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Nanoparticles-A Thoracic Toxicology Perspective
Rodger Duffin,Nicholas L. Mills,Ken Donaldson 연세대학교의과대학 2007 Yonsei medical journal Vol.48 No.4
A substantial literature demonstrates that the main ultrafine particles found in ambient urban air are combustion-derived nanoparticles (CDNP) which originate from a number of sources and pose a hazard to the lungs. For CDNP, three properties appear important-surface area, organics and metals. All of these can generate free radicals and so induce oxidative stress and inflammation. Inflammation is a process involved in the diseases exhibited by the individuals susceptible to the effects of PM- development and exacerbations of airways disease and cardiovascular disease. It is therefore possible to implicate CDNP in the common adverse effects of increased PM. The adverse effects of increases in PM on the cardiovascular system are well-documented in the epidemiological literature and, as argued above, these effects are likely to be driven by the combustion-derived NP. The epidemiological findings can be explained in a number of hypotheses regarding the action of NP:-1) Inflammation in the lungs caused by NP causes atheromatous plaque development and destabilization; 2) The inflammation in the lungs causes alteration in the clotting status or fibrinolytic balance favouring thrombogenesis; 3) The NP themselves or metals/organics released by the particles enter the circulation and have direct effects on the endothelium, plaques, the clotting system or the autonomic nervous system/ heart rhythm. Environmental nanoparticles are accidentally produced but they provide a toxicological model for a new class of purposely ‘engineered’ NP arising from the nanotechnology industry, whose effects are much less understood. Bridging our toxicological knowledge between the environmental nanoparticles and the new engineered nanoparticles is a considerable challenge.
Cho, Wan-Seob,Thielbeer, Frank,Duffin, Rodger,Johansson, Emma M. V.,Megson, Ian L.,MacNee, William,Bradley, Mark,Donaldson, Ken Informa UK, Ltd. 2014 Nanotoxicology Vol.8 No.2
<P>Nano materials are commonly functionalized to boost their physicochemical properties. However, there is little known about the impact of these modifications on cellular systems. Herein, we synthesized eight types of polymeric nanoparticles (NPs) bearing different functional groups, and investigated their effects on interactions with cellular membranes. As models for particle membrane interactions, hemolysis assays using human red blood cells and culture with A549 cells were utilized. Under protein-free conditions, the NPs showed a wide distribution of zeta potentials (ζPs) which showed a good correlation with their hemolytic potential. However, in the presence of serum or lung lining fluid, the ζPs of all NPs coalesced towards a single common negative value and showed neither hemolytic activity nor cytotoxicity to A549 cells. Lipase and protease treatment of the coronated particles did not restore their reactivity. These result simply proves that particle functionalization influences the stability of the particle corona which, if intact, prevents hemolytic activity and membrane disrupture.</P>