The composition of anodic lead dioxide and its use in the quantitative determination of small amounts of lead

Day, Thomas Gordon,

January 1900

Thesis (Ph. D.)--University of Missouri, 1935. / Vita. By T.G. Day and W.T. Schrenk. Published also as part 2 of "The quantitative determination of lead by the electrolytic deposition of lead dioxide ... By Thomas Gordon Day, Phillip Hall Delano and W.T. Schrenk." Rolla, Mo., 1935. eContent provider-neutral record in process. Description based on print version record. Bibliography: p. 62-68.

Electrochemical Fragmentation of Proteins

Robertson, Paul David

January 2012

This thesis presents a study of three electrochemical methods applied to the fragmentation of proteins. Direct electrochemical oxidation at graphite electrodes, production of hydroxyl radicals on lead dioxide electrodes and electro-Fenton methods were each investigated as methods for fragmenting proteins. A key objective of this project was to achieve specific fragmentation, meaning that fragmentation would only occur at defined sites on each protein molecule and that this process may provide a new pathway to producing useful protein fragments. Protein fragments produced by electrochemical means were detected using mass spectroscopy and gel electrophoresis techniques. Direct electrochemical oxidation of the target proteins was studied at a graphite rod electrode in a solution containing acetonitrile, water and formic acid. β-lactoglobulin fragmentation was detected by mass spectroscopy, but fragmentation did not occur to an extent where fragments were observable by gel electrophoresis. It was evident that most of the electrolysis products appear to arise from non-cleavage oxidation reactions. The use of lead dioxide electrodes to generate hydroxyl radicals was thoroughly investigated in this work. For the first time, specific fragmentation of proteins has been achieved by direct electrochemical generation of hydroxyl radicals on the electrode surface. The pH and the chemical composition of the protein solutions were found have a strong influence on the extent of fragmentation. Electro-Fenton chemistry was conducted on a woven carbon fibre electrode. The electrode successfully reduced dissolved oxygen to produce hydrogen peroxide and regenerated Fe(II) from Fe(III). Cell conditions were optimized for applied current, method of oxygen delivery and cell division. The Fenton reaction between hydrogen peroxide and Fe(II) produced hydroxyl radicals that were able to specifically fragment proteins. It was not possible to increase the concentration of these protein fragments by increasing the hydrogen peroxide concentration, as the fragmentation products were also further fragmented. Electrochemical protein fragmentation was achieved in all three electrochemical systems, however the most promising results were achieved by electrochemical generation of hydroxyl radicals on a lead dioxide electrode. This work has the potential to become a fast and cost effective method for the fragmentation of proteins required for nutrition and medical purposes or for use in protein identification analysis with mass spectroscopy.

Electrochemical

Fragmentation

Protein

Lead Dioxide

Electro-Fenton

Investigation of the source and occurrence of lead in the Brandon Water Supply System

Winning, Lisa

16 January 2015

Lead concentrations in drinking water were found to exceed the provincial standard of 10 µg/L in Brandon, Portage la Prairie and Winnipeg, in some locations. Lead dioxide was identified in the scale coating the interior of lead pipes in the Brandon water distribution system. However, during periods of stagnation, free chlorine is used up by the elevated concentrations of natural organic matter (NOM) in the treated water, and lead dioxide is reduced back to more soluble divalent lead, resulting in release of dissolved lead. The removal of NOM and the targeted removal of aquatic humic substances (AHS), thought to be the most reactive fraction of NOM, were investigated as a means of decreasing the reduction of lead dioxide. Contrary to expected results, targeted removal of AHS was not found to have a significant impact on reduction of lead dioxide, while removal of 50% of the NOM non-preferentially was found to significantly decrease the reduction of lead dioxide. This indicates that AHS are not the most reductant fraction of natural organic matter in this particular water.

Lead

Lead dioxide

Drinking water

Natural organic matter

Aquatic humic substances