The impact of silver nanoparticles on marine plankton dynamics: Dependence on coating, size and concentration.

During this study, three microcosm experiments were carried out with natural coastal seawater, collected in the Eastern Mediterranean Sea, in order to assess the effect of silver nanoparticle (AgNP) exposure to natural plankton communities. The impact of coating (branched-polyethyleneimine: BPEI vs. poly-vinylpyrrolidone: PVP), size (40 vs. 60nm), concentration (200, 500, 2000, 5000 and 10,000ng Ag L-1) and silver form (dissolved Ag+ vs. AgNPs) were tested. The results of chlorophyll a concentration revealed that PVP AgNPs caused a higher toxicity than BPEI AgNPs, and this was possibly related to the measured higher dissolution rate. Additionally, toxicity of BPEI AgNPs was size-dependent, with 40 being more toxic than 60 nm AgNPs, which was nevertheless not seen clearly for PVP AgNPs. Interestingly, community composition altered in response to AgNP exposure: cyanobacterial abundance was negatively affected at concentrations ≥200ng Ag L-1, and dinoflagellate abundance and composition were altered at a 2000ng Ag L-1 concentration. Specifically, dinoflagellate (Gymnodinium, Prorocentrum and Gyrodinium) and diatom (Nitzschia, Navicula and Climacosphenia) genera either increased or decreased, highlighting taxa-specific effects, with some of them being able to tolerate, compensate or even benefit from AgNPs. Silver in either form (dissolved Ag+ or in NPs) caused almost identical results in the plankton community, further indicating that Ag+ release is the primary cause of AgNP toxicity. This study employed for the first time environmentally relevant AgNP concentrations (minimum 200ng Ag L-1) in natural seawater without pre-filtration steps and showed that community changes were driven by the exposure but were largely dependent on ambient physico-chemical characteristics and should be further investigated.

NMR investigation of the interaction of vanadate with carbasilatranes in aqueous solutions.

Reaction of vanadate with carbasilatranes [methoxy{N,N',N' '-2,2',3-[bis(1-methylethanolato)(propyl)]amino}silane (1), methoxy{N,N',N' '-2,2',3-[bis(1-ethanolethanolato)(propyl)]amino}silane (2), and {N,N',N' '-2,2',2-[bis(ethanolato)(glycolpropyl ether)]amino}silane (3)] in aqueous solution results in the formation of vanadosilicates and five-coordinated chelate vanadium(V) complexes as evidenced by 51V, 1H, and 13C NMR spectroscopy. Chiral carbasilatrane S,S-1 was characterized in the solid state by X-ray diffraction, revealing a trigonal bipyramidal geometry around the metal ion, with one unidentate methoxy group and one atrane nitrogen atom at the axial positions and one carbon and two atrane oxygen atoms at the equatorial plane of the bipyramid. Crystal data (Mo Kalpha; 100(2) K) are as follows: orthorhombic space group P2(1)2(1)2(1); a = 8.8751(6), b = 9.7031(7), c = 14.2263(12) A; Z = 4. The complexation of vanadium either with 1 or 2 is stereoselective yielding approximately 94% of the complex containing ligand in the S,R-configuration. The lower ability of the S,S- and R,R-diastereoisomers of 1 and 2 to ligate vanadate was attributed to stereochemical factors, dictating a square pyramidal geometry for the chelated complexes. A dynamic process between the vanadium chelate complexes and the respective carbasilatranes was evaluated by 2D {1H} EXSY NMR spectroscopy. These spectra show that the vanadate complexes with the open carbasilatranes exchange more slowly with the free ligand compared to the respective alcohol aminate complexes.