B. van Ravenzwaay scite author profile

The tissue distribution and toxicity of intravenously administered nanoparticles of titanium dioxide (TiO2) (>10 wt.% at <100 nm size) were investigated because of the fundamental importance to obtain information on the kinetics of this widely used nanoparticle in a situation of 100% bioavailability. Male Wistar rats were treated with single intravenous injections of a suspension of TiO2 in serum (5 mg/kg body weight), and the tissue content of TiO2 was determined 1, 14, and 28 days later. Biochemical parameters and antigens in serum were also assessed to determine potential pathological changes. The health and behavior of the animals were normal throughout the study. There were no detectable levels of TiO2 in blood cells, plasma, brain, or lymph nodes. The TiO2 levels were highest in the liver, followed in decreasing order by the levels in the spleen, lung, and kidney, and highest on day 1 in all organs. TiO2 levels were retained in the liver for 28 days, there was a slight decrease in TiO2 levels from day 1 to days 14 and 28 in the spleen, and a return to control levels by day 14 in the lung and kidney. There were no changes in the cytokines and enzymes measured in blood samples, indicating that there was no detectable inflammatory response or organ toxicity. Overall, rats exposed to TiO2 nanoparticles by a route that allows immediate systemic availability showed expected tissue distribution, no obvious toxic health effects, no immune response, and no change in organ function. Therefore, even with 100% bioavailability of the 5 mg/kg TiO2 dose afforded by the intravenous route of administration, there were no remarkable toxic effects evident in the experimental animals. These results indicate that TiO2 nanoparticles could be used safely in low doses.

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The in vitro absorption of microfine zinc oxide and titanium dioxide through porcine skin

Gamer¹,

Leibold²,

Ravenzwaay³

2006

Toxicology in Vitro

313

206

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Adverse outcome pathways: opportunities, limitations and open questions

et al. 2017

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Adverse outcome pathways (AOPs) are a recent toxicological construct that connects, in a formalized, transparent and quality-controlled way, mechanistic information to apical endpoints for regulatory purposes. AOP links a molecular initiating event (MIE) to the adverse outcome (AO) via key events (KE), in a way specified by key event relationships (KER). Although this approach to formalize mechanistic toxicological information only started in 2010, over 200 AOPs have already been established. At this stage, new requirements arise, such as the need for harmonization and re-assessment, for continuous updating, as well as for alerting about pitfalls, misuses and limits of applicability. In this review, the history of the AOP concept and its most prominent strengths are discussed, including the advantages of a formalized approach, the systematic collection of weight of evidence, the linkage of mechanisms to apical end points, the examination of the plausibility of epidemiological data, the identification of critical knowledge gaps and the design of mechanistic test methods. To prepare the ground for a broadened and appropriate use of AOPs, some widespread misconceptions are explained. Moreover, potential weaknesses and shortcomings of the current AOP rule set are addressed (1) to facilitate the discussion on its further evolution and (2) to better define appropriate vs. less suitable application areas. Exemplary toxicological studies are presented to discuss the linearity assumptions of AOP, the management of event modifiers and compensatory mechanisms, and whether a separation of toxicodynamics from toxicokinetics including metabolism is possible in the framework of pathway plasticity. Suggestions on how to compromise between different needs of AOP stakeholders have been added. A clear definition of open questions and limitations is provided to encourage further progress in the field.

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Toxico-/biokinetics of nanomaterials

et al. 2012

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Nanomaterials (NM) offer great technological advantages but their risks to human health are still under discussion. For toxicological testing and evaluation, information on the toxicokinetics of NM is essential as it is different from that of most other xenobiotics. This review provides an overview on the toxicokinetics of NM available to date. The toxicokinetics of NM depends on particle size and shape, protein binding, agglomeration, hydrophobicity, surface charge and protein binding. In most studies with topical skin application, unintentional permeation and systemic availability were not observed; permeation for some NM with distinct properties was observed in animals. Upon inhalation, low levels of primary model nanoparticles became systemically available, but many real-world engineered NM aggregate in aerosols, do not disintegrate in the lung, and do not become systemically available. NM are prone to lymphatic transport, and many NM are taken up by the mononuclear phagocyte system (MPS) acting as a depot. Their half-life in blood depends on their uptake by MPS rather than their elimination from the body. NM reaching the GI tract are excreted with the feces, but of some NM low levels are absorbed and become systemically available. Some quantum dots were not observably excreted in urine nor in feces. Some model quantum dots, however, were efficiently excreted by the kidneys below, but not above 5-6 nm hydrodynamic diameter, while nanotubes 20-30 nm thick and 500-2,000 nm long were abundant in urine. NM are typically not metabolized. Some NM cross the blood-brain barrier favored by a negative surface charge.

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Comparing fate and effects of three particles of different surface properties: Nano-TiO2, pigmentary TiO2 and quartz

et al. 2009

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B. van Ravenzwaay

Tissue distribution and toxicity of intravenously administered titanium dioxide nanoparticles in rats

The in vitro absorption of microfine zinc oxide and titanium dioxide through porcine skin

Adverse outcome pathways: opportunities, limitations and open questions

Toxico-/biokinetics of nanomaterials

Comparing fate and effects of three particles of different surface properties: Nano-TiO2, pigmentary TiO2 and quartz

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