Comparative pulmonary toxicity of inhaled nickel nanoparticles; role of deposited dose and solubility.

In this pilot study, we investigated which physicochemical properties of nickel hydroxide nanoparticles (nano-NH) were mainly responsible in inducing pulmonary toxicity. First, we studied the role of nickel ions solubilized from nano-NH by comparing the toxic effects of nano-NH to those of readily soluble nickel sulfate nanoparticles (nano-NS). Additionally, to test whether there was a non-specific stress response due to particle morphology, we compared the toxicity of nano-NH with that of carbon nanoparticles (nano-C) and titanium dioxide nanoparticles (nano-Ti), both of which had similar physical properties such as particle size and shape, to nano-NH. We exposed mice to each type of nanoparticles for 4?h via a whole-body inhalation system and examined oxidative stress and inflammatory responses in the lung. We also determined the lung burden and clearance of Ni following nano-NH and nano-NS exposures. The results showed that lung deposition of nano-NH was significantly greater than that of nano-NS and nano-NH appeared to have stronger inflammogenic potential than nano-NS even when lung Ni burden taken into consideration. This suggests that the toxicity of nano-NH is not driven solely by released Ni ions from deposited nano-NH particles. However, it is unlikely that the greater toxic potential of nano-NH is attributable to a generic stress response from any nanoparticle exposure, since nano-C and nano-Ti did not elicit toxic responses similar to those of nano-NH. These results indicate that the observed pulmonary toxicity by inhaled nano-NH were chemical-specific and deposited dose and solubility are key factors to understand toxicity induced by nano-NH.

Inhaled nickel nanoparticles alter vascular reactivity in C57BL/6 mice.

BACKGROUND: The use of nanoparticles (NPs) in technological applications is rapidly expanding, but the potential health effects associated with NP exposure are still largely unknown. Given epidemiological evidence indicating an association between inhaled ambient ultrafine particles and increased risk of cardiovascular disease morbidity and mortality, it has been suggested that exposure to NPs via inhalation may induce similar cardiovascular responses. METHODS: Male C57BL/6 mice were exposed via whole-body inhalation to either filtered air (FA) or nickel hydroxide (NH) NPs (100, 150, or 900 µg/m(3)) for 1, 3, or 5 consecutive days (5 h/day). At 24-h post-exposure, vascular function in response to a vasoconstrictor, phenylephrine (PE), and a vasodilator, acetylcholine (ACh), was measured in the carotid artery. RESULTS: Carotid arteries from mice exposed to all concentrations of NH-NPs showed statistically significant differences in graded doses of PE-induced contractile responses compared with those from FA mice. Similarly, vessels from NH-NP-exposed mice also demonstrated impaired vasorelaxation following graded doses of ACh as compared with FA mice. CONCLUSIONS: These results suggest that short-term exposure to NH-NPs can induce acute endothelial disruption and alter vasoconstriction and vasorelaxation. These findings are consistent with other studies assessing vascular tone and function in the aorta, coronary, and mesenteric vessels from mice exposed to motor vehicular exhaust and concentrated ambient particles.

Exposure to inhaled nickel nanoparticles causes a reduction in number and function of bone marrow endothelial progenitor cells.

INTRODUCTION: Particulate matter (PM), specifically nickel (Ni) found on or in PM, has been associated with an increased risk of mortality in human population studies and significant increases in vascular inflammation, generation of reactive oxygen species, altered vasomotor tone, and potentiated atherosclerosis in murine exposures. Recently, murine inhalation of Ni nanoparticles have been shown to cause pulmonary inflammation that affects cardiovascular tissue and potentiates atherosclerosis. These adverse cardiovascular outcomes may be due to the effects of Ni on endothelial progenitor cells (EPCs), endogenous semi-pluripotent stem cells that aid in endothelial repair. Thus, we hypothesize that Ni nanoparticle exposures decrease cell count and cause impairments in function that may ultimately have significant effects on various cardiovascular diseases, such as, atherosclerosis. METHODS: Experiments involving inhaled Ni nanoparticle exposures (2 days/5 h/day at ∼1200 µg/m(3), 3 days/5 h/day at ∼700 µg/m(3), and 5 days/5 h/day at ∼100 µg/m(3)), were performed in order to quantify bone marrow resident EPCs using flow cytometry in C57BL/6 mice. Plasma levels of human stromal cell-derived factor 1α (SDF-1α) and vascular endothelial growth factor (VEGF) were assessed by enzyme-linked immunosorbent assay and in vitro functional assessments of cultured EPCs were conducted. RESULTS AND CONCLUSIONS: Significant EPC count differences between exposure and control groups for Ni nanoparticle exposures were observed. Differences in EPC tube formation and chemotaxis were also observed for the Ni nanoparticle exposed group. Plasma VEGF and SDF-1α differences were not statistically significant. In conclusion, this study shows that inhalation of Ni nanoparticles results in functionally impaired EPCs and reduced number in the bone marrow, which may lead to enhanced progression of atherosclerosis.

Developmental neurotoxicity of engineered nanomaterials: identifying research needs to support human health risk assessment.

Increasing use of engineered nanomaterials (ENM) in consumer products and commercial applications has helped drive a rise in research related to the environmental health and safety (EHS) of these materials. Within the cacophony of information on ENM EHS to date are data indicating that these materials may be neurotoxic in adult animals. Evidence of elevated inflammatory responses, increased oxidative stress levels, alterations in neuronal function, and changes in cell morphology in adult animals suggests that ENM exposure during development could elicit developmental neurotoxicity (DNT), especially considering the greater vulnerability of the developing brain to some toxic insults. In this review, we examine current findings related to developmental neurotoxic effects of ENM in the context of identifying research gaps for future risk assessments. The basic risk assessment paradigm is presented, with an emphasis on problem formulation and assessments of exposure, hazard, and dose response for DNT. Limited evidence suggests that in utero and postpartum exposures are possible, while fewer than 10 animal studies have evaluated DNT, with results indicating changes in synaptic plasticity, gene expression, and neurobehavior. Based on the available information, we use current testing guidelines to highlight research gaps that may inform ENM research efforts to develop data for higher throughput methods and future risk assessments for DNT. Although the available evidence is not strong enough to reach conclusions about DNT risk from ENM exposure, the data indicate that consideration of ENM developmental neurotoxic potential is warranted.

Pulmonary response after exposure to inhaled nickel hydroxide nanoparticles: short and long-term studies in mice.

Short and long-term pulmonary response to inhaled nickel hydroxide nanoparticles (nano-Ni(OH)(2), CMD = 40 nm) in C57BL/6 mice was assessed using a whole body exposure system. For short-term studies mice were exposed for 4 h to nominal concentrations of 100, 500, and 1000 mg/m(3). For long-term studies mice were exposed for 5 h/d, 5 d/w, for up to 5 months (m) to a nominal concentration of 100 mg/m(3). Particle morphology, size distribution, chemical composition, solubility, and intrinsic oxidative capacity were determined. Markers of lung injury and inflammation in bronchoalveolar lavage fluid (BALF); histopathology; and lung tissue elemental nickel content and mRNA changes in macrophage inflammatory protein-2 (Mip-2), chemokine ligand 2 (Ccl2), interleukin 1-alpha (Il-1α), and tumor necrosis factor-alpha (Tnf-α) were assessed. Dose-related changes in BALF analyses were observed 24 h after short-term studies while significant changes were noted after 3 m and/or 5 m of exposure (24 h). Nickel content was detected in lung tissue, Ccl2 was most pronouncedly expressed, and histological changes were noted after 5 m of exposure. Collectively, data illustrates nano-Ni(OH)(2) can induce inflammatory responses in C57BL/6 mice.