancreatic beta cells. However, these cells are especially vulnerable towards oxidative stress mediated by hydrogen peroxide due to a low expression of antioxidative enzymes.
The main aims of the present thesis were to analyse the intracellular generation and to enable the site-specific detection of hydrogen peroxide to evaluate its role in the delicate equilibrium between redox signalling and oxidative stress under certain pathophysiological conditions, and moreover to monitor its movement through compartments and subcellular membranes of insulin-producing cells. Additionally, a new methodology for an artificial site-specific generation of hydrogen peroxide inside living cells was developed.
Background: The use of cold atmospheric plasma (CAP) in oncology has been intensively investigated over the past 15 years as it inhibits the growth of many tumor cells. It is known that reactive oxidative species (ROS) produced in CAP are responsible for this effect. However, to translate the use of CAP into medical practice, it is essential to know how CAP treatment affects non-malignant cells. Thus, the current in vitro study deals with the effect of CAP on human bone cancer cells and human osteoblasts. Here, identical CAP treatment regimens were applied to the malignant and non-malignant bone cells and their impact was compared. Methods: Two different human bone cancer cell types, U2-OS (osteosarcoma) and A673 (Ewing’s sarcoma), and non-malignant primary osteoblasts (HOB) were used. The CAP treatment was performed with the clinically approved kINPen MED. After CAP treatment, growth kinetics and a viability assay were performed. For detecting apoptosis, a caspase-3/7 assay and a TUNEL assay were used. Accumulated ROS was measured in cell culture medium and intracellular. To investigate the influence of CAP on cell motility, a scratch assay was carried out. Results: The CAP treatment showed strong inhibition of cell growth and viability in bone cancer cells. Apoptotic processes were enhanced in the malignant cells. Osteoblasts showed a higher potential for ROS resistance in comparison to malignant cells. There was no difference in cell motility between benign and malignant cells following CAP treatment. Conclusions: Osteoblasts show better tolerance to CAP treatment, indicated by less affected viability compared to CAP-treated bone cancer cells. This points toward the selective effect of CAP on sarcoma cells and represents a further step toward the clinical application of CAP.
AbstractPulsed streamer discharges submerged in water have demonstrated potential in a number of applications. Especially the generation of discharges by short high-voltage pulses in the nanosecond range has been found to offer advantages with respect to efficacies and efficiencies. The exploited plasma chemistry generally relies on the initial production of short-lived species, e.g. hydroxyl radicals. Since the diagnostic of these transient species is not readily possible, a quantification of hydrogen peroxide provides an adequate assessment of underlying reactions. These conceivably depend on the characteristics of the high-voltage pulses, such as pulse duration, pulse amplitude, as well as pulse steepness.A novel electrochemical flow-injection system was used to relate these parameters to hydrogen peroxide concentrations. Accordingly, the accumulated hydrogen peroxide production for streamer discharges ignited in deionized water was investigated for pulse durations of 100 ns and 300 ns, pulse amplitudes between 54 kV and 64 kV, and pulse rise times from 16 ns to 31 ns. An independent control of the individual pulse parameters was enabled by providing the high-voltage pulses with a Blumlein line. Applied voltage, discharge current, optical light emission and time-integrated images were recorded for each individual discharge to determine dissipated energy, inception statistic, discharge expansion and the lifetime of a discharge.Pulse steepness did not affect the hydrogen peroxide production rate, but an increase in amplitude of 10 kV for 100 ns pulses nearly doubled the rate to (0.19 ± 0.01) mol l−1 s−1, which was overall the highest determined rate. The energy efficiency did not change with pulse amplitude, but was sensitive to pulse duration. Notably, production rate and efficiency doubled when the pulse duration decreased from 300 ns to 100 ns, resulting in the best peroxide production efficiency of (9.2 ± 0.9) g kWh−1. The detailed analysis revealed that the hydrogen peroxide production rate could be described by the energy dissipation in a representative single streamer. The production efficiency was affected by the corresponding discharge volume, which was comprised by the collective volume of all filaments. Hence, dissipating more energy in a filament resulted in an increased production rate, while increasing the relative volume of the discharge compared to its propagation time increased the energy efficiency.