Impact of artificial digestion on the sizes and shapes of microplastic particles.

Current analyses show a widespread occurrence of microplastic particles in food products and raise the question of potential risks to human health. Plastic particles are widely considered to be inert due to their low chemical reactivity and therefore supposed to pose, if at all only minor hazards. However, variable physicochemical conditions during the passage of the gastrointestinal tract gain strong importance, as they may affect particle characteristics. This study aims to analyze the impact of the gastrointestinal passage on the physicochemical particle characteristics of the five most produced and thus environmentally relevant plastic materials polyethylene, polypropylene, polyvinyl chloride, polyethylene terephthalate and polystyrene. Scanning electron microscopy (SEM) and subsequent image analysis were employed to characterize microplastic particles. Our results demonstrate a high resistance of all plastic particles to the artificial digestive juices. The present results underline that the main stages of the human gastrointestinal tract do not decompose the particles. This allows a direct correlation between the physicochemical particle characteristics before and after digestion. Special attention must be paid to the adsorption of organic compounds like proteins, mucins and lipids on plastic particles since it could lead to misinterpretations of particle sizes and shapes.

Formation mechanism of colloidal silver nanoparticles: analogies and differences to the growth of gold nanoparticles.

The formation mechanisms of silver nanoparticles using aqueous silver perchlorate solutions as precursors and sodium borohydride as reducing agent were investigated based on time-resolved in situ experiments. This contribution addresses two important issues in colloidal science: (i) differences and analogies between growth processes of different metals such as gold and silver and (ii) the influence of a steric stabilizing agent on the growth process. The results reveal that a growth due to coalescence is a fundamental growth principle if the monomer-supplying chemical reaction is faster than the actual particle formation.

On the influence of different surfaces in nano- and submicrometer particle based fluorescence immunoassays.

Recently, numerous attempts have been made to improve the performance of fluorescence immunoassays. One way pursued is the substitution of labeling molecules by micro- or nanocrystalline dyes. The surfaces of these particulate structures are typically engineered by a layerwise assembly of oppositely charged polyelectrolytes, the outer layer being constituted of biorecognition molecules, for example, immunoglobulins. In this study, we show that amphiphilic polymers such as alkylated poly(ethylene imine)s and 1,2-distearoyl-sn-glycero-3-phosphatoethanolamine-N-[amino(poly(ethylene glycol))] can fully substitute the more intricate layer-by-layer technique and evaluate the influence of surface charge and particle size on the overall performance of these assays.