Bingbing Sun

Publications (6)63.78 Total impact

• Article: Graphene Oxide Induces Toll-like Receptor 4 (TLR4)-Dependent Necrosis in Macrophages.

  Guangbo Qu, Sijin Liu, Shuping Zhang, Lei Wang, Xiaoyan Wang, Bingbing Sun, Nuoya Yin, Xiang Gao, Tian Xia, Jane-Jane Chen, Guibin Jiang
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  ABSTRACT: Graphene and graphene-based nanomaterials display novel and beneficial chemical, electrical, mechanical, and optical characteristics, which endow these nanomaterials with promising applications in a wide spectrum of areas such as electronics and biomedicine. However, its toxicity on health remains unknown and is of great concern. In the present study, we demonstrated that graphene oxide (GO) induced necrotic cell death to macrophages. This toxicity is mediated by activation of toll-like receptor 4 (TLR4) signaling and subsequently in part via autocrine TNF-α production. Inhibition of TLR4 signaling with a selective inhibitor prevented cell death nearly completely. Furthermore, TLR4-deficient bone marrow-derived macrophages were resistant to GO-triggered necrosis. Similarly, GO did not induce necrosis of HEK293T/TLR4-null cells. Macrophagic cell death upon GO treatment was partially attributed to RIP1-RIP3 complex-mediated programmed necrosis downstream of TNF-α induction. Additionally, upon uptake into macrophages, GO accumulated primarily in cytoplasm causing dramatic morphologic alterations and a significant reduction of the macrophagic ability in phagocytosis. However, macrophagic uptake of GO may not be required for induction of necrosis. GO exposure also caused a large increase of intracellular reactive oxygen species (ROS), which contributed to the cause of cell death. The combined data reveal that interaction of GO with TLR4 is the predominant molecular mechanism underlying GO-induced macrophagic necrosis; also, cytoskeletal damage and oxidative stress contribute to decreased viability and function of macrophages upon GO treatment.
  ACS Nano 06/2013; · 10.77 Impact Factor
• Source

  Available from: Xiang Wang

  Article: Surface Charge and Cellular Processing of Covalently Functionalized Multiwall Carbon Nanotubes Determine Pulmonary Toxicity.

  Ruibin Li, Xiang Wang, Zhaoxia Ji, Bingbing Sun, Haiyuan Zhang, Chong Hyun Chang, Sijie Lin, Huan Meng, Yu-Pei Liao, Meiying Wang, Zongxi Li, Angela A Hwang, Tze-Bin Song, Run Xu, Yang Yang, Jeffrey I Zink, André E Nel, Tian Xia
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  ABSTRACT: Functionalized carbon nanotubes (f-CNTs) are being produced in increased volume because of the ease of dispersion and maintenance of the pristine material physicochemical properties when used in composite materials as well as for other commercial applications. However, the potential adverse effects of f-CNTs have not been quantitatively or systematically explored. In this study, we used a library of covalently functionalized multiwall carbon nanotubes (f-MWCNTs), established from the same starting material, to assess the impact of surface charge in a predictive toxicological model that relates the tubes' pro-inflammatory and pro-fibrogenic effects at cellular level to the development of pulmonary fibrosis. Carboxylate (COOH), polyethylene glycol (PEG), amine (NH2), sidewall amine (sw-NH2), and polyetherimide (PEI)-modified MWCNTs were successfully established from raw or as-prepared (AP-) MWCNTs and comprehensively characterized by TEM, XPS, FTIR, and DLS to obtain information about morphology, length, degree of functionalization, hydrodynamic size, and surface charge. Cellular screening in BEAS-2B and THP-1 cells showed that, compared to AP-MWCNTs, anionic functionalization (COOH and PEG) decreased the production of pro-fibrogenic cytokines and growth factors (including IL-1β, TGF-β1, and PDGF-AA), while neutral and weak cationic functionalization (NH2 and sw-NH2) showed intermediary effects. In contrast, the strongly cationic PEI-functionalized tubes induced robust biological effects. These differences could be attributed to differences in cellular uptake and NLRP3 inflammasome activation, which depends on the propensity toward lysosomal damage and cathepsin B release in macrophages. Moreover, the in vitro hazard ranking was validated by the pro-fibrogenic potential of the tubes in vivo. Compared to pristine MWCNTs, strong cationic PEI-MWCNTs induced significant lung fibrosis, while carboxylation significantly decreased the extent of pulmonary fibrosis. These results demonstrate that surface charge plays an important role in the structure-activity relationships that determine the pro-fibrogenic potential of f-CNTs in the lung.
  ACS Nano 02/2013; · 10.77 Impact Factor
• Source

  Available from: Xiang Wang

  Article: NLRP3 Inflammasome Activation Induced by Engineered Nanomaterials.

  Bingbing Sun, Xiang Wang, Zhaoxia Ji, Ruibin Li, Tian Xia
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  ABSTRACT: Engineered nanomaterials (ENMs) continue to attract significant attention because they have novel physicochemical properties that can improve the functions of products that will benefit human lives. However, the physicochemical properties that make ENMs attractive could interact with biological systems and induce cascades of events that cause toxicological effects. Recently, there have been more studies suggesting inflammasome activation may play an important role in ENM-induced biological responses. Inflammasomes are a family of multiprotein complexes that are increasingly recognized as major mediators of the host immune system. Among these, NLRP3 inflammasome is the most studied that could directly interact with ENMs to generate inflammatory responses. In this review, the ENM physicochemical properties are linked to NLRP3 inflammasome activation. An understanding of the mechanisms of ENM-NLRP3 inflammasome interactions will provide us with strategies for safer nanomaterial design and therapy.
  Small 11/2012; · 8.35 Impact Factor
• Source

  Available from: Xiang Wang

  Article: Processing Pathway Dependence of Amorphous Silica Nanoparticle Toxicity: Colloidal vs Pyrolytic.

  Haiyuan Zhang, Darren R Dunphy, Xingmao Jiang, Huan Meng, Bingbing Sun, Derrick Tarn, Min Xue, Xiang Wang, Sijie Lin, Zhaoxia Ji, Ruibin Li, Fred L Garcia, Jing Yang, Martin L Kirk, Tian Xia, Jeffrey I Zink, Andre Nel, C Jeffrey Brinker
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  ABSTRACT: We have developed structure/toxicity relationships for amorphous silica nanoparticles (NPs) synthesized through low-temperature colloidal (e.g., Stöber silica) or high-temperature pyrolysis (e.g., fumed silica) routes. Through combined spectroscopic and physical analyses, we have determined the state of aggregation, hydroxyl concentration, relative proportion of strained and unstrained siloxane rings, and potential to generate hydroxyl radicals for Stöber and fumed silica NPs with comparable primary particle sizes (16 nm in diameter). On the basis of erythrocyte hemolytic assays and assessment of the viability and ATP levels in epithelial and macrophage cells, we discovered for fumed silica an important toxicity relationship to postsynthesis thermal annealing or environmental exposure, whereas colloidal silicas were essentially nontoxic under identical treatment conditions. Specifically, we find for fumed silica a positive correlation of toxicity with hydroxyl concentration and its potential to generate reactive oxygen species (ROS) and cause red blood cell hemolysis. We propose fumed silica toxicity stems from its intrinsic population of strained three-membered rings (3MRs) along with its chainlike aggregation and hydroxyl content. Hydrogen-bonding and electrostatic interactions of the silanol surfaces of fumed silica aggregates with the extracellular plasma membrane cause membrane perturbations sensed by the Nalp3 inflammasome, whose subsequent activation leads to secretion of the cytokine IL-1β. Hydroxyl radicals generated by the strained 3MRs in fumed silica, but largely absent in colloidal silicas, may contribute to the inflammasome activation. Formation of colloidal silica into aggregates mimicking those of fumed silica had no effect on cell viability or hemolysis. This study emphasizes that not all amorphous silicas are created equal and that the unusual toxicity of fumed silica compared to that of colloidal silica derives from its framework and surface chemistry along with its fused chainlike morphology established by high-temperature synthesis (>1300 °C) and rapid thermal quenching.
  Journal of the American Chemical Society 08/2012; 134(38):15790-804. · 9.91 Impact Factor
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  Available from: Xiang Wang

  Article: Designed synthesis of CeO2 nanorods and nanowires for studying toxicological effects of high aspect ratio nanomaterials.

  Zhaoxia Ji, Xiang Wang, Haiyuan Zhang, Sijie Lin, Huan Meng, Bingbing Sun, Saji George, Tian Xia, André E Nel, Jeffrey I Zink
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  ABSTRACT: While it has been shown that high aspect ratio nanomaterials like carbon nanotubes and TiO(2) nanowires can induce toxicity by acting as fiber-like substances that damage the lysosome, it is not clear what the critical lengths and aspect ratios are that induce this type of toxicity. To answer this question, we synthesized a series of cerium oxide (CeO(2)) nanorods and nanowires with precisely controlled lengths and aspect ratios. Both phosphate and chloride ions were shown to play critical roles in obtaining these high aspect ratio nanostructures. High-resolution TEM analysis shows that single-crystalline CeO(2) nanorods/nanowires were formed along the [211] direction by an "oriented attachment" mechanism, followed by Ostwald ripening. The successful creation of a comprehensive CeO(2) nanorod/nanowire combinatorial library allows, for the first time, the systematic study of the effect of aspect ratio on lysosomal damage, cytotoxicity, and IL-1β production by the human myeloid cell line (THP-1). This in vitro toxicity study demonstrated that, at lengths ≥200 nm and aspect ratios ≥22, CeO(2) nanorods induced progressive pro-inflammatory effects and cytotoxicity. The relatively low "critical" length and aspect ratio were associated with small nanorod/nanowire diameters (6-10 nm), which facilitates the formation of stacking bundles due to strong van der Waals and dipole-dipole attractions. Our results suggest that both length and diameter components of aspect ratio should be considered when addressing the cytotoxic effects of high aspect ratio materials.
  ACS Nano 05/2012; 6(6):5366-80. · 10.77 Impact Factor
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  Available from: Xiang Wang

  Article: Pluronic F108 coating decreases the lung fibrosis potential of multiwall carbon nanotubes by reducing lysosomal injury.

  Xiang Wang, Tian Xia, Matthew C Duch, Zhaoxia Ji, Haiyuan Zhang, Ruibin Li, Bingbing Sun, Sijie Lin, Huan Meng, Yu-Pei Liao, Meiying Wang, Tze-Bin Song, Yang Yang, Mark C Hersam, André E Nel
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  ABSTRACT: We compared the use of bovine serum albumin (BSA) and pluronic F108 (PF108) as dispersants for multiwalled carbon nanotubes (MWCNTs) in terms of tube stability as well as profibrogenic effects in vitro and in vivo. While BSA-dispersed tubes were a potent inducer of pulmonary fibrosis, PF108 coating protected the tubes from damaging the lysosomal membrane and initiating a sequence of cooperative cellular events that play a role in the pathogenesis of pulmonary fibrosis. Our results suggest that PF108 coating could serve as a safer design approach for MWCNTs.
  Nano Letters 04/2012; 12(6):3050-61. · 13.20 Impact Factor