Antonio Salluzzo

Suitability of lysosomal membrane stability in Eisenia fetida as biomarker of soil copper contamination

Accumulated metals in soils negatively affect dwelling organisms. Earthworms, which are widespread and perform various essential functions, are able to accumulate metals that can damage the coelomic cells. The aim of this work was to evaluate the effect on Eisenia fetida lysosomal membrane stability both during and after copper exposure, and finally to link this to internal concentrations. E. fetida specimens were exposed to a reference soil and two Cu-spiked soils (35 and 350 mg kg(-1) d.w.) for 14 days (uptake period) and then transferred into the reference soil for other 18 days (elimination period). After 3 days of uptake, internal Cu concentrations increased and were higher in the specimens exposed to soils spiked with 350 mg Cu kg(-1) d.w. After 2 days of elimination, a strong decrease of internal Cu concentrations was always observed. The lysosomal membrane stability, measured as neutral red retention-times, was approximately 50 min for the earthworms exposed to the reference soils, whereas it decreased, at the end of the uptake period, to 21 and 13 min, respectively, for the organisms exposed to soils spiked with 35 and 350 mg Cu kg(-1) d.w. A full recovery of the lysosomal membrane stability was reached after 14 and 18 days of the elimination period, respectively, for the organisms exposed to soils spiked with 35 and 350 mg Cu kg(-1) d.w. The neutral-red assay would seem a good biomarker since the lysosomal membrane stability of E. fetida appeared to respond rapidly and strongly to soil copper contamination.

Determination of Platinum Group Elements and Evaluation of Their Traffic-Related Distribution in Italian Urban Environments

Abstract The platinum (Pt) distribution in urban matrices, soils and dusts was studied in five cities, from north (Padova), central (Rome and Viterbo), and south (Naples and Palermo) Italy, in order to obtain a large set of data concerning pollution from autocatalysts. Quantitative analyses, made by inductively coupled plasma mass-spectroscopy (ICP-MS), show a beginning of Pt enrichment in urban soils, with concentration ranges of 0.1–5.7 ng/g (Padova), 7–19.4 ng/g (Rome), 4.9–20 ng/g (Viterbo), 4.7–14.3 ng/g (Naples), and 0.2–3.9 ng/g (Palermo). These results can be related to vehicular traffic, because the concentrations decrease with the distance from the roads. The high concentrations found in road and tunnel dusts (up to 1177 ng/g) confirm these samples as the major reserve of the particulate matter that is released with the exhaust fumes (which is responsible for the Pt enrichment). Qualitative analyses by laser-ablation-ICP-MS (LA-ICP-MS) were used, in addition, to determine the real presence of the catalyst particles in the urban dusts. The association of the analytical signals of cerium, platinum, and rhodium was used as a fingerprint to distinguish the catalyst particles from the other components of the urban dusts. The scanning electron microscopy (Energy Dispersive Spectrometer-Scanning Electron Microscope; EDS-SEM) qualitative analysis was also used to characterize the morphology of the autocatalyst and its related elemental distribution.

Experimental investigation to evaluate the potential environmental hazards of photovoltaic panels.

Recently the potential environmental hazard of photovoltaic modules together with their management as waste has attracted the attention of scientists. Particular concern is aroused by the several metals contained in photovoltaic panels whose potential release in the environment were scarcely investigated. Here, for the first time, the potential environmental hazard of panels produced in the last 30 years was investigated through the assessment of up to 18 releasable metals. Besides, the corresponding ecotoxicological effects were also evaluated. Experimental data were compared with the current European and Italian law limits for drinking water, discharge on soil and landfill inert disposal in order to understand the actual pollution load. Results showed that less than 3% of the samples respected all law limits and around 21% was not ecotoxic. By considering the technological evolutions in manufacturing, we have shown that during the years crystalline silicon panels have lower tendency to release hazardous metals with respect to thin film panels. In addition, a prediction of the amounts of lead, chromium, cadmium and nickel releasable from next photovoltaic waste was performed. The prevision up to 2050 showed high amounts of lead (30t) and cadmium (2.9t) releasable from crystalline and thin film panels respectively.