Study of lead zirconate titanate films grown by MOCVD

Braun, Wolfgang

05 1900

No description available.

Lead compounds

Ferric oxide

Hydrogen reduction of lead from Kelex 100

De Santis, Donato.

January 1987

No description available.

Lead -- Metallurgy

Hydrometallurgy

Response of a New Zealand tree fern

Wanninayake, Seetha Podimenike

January 2007

Lead (Pb) pollution is a serious environmental problem. Phytoremediation is emerging as a promising technology for removal of Pb and other heavy metals from soils and waterways. In this study, the phytoremediation potential of a popular landscape plant, in New Zealand, Cyathea medullaris (the black tree fern), was investigated. Pb uptake by the gametophytes and different parts (roots, shoots and leaves) of 3-month-old black tree fern plants in hydroponic experiments were studied using flame atomic absorption spectrometry. Morphological and ultrastructural changes in the Pb-treated materials were also investigated. Generally, the levels of Pb in the various black tree fern tissues increased with the external Pb concentration and exposure time. Transmission electron microscopy observation showed that the cell wall was the major subcellular site for Pb accumulation. Evidence obtained here suggests that the black tree fern gametophytes and the sporophyte can accumulate levels of Pb exceeding 1% of their dry weights. This resembles the capacity of a hyperaccumulating plant.

Lead

ferns

gametophytes

hyperaccumulation

Cardiovascular effects of lead and mercury and their mixtures in rats

2015 April 1900

Cardiovascular diseases are the major cause of death worldwide. It is a group of diseases, which affect the heart, the vasculature and the brain. Lifestyle and metabolic risk factors are major contributors to cardiovascular ill-health. In addition to these risk factors, a growing number of scientific studies show that some environmental pollutants, e.g. lead and mercury, can adversely affect cardiovascular health. Despite the increasing amount of knowledge from human and animal studies, cardiovascular effects of lead, mercury species or their mixtures are not well understood. It is also unknown if safe exposure thresholds for these metals exist or the underlying mechanisms of action for the elicitation of cardiovascular toxicity. The first set of studies had the objectives to elucidate the range of effects of single exposure to lead, inorganic mercury or methylmercury on the cardiovascular system. Therefore, male Wistar rats were exposed to a broad range of doses of lead, inorganic mercury or methylmercury for four weeks through the drinking water. Cardiovascular health of the rats was assessed by measuring the blood pressure and the cardiac electrical activity after four weeks of exposure, while the heart function and blood flow in the carotid artery was measured at baseline and at the end of the exposure duration. The study showed that all three metals differ in their effects on the cardiovascular system. Lead showed bi-phasic dose-response curves for several cardiovascular end-points. No cardiovascular effects were observed for inorganic mercury, while methylmercury showed linear dose-response curves. Based on these results, safe levels of exposure for lead and methylmercury were derived. The second study applied the same experimental design as the previous study in order to investigate the cardiovascular effects of combined exposures to lead, inorganic mercury and methylmercury. The mixture ratios were based on reference and exposure values published in the scientific literature. The adverse cardiovascular effects, which were observed for single exposures were reversed for the mixtures indicating antagonism. In contrast to single exposures, mixtures negatively affected the electrical activity of the heart (synergism), which could lead to arrhythmias and heart failure. The third set of studies focused on the exploration of oxidative stress, kidney function and damage, and global DNA methylation as potential mechanisms of action for the development of elevated blood pressure. Results for lead showed an increase in oxidative stress but not mercury. While only lead was associated with kidney damage, only inorganic mercury was related to altered global DNA methylation. Methylmercury appears to elevate blood pressure through a not investigated mechanism. Therefore, oxidative stress and kidney damage seem to be associated with elevated blood pressure but not global DNA methylation. Overall, the research presented in this thesis shows that lead, inorganic mercury and methylmercury and their mixtures have the ability to adversely affect the cardiovascular system. However, each metal affected the cardiovascular system differently and surprisingly, mixtures showed antagonism or synergism depending on the examined end-point, which was reflected in the results of the mechanistic study. As health problems of the cardiovascular system, e.g. hypertension, occur mainly in the adult population and in particular the elderly, cardiovascular effects should be considered as an important end-point for this age group in addition to neurodevelopmental effects in children.

Mercury

lead

cardiovascular

mixtures

Some studies on lead dioxide

Munasiri, B.

January 1977

No description available.

669

Lead battery corrosion

An investigation into the effects of chronic lead exposure hypertension, and ethanol on the susceptibility of the rat heart to arrhythmias induced by myocardial ischaemia

Evis, M. J.

January 1987

No description available.

615.9

Toxicity of lead in Rats

Application of lead isotope analysis to provenance studies in archaeology

Stos-Gale, Zofia

January 1992

Advances in mass spectrometry in the second half of this century allowed very accurate measurements of isotopic compositions of various elements. In turn it was discovered that due to the radiogenic origin of some of these isotopes their composition often reflects the geochemical history of minerals and rocks. Terrestrial lead is composed of four isotopes, of which three are radiogenic in origin as daughters of uranium and thorium. In geochronology the isotopic composition of minerals helps in dating the ore and rock formations. However, if there is enough diversity amongst the isotopic compositions of different deposits, then their lead isotope composition can be used as a simple and unique 'fingerprint', which can be scientifically measured. This feature can be used as a powerful tool in the identification of sources of ancient metals, because it passes unchanged through the smelting and refining processes. However, one of the most important requirements for such 'lead isotope provenance studies' is empirical investigation of the 'fingerprints' of ore deposits which are relevant to a given archaeological research. In this dissertation the scientific foundations of lead isotope provenance studies are described and examined in detail. All available evidence concerning the possibility of distinguishing isotopically between different European ore deposits is examined and methods of visual and numerical evaluation of the lead isotope data are suggested. Two examples of applications to specific archaeological problems are also given: the identification of sources of metals used for production of Bronze Age Cretan weapons and of non-ferrous metals in the Roman Period in Southern Poland. The interpretation of lead isotope data for archaeological objects is based on nearly 1500 isotopic analyses of ores.

930.1

Lead : Isotopes : Archaeometry

Lead tetraacetate oxidation of oximes.

Dahl, Klaus Joachim.

January 1966

No description available.

Oximes.

Lead tetraacetate.

Oxidation

Synthetic studies towards potential lead(II) specific fluorescent probes / by John Vic Valente.

Valente, John Vic

January 1998

Bibliography: leaves 177-181. / v, 181 leaves : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Chemistry, 1999

Lead Toxicology

Fluorescent probes.

Investigations into Lead (Pb) Accumulation in Symphytum officinale L.: A Phytoremediation Study

Chin, Lily

January 2007

Lead (Pb) is the number one heavy metal pollutant in the environment. The high cost and environmental concerns of conventional remediation technologies has led to an emerging alternative technology for heavy metal remediation: phytoremediation. This study was set out to advance Pb phytoremediation by investigating plant-associated factors (e.g. polyphenol levels, Pb-tannin chelation, and superoxide dismutase activity) and chemical-based factors (e.g. concentration of Pb, and the type and dosage of chelating agents in treatments) that may affect Pb accumulation. Using a hydroponic system, sand-grown Symphytum officinale L. plants were exposed to nutrient solutions with or without lead nitrate (Pb(NO₃)₂) and ethylenediamine tetraacetic acid (EDTA). Using flame atomic absorption spectroscopy (to measure Pb content) and bovine serum albumin-protein precipitation (to measure polyphenol and tannin levels), a significant in vivo correlation between tannin level and Pb accumulation level was observed in roots of plants exposed to all Pb treatments. Higher tannin containing-lateral roots accumulated significantly more Pb than lowertannin main roots. Transmission electron micrographs of unchelated Pb-treated plants supported these findings, whilst dialysis-based in vitro Pb-chelation studies with crude S. officinale root polyphenol extracts did not. The dialysis method was likely to be subject to fructan interference. A new, more accurate and simple method based on tannin immobilisation was consequently developed. Results using this method supported the hydroponic trends. This new method was also verified with purified tannic acid (from Sigma). Together, these findings demonstrate that S. officinale root tannins have the ability to chelate Pb. This may be a mechanism to cope with Pb stress (adaptive tolerance). Despite the typical signs of Pb stress at root level (e.g. root growth inhibition, and degraded cytoplasms), shoots showed no signs of stress under any Pb treatments. Most importantly, since this chelation-based tolerance mechanism also influences the accumulation levels, the phytochemical composition of plants should also be considered when screening plants for phytoremediation. The level of Pb accumulated in the shoots depended on the concentration of Pb(NO₃)₂ and presence of chelating agents (EDTA or N-[2 acetamido] iminodiacetic acid (ADA)) in the nutrient solution. The highest level of Pb in shoots was between 0.05-0.06% (d.w. on average) using EDTA or ADA, well short of the 1% (d.w.) shoot accumulation target for Pb phytoextraction. The highest level of Pb in the roots (and of all measurements) was with unchelated 500 µM Pb(NO₃)₂; on average 2% (d.w.) accumulated in root. Overall, since S. officinale accumulated Pb predominately in the roots, it is most suited for rhizofiltration and phytostabilisation. Whilst chelating agents enhanced Pb accumulation in shoots, root levels were unexpectedly reduced compared to unchelated Pb treatments. The level of Pb translocated did not completely account for this loss. Minor factors relating to EDTA desorption of roots, EDTA specificity, and charge repulsion of the PbEDTA complex may account for some of the loss, but the main cause remains unclear. In vitro S. officinale cultures were developed and somaclonal variation (involving Pb pre-treatment of petioles) was used as a tool to further investigate, and attempt to improve its Pb phytoremediation potential. The shoots and roots of plants produced from petioles pre-treated with Pb(NO₃)₂ appeared more stressed than those without Pb pre-treatment. After re-treatment with Pb (Pb(NO₃)₂ or PbADA), plants developed from most Pb pre-treated petioles appeared to have reduced Pb accumulation and polyphenol levels, and increased superoxide dismutase activity in roots (although no statistically significant trends were found). Overall, plants produced from Pb pre-treated petioles in this study may have less phytoremediation potential.

Symphytum officinale

phytoremediation

lead