Hydrogen peroxide- metals- chelating agents; interactions and analytical techniques

Rämö, J. (Jaakko)

25 April 2003

Abstract Information about interactions among metals, hydrogen peroxide and chelating agents is needed to develop environmental technology and the operating efficiency of modern elemental chlorine free and total chlorine free bleaching processes. The work presented here focused on the properties of metal chelates and corrosion of titanium in an alkaline hydrogen peroxide solution. A comparative study between three rapid analysis methods, ICP-AES, XRF and ISE, was performed in pulp matrix and error sources of ISE were investigated in detail. Sensitive and selective GC methods for chelating agents ADA and NTA in water matrices were developed. Decomposition of ADA (percentage of residual 71) was observed already at the hydrogen peroxide anion level of 400 mg/l in which DTPA was more persistent (percentage of residual 94). EDTA was stable even in the hydrogen peroxide anion level of 1200 mg/l, in which its percentage of residual was 94. DTPA, EDTA and ADA were more soluble in the presence of iron and manganese than in the absence of these metals. The chelation of iron appeared to be thermodynamically limited in hydrogen peroxide bleaching conditions. Unalloyed (Grade 2) and alloyed (Grade 5) titanium corroded at the hydrogen peroxide anion level of 200 mg/l. The presence of calcium and silica inhibitors and further iron and manganese enhanced the critical hydrogen peroxide anion levels. Grade 5 was inferior to Grade 2. During rapid uniform corrosion, the potential of unalloyed titanium was under 200 mV (SHE) and lower than that of platinum. Over 90% of manganese and many other metals could be leached into aqueous phase for ICP-AES analysis using chelation or acid hydrolysis. An XRF method for manganese, iron and copper in pulp including little or no sample treatment was developed. Measuring temperature differences and atmospheric carbon dioxide were observed to be notable error sources of the ISE technique.

bleaching

chelating agents

hydrogen peroxide

metals

Simultaneous electrosynthesis of alkaline hydrogen peroxide and sodium chlorate

Kalu, Eric Egwu

January 1987

Simultaneous electrosynthesis of alkaline hydrogen peroxide and sodium chlorate in the same cell was investigated. The alkaline hydrogen peroxide was obtained by the electroreduction of oxygen in NaOH on a fixed carbon bed while the chlorate was obtained by the reaction of anodic electrogenerated hypochlorite and hypochlorous acid in an external reactor. An anion membrane, protected on the anode side with an asbestos diaphragm was used as the separator between the two chambers of the cell. The effects of superficial current density (1.2 - 2.4 kA m⁻²), sodium hydroxide concentration (0.5 - 2.0 M) and catholyte flow (0.1 x 10⁻⁶ - 0.5 x 10⁻⁶ m³ s⁻¹) on the chlorate and peroxide current efficiencies were measured. The effect of peroxy to hydroxy mole ratio on the chlorate current efficiency was measured too. The cell was operated at fixed anolyte flow of 2.0 x 10⁻⁶ m³ s⁻¹, inlet and outlet temperatures of 27/33°C (anode side), 20/29°C (cathode side), cell voltages of 3.0 - 4.2 V (current density of 1.2 - 2.4 kA -m⁻²) and a fixed temperature of 70°C in the anolyte tank. Depending on the conditions, alkaline peroxide solution and sodium chlorate were cogenerated at peroxide current efficiency between 20% and 86%, chlorate current efficiency between 51.0% and 80.6% and peroxide concentration ranging from 0.069 M to 0.80 M. The cogeneration of the two chemicals was carried out at both concentrated (2.4 - 2.8 M) and dilute (0 - 0.5 M) chlorate solutions. A relative improvement on the current efficiencies at concentrated chlorate was observed. A chloride balance indicated negligible chloride loss to the catholyte. The results are interpreted in terms of the electrochemical and chemical kinetics and the hydrodynamics of the cell . / Applied Science, Faculty of / Chemical and Biological Engineering, Department of / Graduate

Hydrogen peroxide

Sodium chlorate

Electrochemical analysis

Experimental Evaluation of Catalyzed Hydrogen Peroxide and Sodium Persulfate for Destruction of BTEX Contaminants

Crimi, Michelle L., Taylor, Jesse

01 January 2007

Due to the toxicity and prevalence of BTEX contaminants (benzene, toluene, ethylbenzene, and xylenes) at hazardous waste sites, approaches for their remediation are of interest, especially those that particularly address benzene, which is often the limiting factor for achieving regulatory cleanup at these contaminated sites. In situ chemical oxidation (ISCO) is a viable technology for BTEX destruction, and hydrogen peroxide and sodium persulfate are two oxidants of interest for BTEX treatment.Laboratory studies were conducted to compare BTEX contaminant destruction and oxidant persistence for these two oxidants and for varied methods of oxidant activation/propagation. Additionally, studies were performed to compare contaminant destruction and oxidant persistence in laboratory contaminant spike systems vs. field site contaminant systems. Finally, contaminant destruction and oxidant persistence in field porous media with varied characteristics were evaluated. Contaminant and oxidant concentrations were measured at multiple time points over a three-week reaction period in each oxidant and oxidant activation/propagation system.Under the comparable conditions evaluated here, sodium persulfate systems demonstrated greater BTEX contaminant destruction and greater oxidant persistence than hydrogen peroxide systems. FeSO4 and citric acid activation of sodium persulfate resulted in greater BTEX destruction and greater oxidant persistence than pH adjustment or hydrogen peroxide activation in both laboratory contaminant spike systems and field gas condensate systems. Additionally, results indicate that the response of the contaminant(s) and oxidant (extent and rate of depletion) are both contaminant-and porous media type-dependent.

BTEX

hydrogen peroxide

oxidation

persulfate

remediation

The Impact of Pyruvate Oxidase (SpxB) on the Release of the Toxin Pneumolysin in Streptococcus Pneumoniae

Bryant, Joseph Colby

14 August 2015

Streptococcus pneumoniae (pneumococcus) is a major human pathogen and commensal organism of the nasopharynx. A major virulence factor of the pneumococcus is the cholesterol dependent, pore forming cytolysin pneumolysin. This toxin acts extracellularly, but the mechanism of release has not been well elucidated. Despite being a catalase negative organism, the pneumococcus produces up to millimolar concentrations of hydrogen peroxide through the activity of pyruvate oxidase. In all strains analyzed, deletion of the pyruvate oxidase gene yielded a significant reduction in the amount of PLY observed in the supernatant via western blot. A single strain, WU2 was also observed to have a significant (p<.05) reduction in the amount of PLY observed in the supernatant when treated with extracellular catalase. Furthermore, a significant correlation between hydrogen peroxide production and PLY release was observed in a panel of 15 clinical isolates.

pneumolysin

toxin

hydrogen peroxide

microbiology

streptococcus pneumoniae

A comparison of the disinfecting capacity of commercial preparations of 3% and 6% hydrogen peroxide and its applicability to the disinfection of soft contact lenses.

Levine, William Leonard

01 January 1980

No description available.

Hydrogen peroxide

Soft contact lenses Disinfection.

Simulating the Use of Hydrogen Peroxide in Diesel Autothermal Reforming: A Comparative Study

Alhussain, Ali S.

08 1900

This thesis reports the outcome of a simulation study that examines the feasibility of using hydrogen peroxide as an alternative oxidant in the autothermal reforming (ATR) of diesel. The primary objective is to compare hydrogen peroxide's performance against conventional oxidants in reforming, focusing on product distribution and three pivotal process properties: diesel conversion, hydrogen production, and ethylene generation. The study further investigates the influence of the heat of decomposition on the performance and reaction routes of different oxidants. Additionally, a comparative analysis is conducted on the reforming performance in different reformer configurations, specifically contrasting a combined-reformer-configuration with a catalytic-reformer configuration. The ANSYS Chemkin-Pro is utilized to understand the potential benefits and challenges of the proposed approached. A reduced chemical mechanism of N-heptane/Toluene reforming as a surrogate for diesel, combined with a detailed surface reaction mechanism of propene on a three-way Pt/Rh catalyst are used in this study. It is found that the use of hydrogen peroxide as an oxidant demonstrated a complete fuel conversion and 183% higher hydrogen yield when compared with conventional oxidants. It also led to a 12% lower generation of ethylene, a precursor for coke formation. The catalytic-reformer configuration showed superior performance over the combined-reformer-configuration in terms of hydrogen yield. The insights from this study offer valuable perspectives on the feasibility and efficiency of using hydrogen peroxide as an alternative oxidant in the ATR of diesel, paving the way for potential advancements in the field.

Autothermal reforming

hydrogen

hydrogen peroxide

diesel

oxidant

H2O2-mediated oxidation and nitration enhances DNA binding capacity / DNA repair via up-regulated epidermal wild-type p53 in vitiligo.

Salem, Mohamed M.A.

January 2009

The entire epidermis of patients with vitiligo exhibits accumulation of up to 10-3M concentrations of hydrogen peroxide (H2O2) (Schallreuter, Moore et al. 1999). Over the last decade our group and others have focused on the effect of H2O2-mediated oxidative stress on the function of many proteins and peptides due to oxidation of target amino acid residues in their structure including L-methionine, L-tryptophan, L-cysteine and seleno cysteine (Rokos, Beazley et al. 2002; Gillbro, Marles et al. 2004; Hasse, Kothari et al. 2005; Schallreuter, Chavan et al. 2005; Spencer, Chavan et al. 2005; Chavan, Gillbro et al. 2006; Elwary, Chavan et al. 2006; Gibbons, Wood et al. 2006; Schallreuter, Bahadoran et al. 2008; Shalbaf, Gibbons et al. 2008; Wood, Decker et al. 2009). Moreover, it was shown that patients with vitiligo possess up regulated wild type functioning p53 protein in their skin (Schallreuter, Behrens- Williams et al. 2003). The reason behind this up regulation has remained unclear (Schallreuter, Behrens-Williams et al. 2003). Therefore the aim of this thesis was to get a better understanding of these puzzling data. Along this project different techniques have been used including Western blot, dot blot, immuno precipitation, immuno fluorescence, EMSA and computer modelling. In this thesis we confirmed the previous result on up regulation of p53 in vitiligo and we showed that p90MDM2, the master regulator for p53 protein is not different in patients and healthy controls. Therefore we decided to test for expression of p76MDM2 which mediates the inhibition of p90MDM2-p53 binding. Our results show for the first time the presence and over expression of p76MDM2 protein in vitiligo compared to 3 healthy individuals. This result could provide an explanation, why up regulated p53 is not degraded in this disease. Since epidermal H2O2 accumulation has been extensively documented in vitiligo, we wanted to know whether other ROS could also contribute to the overall oxidative stress in this scenario. Therefore we turned our interest to nitric oxide (NO) and its possible effects on p53 protein. In order to elucidate this role in more detail, the expression levels of epidermal nitric oxide synthesase (iNOS) and the oxidation product of NO and O2 - i.e peroxynitrite (ONOO-) were investigated. Our data revealed over expression of iNOS and nitrated tyrosine residues, the foot print for ONOO-. Moreover, we show for the first time the presence of abundant nitration of p53 protein in vitiligo. In addition using purified p53 from E. coli strain (BL21/DE3) and mutant p53 protein from HT-29 cells (colon cancer cells), we show that nitration takes place in a dose and time dependent manner. On this basis we investigated the effect of both H2O2 and ONOO- on p53-DNA binding capacity employing EMSA, since this is the most acceptable technique to follow the binding between proteins and DNA. Our results revealed that ONOO- abrogated p53-DNA binding capacity at concentrations >300 ¿M, meanwhile oxidation of p53 protein with H2O2 at the same concentrations does not affect binding capacity. Importantly, a much higher p53- DNA binding capacity was observed after exposure to both ONOO- and H2O2. Taken together, p53 is regulated by both ROS (H2O2) and RNS (ONOO-). Next we identified the presence of phosphorylated and acetylated p53 in vitiligo. Phosphorylation of ser 9 and ser 15 residues of the protein are associated with over expressed ATM protein kinase, while acetylation of lys 373, 382 residues correlates with increased PCAF expression. We show that up regulated p53 is associated with over expressed p21 (cyclin dependent kinase inhibitor 1) and induced PCNA 4 expression. Hence, we can conclude that p53 in patients with vitiligo is up regulated, activated and functional. Finally we show up regulated BCL-2 supporting the long voiced absence of increased apoptosis in vitiligo. Given that patients with vitiligo have no increased risk for solar induced skin cancer and increased photo damage (Calanchini-Postizzi and Frenk 1987; Westerhof and Schallreuter 1997; Schallreuter, Tobin et al. 2002), despite the presence of increased DNA damage as evidenced by increased 8-oxoG levels in the skin and in the plasma, our findings suggest that both p53 and PCNA provide a powerful machinery to mediate DNA repair via hOgg1, APE1 and DNA polymerase ß (Shalbaf 2009). On this basis it is tempting to conclude that DNArepair is the overriding mechanism to combat oxidative stress in this disease. / Egyptian government; Institute for Pigmentary Disorders in association with the EM Arndt University of Greifswald, Germany.

Vitiligo

Oxidative stress

Hydrogen peroxide

DNA repair

Elucidation Of Key Interactions Between In Situ Chemical Oxidation Reagents And Soil Systems

Harden, John Michael

13 May 2006

Many soil and aquifer systems in the United States have been subjected to chemical contamination from past industrial and military activities. While many remediation technologies are currently being applied, in situ chemical oxidation (ISCO) is one option that is often favored because of its potential for fast remediation times and high user control. This technology involves the direct injection of chemical oxidizers (e.g. hydrogen peroxide, ozone, or permanganate) into targeted contaminant zones within the subsurface, and it has been proven to be amenable to both BTEX compounds and other volatile organic compounds such as chlorinated solvents. This study had several key objectives. Firstly, multiple soil samples, each containing an elevated level of a targeted chemical constituent, were successfully collected in order to provide a wide range of soil types in order to make important comparisons and correlations related to ISCO?s impacts. Secondly, the impact of common soil constituents on process reagent transport was studied in order to determine which soil constituents would act as primary hindrances for the transport of hydrogen peroxide and ozone into the subsurface. Thirdly, experiments were performed to pinpoint certain personnel safety threats such as excess oxygen and heat generation that might arise during process application. Fourthly, the impact of ISCO process application on soil fabric properties was examined. Soil aerobic microbial populations, soil hydraulic conductivity, soil natural organic matter constituents, and soil adsorptive properties were all shown to be impacted following the application of chemical oxidizers.

chemical oxidation

remediation

hydrogen peroxide

ozone

soil

CATALASE ACTIVITY, POTENTIAL VIRULENCE FACTORS, AND THEIR RESPONSE TO OXYGEN IN <i>MYCOPLASMA IOWAE</i>

Pritchard, Rachel Elizabeth

21 October 2014

No description available.

Microbiology

mycoplasma

Mycoplasma iowae

catalase

hydrogen peroxide

A STUDY OF THE HYDROGEN BONDING CHARACTERISTICS OF HYDROGEN PEROXIDE BY MATRIX ISOLATION VIBRATIONAL SPECTROSCOPY

Goebel, James Robert

January 2000

No description available.

Chemistry, Physical

Hydrogen Peroxide Complexes

Matrix Isolation