Simultaneous removal of pharmaceuticals and heavy metals from aqueous phase via adsorptive strategy: A critical review

The coexistence of pharmaceuticals and heavy metals is regarded as a serious threat to aquatic environments. Adsorbents have been widely applied to the simultaneous removal of pharmaceuticals and metals from aqueous phase. Through a comprehensive review, behaviors that promote, inhibit, or have no effect on simultaneous adsorption of pharmaceuticals and heavy metals were found to depend on the system of contaminants and adsorbents and their environmental conditions, such as: characteristics of adsorbent and pollutant, temperature, pH, inorganic ions, and natural organic matter. Bridging and competition effects are the main reasons for promoting and inhibiting adsorption in coexisting systems, respectively. The promotion is more significant in neutral or alkaline conditions. After simultaneous adsorption, a solvent elution approach was most commonly used for regeneration of saturated adsorbents. To conclude, this work could help to sort out the theoretical knowledge in this field, and may provide new insights into the prevention and control of pharmaceuticals and heavy metals coexisting in wastewater.

v-Src activates both protein kinase C-dependent and independent signaling pathways in murine fibroblasts

Activating the protein-tyrosine kinase activity of v-Src rapidly induced expression of the two 'primary response' genes, TIS10 and Egr-1, in Balb/c 3T3 cells. Depleting cells of protein kinase C (PKC) by prolonged exposure to 12-O-tetradecanoylphorbol 13-acetate (TPA), blocked v-Src-induced TIS10 expression, but had no effect on v-Src-induced Egr-1 gene expression. In addition, the induction of TIS10 and Egr-1 by v-Src could be distinguished using protein kinase inhibitors. Thus, v-Src induced gene expression in murine fibroblasts via two distinguishable signaling pathways: one dependent upon PKC and another that is independent of PKC. Consistent with the use of PKC-mediated signaling pathway by v-Src in murine fibroblasts, we found that activating the kinase activity of v-Src led to increased phosphorylation of a major PKC substrate. Thus, data presented here suggest that v-Src-induced transformation involves the activation of multiple signalling pathways, one of which requires PKC.