Carbon paste electrodes modified with biosolids, soils and biocomposites utilized to study the interaction between organic matter and copper.

Carbon paste electrodes (CPEs) modified with a biosolid, two types of soils with different amounts of organic matter (OM), and two biocomposites (soils mixed with a biosolid) were used to assess and compare the Cu(II) ion retention properties of the organic matter contained in the samples. The accumulation of Cu(II) on the surface of the modified carbon paste electrodes (MCPEs) was performed under open-circuit conditions. When comparing the response of the MCPEs while assessing parameters such as pH, preconcentration time, and adsorption/desorption capacity, it was found that the reaction mechanism of the two soils is different between the soils and dissimilar from the biosolid; while the biocomposites show reaction mechanisms that are intermediate between those of the soils and the biosolid. This was proven with the use of infrared spectroscopy, since the FTIR spectra show similarities between the two soils and significant differences between the soils and the biosolid.

Changes in hippocampal NMDA-R subunit composition induced by exposure of neonatal rats to L-glutamate.

Overactivation of NMDA-Rs may mediate excitotoxic cell death associated with epileptic seizures, and hypoxic-ischemic conditions. We assessed whether repeated subcutaneous administration of l-glutamate to neonatal rats affects the subunit composition of NMDA-Rs. Accordingly, cortical and hippocampal tissue from 14-day-old rats was analyzed by Western blotting and RT-PCR to quantify the protein and mRNA expression of different NMDA-R subunits. In addition, tissue sections were Nissl stained to assess the cell damage in this tissue. Early exposure of neonatal rats to L-glutamate differentially affects the expression of mRNA transcripts for NMDA-R subunits in the cerebral cortex and hippocampus. In the cerebral cortex, a decrease in NR2B subunit mRNA expression was observed, as well as a loss of NR1 and NR2A protein. By contrast, neonatal L-glutamate administration augmented the transcripts encoding the NR1, NR2B, and NR2C subunits in the hippocampal formation. The expression of mRNA encoding the NR2A subunit was not affected by neonatal L-glutamate administration in either of the brain regions examined. This differential expression of NMDA-R subunits following neonatal exposure to L-glutamate may represent an adaptive response of the glutamate receptors to overactivation in order to reduce the effect of high L-glutamate during the early period of life when the animal is more vulnerable to excitotoxicity.