No effect of digestate amendment on Cs-137 and Sr-90 translocation in lysimeter experiments.

The soil-plant transfer of Cs-137 and Sr-90 in different crops was determined with respect to the present-day amendment practice of using digestate from biogas fermenters. The studies were performed using large lysimeters filled with undisturbed luvisol monoliths. In contrast to the conservative tracer, Br-, neither of the studied radionuclides showed a significant vertical translocation nor effect of the applied digestate amendment compared to a non-amended control was found. Furthermore, no significant plant uptake was measured for both nuclides in wheat or oat as indicated by the low transfer factors between soil-shoot for Cs-137 (TF 0.001-0.010) and for Sr-90 (0.10-0.51). The transfer into nutritionally relevant plant parts was even lower with transfer factors for soil-grain for Cs-137 (TF 0.000-0.001) and for Sr-90 (0.01-0.06). Hence, the amendment with biogas digestate is unfortunately not an option to further reduce plant uptake of these radionuclides in agricultural crops, but it does not increase plant uptake either.

Metal imaging on surface of micro- and nanoelectronic devices by laser ablation inductively coupled plasma mass spectrometry and possibility to measure at nanometer range.

An analytical mass spectrometric method for the elemental analysis of nano-bioelectronic devices involved in bioengineering research was developed and applied for measurements of selected metals (Au, Ti, Pt, Cr, etc.) on interdigitated electrode array chips (IDA-chip). An imaging laser ablation inductively coupled plasma mass spectrometric (LA-ICP-MS) procedure was used to map the elements of interest on the surface of the analyzed sample. The obtained images of metals were in a good agreement and corresponded to the micro- and nanofabricated metal electrode pattern. For the analysis at nanometer resolution scale a NF-LA-ICP-MS (NF-near-field) procedure was applied, which utilize thin Ag needle to enhance laser beam energy and improve spatial resolution of the method. The results show a approximately 100x enhancement of analyte signal, when the needle was positioned in the "near-field region" to the sample surface and the laser shot was performed. In addition, mass spectrometric studies of reproducibly for five separated NF-LA shots in different places of analyzed sample yielded an RSD of the measurement of 16%.

Near-field laser ablation inductively coupled plasma mass spectrometry: a novel elemental analytical technique at the nanometer scale.

An analytical technique utilizing a near-field effect (to enhance the incident light energy on the thin tip of an Ag needle) in a laser ablation inductively coupled plasma mass spectrometry (NF-LA-ICP-MS) procedure was developed. To produce the thin needles with a tip diameter in the hundreds of nm range a robust needle etching procedure was established. The 'sample-to-tip' distance was controlled via the measurement of a tunnel current between the needle and sample surface. The NF-LA-ICP-MS technique thus developed was applied for the analysis of copper isotopic standard reference material NIST SRM 976 and tungsten-molybdenum alloy NIST SRM 480 in the nm resolution range. The observed craters ranged from 200 nm to about 2 microm in diameter and were dependent on the needle used as well as on the 'sample-to-tip' distance. The mass spectrometric measurements of (63)Cu(+) ion intensity on NIST SRM 976 showed that using near-field enhancement in laser ablation allowed a roughly 6-fold increase in the ion intensity of the analyte when the needle was about 100 nm (and below) from the surface, in contrast to when it was far away (e.g. 10 microm) from the sample. The relative standard deviation (RSD) of the (65)Cu(+)/(63)Cu(+) isotopic ratio measurements by NF-LA-ICP-MS was 3.9% (n = 9). The detection efficiencies obtained for the compared LA-ICP-MS and NF-LA-ICP-MS methods were found to be 4.6 x 10(-3) counts per second (cps)/ablated atom and 2.7 x 10(-5) cps/ablated atom, respectively.

Element distribution is altered in a zone surrounding human glioblastoma multiforme.

Recent data indicate that A(1) adenosine receptor (A(1)AR) density is increased in a zone surrounding human and experimental gliomas. On the contrary, tumor tissue and adjacent brain tissue show low to intermediate A(1)AR densities. In order to assess whether changes in A(1)AR expression are indicating further processes of a chemical reorganization of the peritumoral zone, we investigated element concentrations and distribution patterns of copper and zinc in six human glioblastoma multiforme (GBM) specimens by laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS). Uranium and lead were used as external standards. Copper and zinc levels were increased in a peritumoral zone corresponding to the region of elevated A(1)AR density. They showed a lower density in the solid tumor in comparison to surrounding brain tissue, although the cellular density was higher within GBM. Our findings suggest that the immediate vicinity of GBM is characterized by increased levels of copper and zinc supporting the view that higher A(1)AR density surrounding GBM is not an isolated alteration of peritumoral tissue but an indicator of complex changes in the vicinity of infiltrative tumors. Further research is needed to explore the pathophysiological consequences of altered peritumoral element distribution.

Glia protects neurons against extracellular human neuromelanin.

BACKGROUND: Neuromelanin-containing neurons of the substantia nigra are highly vulnerable to degenerate in Parkinson's disease. Inhibition of the respiratory chain or formation of reactive oxygen species (ROS) by intracellular neuromelanin and triggering of inflammatory processes by extracellular neuromelanin emanating from melanized neurons after their demise are thought to be causally implicated in the high vulnerability of melanized neurons. OBJECTIVE: We addressed the direct effect of purified neuromelanin on mitochondrial complex I activity, and its influence on ROS production and survival of primary mesencephalic neurons in the presence or absence of glia. METHODS: Neuromelanin was isolated from midbrain of postmortem human brains. The content in iron and other elements was measured by inductively coupled mass spectrometry. The effect of neuromelanin on mitochondrial complex I activity was analyzed in post-nuclear extracts. Primary neuronal enriched and neuron-glia mixed cultures from midbrain were treated with different concentrations of neuromelanin. The generation of ROS was determined by fluorochrome detection. MAP2-positive and TH-positive neuronal viability was analyzed. RESULTS: Neuromelanin did not affect complex I activity, but concentration-dependently increased ROS production in neurons and reduced the number of MAP2-positive and TH-positive cultured neurons. Glia protected neurons against the neuromelanin toxicity. CONCLUSION: Extracellular neuromelanin is detrimental to neurons implicating a mechanism of intracellular ROS production, but not complex I inhibition. ROS formation may be catalyzed by iron, which was sensitively identified in purified neuromelanin (3.3 mg/g). Importantly, we demonstrate that glial cells have the potential to mitigate the neurotoxic effect of neuromelanin.

Depth profiling of Pu, 241Am and 137Cs in soils from southern Belarus measured by ICP-MS and alpha and gamma spectrometry.

The depth distribution of plutonium, americium, and 137Cs originating from the 1986 accident at the Chernobyl Nuclear Power Plant (NPP) was investigated in several soil profiles in the vicinity from Belarus. The vertical migration of transuranic elements in soils typical of the 30 km relocation area around Chernobyl NPP was studied using inductively coupled plasma mass spectrometry (ICP-MS), alpha spectrometry, and gamma spectrometry. Transuranic concentrations in upper soil layers ranged from 6 x 10(-12) g g(-1) to 6 x 10(-10) g g(-1) for plutonium and from 1.8 x 10(-13) g g(-1) to 1.6 x 10(-11) g g(-1) for americium. These concentrations correspond to specific activities of (239+240)Pu of 24-2400 Bq kg(-1) and specific activity of 241Am of 23-2000 Bq kg(-1), respectively. Transuranics in turf-podzol soil migrate slowly to the deeper soil layers, thus, 80-95%, of radionuclide inventories were present in the 0-3 cm intervals of turf-podzol soils collected in 1994. In peat-marsh soil migration processes occur more rapidly than in turf-podzol and the maximum concentrations are found beneath the soil surface (down to 3-6 cm). The depth distributions of Pu and Am are essentially identical for a given soil profile. (239+240)Pu/137Cs and 241Am/137Cs activity ratios vary by up to a factor of 5 at some sites while smaller variations in these ratios were observed at a site close to Chernobyl, suggesting that 137Cs is dominantly particle associated close to Chernobyl but volatile species of 137Cs are of relatively greater importance at the distant sites.