Mary C. Buford

Particle length-dependent titanium dioxide nanomaterials toxicity and bioactivity

BackgroundTitanium dioxide (TiO2) nanomaterials have considerable beneficial uses as photocatalysts and solar cells. It has been established for many years that pigment-grade TiO2 (200 nm sphere) is relatively inert when internalized into a biological model system (in vivo or in vitro). For this reason, TiO2 nanomaterials are considered an attractive alternative in applications where biological exposures will occur. Unfortunately, metal oxides on the nanoscale (one dimension < 100 nm) may or may not exhibit the same toxic potential as the original material. A further complicating issue is the effect of modifying or engineering of the nanomaterial to be structurally and geometrically different from the original material.ResultsTiO2 nanospheres, short (< 5 μm) and long (> 15 μm) nanobelts were synthesized, characterized and tested for biological activity using primary murine alveolar macrophages and in vivo in mice. This study demonstrates that alteration of anatase TiO2 nanomaterial into a fibre structure of greater than 15 μm creates a highly toxic particle and initiates an inflammatory response by alveolar macrophages. These fibre-shaped nanomaterials induced inflammasome activation and release of inflammatory cytokines through a cathepsin B-mediated mechanism. Consequently, long TiO2 nanobelts interact with lung macrophages in a manner very similar to asbestos or silica.ConclusionsThese observations suggest that any modification of a nanomaterial, resulting in a wire, fibre, belt or tube, be tested for pathogenic potential. As this study demonstrates, toxicity and pathogenic potential change dramatically as the shape of the material is altered into one that a phagocytic cell has difficulty processing, resulting in lysosomal disruption.

A comparison of dispersing media for various engineered carbon nanoparticles

BackgroundWith the increased manufacture and use of carbon nanoparticles (CNP) there has been increasing concern about the potential toxicity of fugitive CNP in the workplace and ambient environment. To address this matter a number of investigators have conducted in vitro and in vivo toxicity assessments. However, a variety of different approaches for suspension of these particles (culture media, Tween 80, dimethyl sulfoxide, phosphate-buffered saline, fetal calf serum, and others), and different sources of materials have generated potentially conflicting outcomes. The quality of the dispersion of nanoparticles is very dependent on the medium used to suspend them, and this then will most likely affect the biological outcomes.ResultsIn this work, the distributions of different CNP (sources and types) have been characterized in various media. Furthermore, the outcome of instilling the different agglomerates, or size distributions, was examined in mouse lungs after one and seven days. Our results demonstrated that CNP suspended in serum produced particle suspensions with the fewest large agglomerates, and the most uniform distribution in mouse lungs. In addition, no apparent clearance of instilled CNP took place from lungs even after seven days.ConclusionThis work demonstrates that CNP agglomerates are present in all dispersing vehicles to some degree. The vehicle that contains some protein, lipid or protein/lipid component disperses the CNP best, producing fewer large CNP agglomerates. In contrast, vehicles absent of lipid and protein produce the largest CNP agglomerates. The source of the CNP is also a factor in the degree of particle agglomeration within the same vehicle.

Prostaglandin I2-IP Signaling Blocks Allergic Pulmonary Inflammation by Preventing Recruitment of CD4+ Th2 Cells into the Airways in a Mouse Model of Asthma

PGI2 plays a key role in limiting Th2-mediated airway inflammation. In studies to investigate the mechanism underlying such regulation, we found that the PGI2 receptor, IP, is preferentially expressed by effector CD4+ Th2 cells, when compared with Th1 cells. Adoptive transfer of DO11.10 Th2 cells pretreated with PGI2 resulted in considerably attenuated pulmonary inflammation and airway hyperreactivity in BALB/c recipient mice in response to OVA inhalation. This suppression was independent of increased cAMP levels, because pretreatment of Th2 cells with dibutyryl cAMP before transfer had no effect on airway inflammation. Moreover, PGI2 pretreatment of Th2 cells suppressed the ability of the cells to infiltrate the lungs but not the spleen. In vitro studies showed that PGI2 did not affect IL-4 and IL-5 production or the level of IFN-γ by the T cells. However, the prostanoid strongly inhibited CCL17-induced chemotaxis of CD4+ Th2 but not Th1 cells. The IP was implicated in this process since migration of wild-type Th2 cells in response to CCL17 was markedly reduced following treatment with PGI2, whereas IP-deficient Th2 cells were unaffected and migrated effectively. Collectively, these experiments suggest that PGI2, which is generated by endothelial cells during lung inflammatory response, serves to limit the influx of Th2 cells to the airways. Our results identify PGI2-IP as an important pathway for inhibiting allergic pulmonary inflammation by controlling recruitment of CD4+ Th2 cells into the inflammatory site.

Elevated Asymmetric Dimethylarginine Alters Lung Function and Induces Collagen Deposition in Mice

Increasing evidence suggests that lung mechanics and structure are maintained in part by an intimate balance between the L-arginine-metabolizing enzymes nitric oxide synthase (NOS) and arginase. Asymmetric dimethylarginine (ADMA) is a competitive endogenous inhibitor of NOS. The role of ADMA in the regulation of NOS and arginase in the airways has not yet been explored. Our objective was to investigate the role of ADMA in lung physiology. A murine model of continuous subcutaneous ADMA infusion via osmotic minipump was used for assessment of elevated ADMA in vivo, and primary lung fibroblasts were used for in vitro assessments. Two weeks after minipump placement, animals were anesthetized and mechanically ventilated, and lung mechanical responses were evaluated. Lungs were assessed histologically and biochemically for collagen content, arginase activity, and arginase protein levels. Lung lavage fluid was assessed for cellularity, nitrite, urea, and cytokine concentrations. ADMA infusion resulted in significantly enhanced lung resistance and decreased dynamic compliance in response to methacholine. These physiologic changes were associated with significantly increased lung collagen content in the absence of inflammation. Significant decreases in lung fluid nitrite were accompanied by elevated lung fluid urea and arginase activity in lung homogenates. These changes were reversed in mice 4 weeks after completion of ADMA administration. In addition, treatment of primary mouse lung fibroblasts with ADMA stimulated arginase activity and collagen formation in vitro. These data support the idea that ADMA may play a role in airway diseases, including asthma and pulmonary fibrosis, through NOS inhibition and enhancement of arginase activity.

NLRP3 inflammasome activation in murine alveolar macrophages and related lung pathology is associated with MWCNT nickel contamination

Multi-walled carbon nanotubes (MWCNT) have been reported to cause lung pathologies in multiple studies. However, the mechanism responsible for the bioactivity has not been determined. This study used nine different well-characterized MWCNT and examined the outcomes in vitro and in vivo. MWCNT, from a variety of sources that differed primarily in overall purity and metal contaminants, were examined for their effects in vitro (toxicity and NLRP3 inflammasome activation using primary alveolar macrophages isolated from C57Bl/6 mice). In addition, in vivo exposures were conducted to determine the inflammatory and pathogenic potency. The particles produced a differential magnitude of responses, both in vivo and in vitro, that was associated most strongly with nickel contamination on the particle. Furthermore, the mechanism of action for the Ni-contaminated particles was in their ability to disrupt macrophage phagolysosomes, which resulted in NLRP3 activation and subsequent cytokine release associated with prolonged inflammation and lung pathology.

The IL-4Rα pathway in macrophages and its potential role in silica-induced pulmonary fibrosis

Crystalline silica exposure can result in pulmonary fibrosis, where the pulmonary macrophage is key as a result of its ability to react to silica particles. In the mouse silicosis model, there is initial Th1‐type inflammation, characterized by TNF‐α and IFN‐γ. Previous studies determined that Th2 mediators (i.e., IL‐13) are vital to development of pulmonary fibrosis. The present study, using in vivo and in vitro techniques, compares silica exposures between Balb/c and Th2‐deficient mice in an effort to determine the link between Th2 immunity and silicosis. In long‐term experiments, a significant increase in fibrosis and activated interstitial macrophages was observed in Balb/c but not IL‐4Rα−/− mice. Additionally, a significant increase in Ym1 mRNA levels, a promoter of Th2 immunity, was determined in the interstitial leukocyte population of silica‐exposed Balb/c mice. To elucidate the effects of silica on macrophage function, bone marrow‐derived macrophages (BMdM) were exposed to particles and assayed for T cell (TC) stimulation activity. As a control, Ym1 mRNA expression in Balb/c BMdM was determined using IL‐4 stimulation. In the in vitro assay, a significant increase in TC activation, as defined by surface markers and cytokines, was observed in the cultures containing the silica‐exposed macrophages in wild‐type and IL‐4Rα−/− mice, with one exception: IL‐4Rα−/− BMdM were unable to induce an increase in IL‐13. These results suggest that crystalline silica alters cellular functions of macrophages, including activation of TC, and that the increase in Th2 immunity associated with silicosis is via the IL‐4Rα‐Ym1 pathway.

Asymmetric dimethylarginine potentiates lung inflammation in a mouse model of allergic asthma

Nitric oxide (NO), formed by nitric oxide synthase (NOS), is an important mediator of lung inflammation in allergic asthma. Asymmetric dimethylarginine (ADMA), a competitive endogenous inhibitor of NOS, is metabolized by the enzyme dimethylarginine dimethylaminohydrolase (DDAH). Elevated ADMA has been shown to affect lung function in mice, and by inhibiting NOS it alters NO and reactive oxygen species production in mouse lung epithelial cells. However, the effects of altered ADMA levels during lung inflammation have not been explored. A model of allergen-induced airway inflammation was utilized in combination with the modulation of endogenous circulating ADMA levels in mice. Airway inflammation was assessed by quantifying inflammatory cell infiltrates in lung lavage and by histology. Lung DDAH expression was assessed by quantitative PCR and immunohistochemistry. Nitrite levels were determined in lung lavage fluid as a measure of NO production. iNOS expression was determined by immunohistochemistry, immunofluorescence, Western blot, and quantitative PCR. NF-κB binding activity was assessed by a transcription factor binding assay. Allergen-induced lung inflammation was potentiated in mice with elevated circulating ADMA and was reduced in mice overexpressing DDAH. Elevated ADMA reduced nitrite levels in lung lavage fluid in both allergen-challenged and control animals. ADMA increased iNOS expression in airway epithelial cells in vivo following allergen challenge and in vitro in stimulated mouse lung epithelial cells. ADMA also increased NF-κB binding activity in airway epithelial cells in vitro. These data support that ADMA may play a role in inflammatory airway diseases such as asthma through modulation of iNOS expression in lung epithelial cells.

IL-1R signalling is critical for regulation of multi-walled carbon nanotubes-induced acute lung inflammation in C57Bl/6 mice

Abstract Exposure to certain engineered nanomaterials has been associated with pathological changes in animal models raising concerns about potential human health effects. MWCNT have been reported to activate the NLRP3 inflammasome in vitro, correlating with lung inflammation and pathology, in vivo. In this study, we investigated the role of IL-1 signalling in pulmonary inflammatory responses in WT and IL-1R-/- mice after exposure to MWCNT. The results suggest that MWCNT were effective in inducing acute pulmonary inflammation. Additionally, WT mice demonstrated significant increased airway resistance 24 h post exposure to MWCNT, which was also blocked in the IL-1R-/- mice. In contrast, by 28 days post exposure to MWCNT, the inflammatory response that was initially absent in IL-1R-/- mice was elevated in comparison to the WT mice. These data suggest that IL-1R signalling plays a crucial role in the regulation of MWCNT-induced pulmonary inflammation.

Engineered carbon nanoparticles alter macrophage immune function and initiate airway hyper-responsiveness in the BALB/c mouse model

With the mass production of fullerenes currently underway, and the mass production of carbon nanotubes soon to follow, only a few studies have examined the biological consequences of manmade nanoparticle exposure in the mammalian system. This study examines carbon nanoparticle (CNP) exposure in both in vitro (murine BALB/c alveolar macrophages) and in vivo (murine BALB/c intranasal instillations) systems. Three types of CNP were examined (single-walled nanotubes, multi-walled nanotubes, and C60 fullerenes). In vitro macrophage experiments included measurements of morphology changes, apoptosis, viability, and antigen-presenting cell function in response to CNP exposure. In vivo mouse experiments determined the inflammatory potential of CNP exposure in the lung using a BUXCO™ apparatus along with cell differentials and cell morphology. This study presents evidence that CNP, accumulated in the plasma membranes of cells (disrupting lipid rafts), increased alveolar macrophage function with regard to antigen-presentation, significantly exacerbated airway hyper-responsiveness, and caused an influx of macrophages into the lung by posited mechanisms that involve the unique molecular and physical properties of CNP.

Acute Inhalation Exposure to Vaporized Methamphetamine Causes Lung Injury in Mice

Methamphetamine (MA) is currently the most widespread illegally used stimulant in the United States. Use of MA by smoking is the fastest growing mode of administration, which increases concerns about potential pulmonary and other medical complications. A murine exposure system was developed to study the pulmonary affects of inhaled MA. Mice were exposed to 25–100 mg vaporized MA and assessments were made 3 h following initiation of exposure to model acute lung injury. Inhalation of MA vapor resulted in dose-dependent increases in MA plasma levels that were in the range of those experienced by MA users. At the highest MA dose, histological changes were observed in the lung and small but significant increases in lung wet weight to body weight ratios (5.656 ± 0.176 mg/g for the controls vs. 6.706± 0.135 mg/g for the 100 mg MA-exposed mice) were found. In addition, there was 53% increase in total protein in bronchoalveolar lavage (BAL) fluid, greater than 20% increase in albumin levels in the BAL fluid, greater than 2.5-fold increase in lactate dehydrogenase levels in the BAL fluid, and reduced total BAL cell numbers (approximately 77% of controls). Levels of the early response cytokines tumor necrosis factor (TNF)-α and interleukin (IL)-6 were dose-dependently increased in BAL fluid of MA-exposed mice. Exposure to 100 mg MA significantly increased free radical generation in the BAL cells to 107–146% of controls and to approximately 135% of the controls in lung tissue in situ. Together, these data show that acute inhalation exposure to relevant doses of volatilized MA is associated with elevated free radical formation and significant lung injury.