Novel approaches to evaluate carbon nanotube health impacts

评估碳纳米管健康影响的新方法

• 批准号: 7938749
• 负责人: KENT Ed PINKERTON
• 金额: $ 49.94万
• 依托单位: UNIVERSITY OF CALIFORNIA AT DAVIS
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-25 至 2012-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7938749
• 关键词: Address; Aerosols; Animals; Antioxidants; Area; Attention; Binding; Biochemical; Biocompatible Materials; Biological; Breathing; Carbon; Carbon Nanotubes; Cell Communication; Cell Culture Techniques; Cell-Mediated Cytolysis; Cells; Cellular Structures; Characteristics; Chemicals; Chemistry; Data; Defect; Deposition; Dose; Electronics; Engineering; Experimental Designs; Exposure to; Fibrosis; Future; Goals; Health; Homeostasis; Human; Imagery; Inflammation Mediators; Inflammatory; Iron; Label; Lipid Peroxidation; Lung; Measures; Mechanics; Mediating; Membrane Lipids; Metals; Methods; Metric; Molecular; Morphology; Occupational; Optics; Organ; Outcome; Oxidative Stress; Pathway interactions; Pattern; Play; Property; Qualifying; Reporting; Research; Resolution; Respiratory System; Respiratory tract structure; Risk; Role; Route; Safety; Surface; Techniques; Testing; Time; Toxic effect; Tracer; Transmission Electron Microscopy; Ultrafine; Work; base; biological systems; biomaterial compatibility; catalyst; cell injury; cytotoxicity; functional group; hazard; instrument; macrophage; nanomaterials; nanoparticle; nanosized; novel strategies; particle; programs; public health relevance; response; single bond

DESCRIPTION (provided by applicant): This application addresses broad Challenge Area (13) Smart Biomaterials - Theranostics and Specific Challenge Topic 13-ES-101, Methods to Evaluate the Health and Safety of Nanomaterials. Carbon-based engineered nanomaterials, such as single-walled carbon nanotubes (SWCNTs), have received notable attention due to their superior electronic, optical, mechanical, chemical, or even biological properties. Nanosized particles have a potentially high efficiency for deposition in both the upper and lower regions of the respiratory tract, are retained in the lungs for a long period of time, and induce more oxidative stress and cause greater inflammatory effects than their fine-sized equivalents, all of which suggest a need to better understand the impact of these particles on the body. Carbon nanotubes are projected to be incorporated into manufactured goods worth trillions of dollars in the next 5 years. Limited studies have reported toxicity and fibrosis following exposure to SWCNTs, which strongly suggests an urgent need to more fully understand the circumstances in which these materials might be compatible in or toxic to biological systems. The goal of our research plan is to elucidate the role that different particle characteristics and exposure/dose metrics (e.g., particle mass, surface area and size) of inhaled SWCNTs have on biological fate and toxicity. We hypothesize that inhaled SWCNTs cause localized cell injury and alter the biochemical homeostasis of the respiratory tract through oxidative stress that is mediated by direct particle interactions and release of pro-inflammatory mediators. It is further postulated that these effects are driven in large measure by molecular interactions of particle characteristics, chemistry, and morphology (i.e., metal contaminants, surface imperfections, dangling bonds, surface area, reactive functional groups, and size) with vital cellular structures. Our research plan will implement a number of novel approaches for material synthesis and aerosolization, as well as visualization of SWCNT-cell interactions at a regional, cellular and molecular level in the lungs. The aim of this research plan is to test the following specific hypotheses: (1) Inhalation of SWCNTs causes cellular injury, oxidative stress, and changes in biochemical homeostasis in the respiratory system of exposed animals; (2) SWCNT particle retention patterns and impaired macrophage function are associated with regional patterns of cytotoxicity and cellular remodeling; (3) Particle physicochemistry, specifically iron content, structural defects, and morphology, influences the extent of cellular injury and oxidative stress in the lungs of animals exposed to airborne carbon-based nanoparticles; and (4) Compromised lipid membrane integrity, diminished antioxidant capacity, and induced lipid peroxidation contribute to the regional cytotoxicity within the lungs caused by inhaled SWCNTs. This experimental design will bring together a number of novel approaches to address key issues regarding the potential health effects of inhaled engineered nanomaterials. This research program will provide unique and new information in offering a more complete understanding of the potential human health risks posed by these materials in industrial, consumer use, and environmental settings, as well as the physical and chemical characteristics of selected engineered nanomaterials that may drive the potential hazards. Our work will provide a more broadly applied understanding of how inhaled ultrafine or nanosized particles produce effects through physical or chemical particle-cellular interactions in the respiratory system and possibly other target organs. We envision that our approach can be broadly used through physical-chemical-activity patterns to determine the mechanisms of toxicity of other engineered nanomaterials and will aid in setting future occupational and environmental standards based on data reflective of the most sensitive health outcomes and relevant routes of exposure. Achieving a better understanding of the dynamics at play between particle physicochemistry, transport patterns, and cellular responses in the lungs and other organs will provide a future basis for establishing predictive measures of toxicity or biocompatibility and a framework for assessing potential human health risks. PUBLIC HEALTH RELEVANCE: Our work will provide a broad understanding of how inhaled ultrafine or nanosized particles in the form of single-walled carbon nanotubes (SWCNTs) produce effects through physical or chemical particle-cell interactions in the respiratory system and possibly other target organs. We envision that our approach with SWCNTs can be widely used to define physical-chemical-activity pathways that will aid in setting future occupational and environmental standards based on data reflective of the most sensitive health outcomes and relevant routes of exposure.

描述（由申请人提供）：本申请涉及广泛的挑战领域（13）智能生物材料-治疗学和特定挑战主题13- es -101，评估纳米材料健康和安全的方法。碳基工程纳米材料，如单壁碳纳米管（SWCNTs），由于其优越的电子、光学、机械、化学甚至生物特性而受到广泛关注。纳米颗粒在呼吸道上半部分和下半部分都具有潜在的高效率沉积，在肺部保留很长一段时间，并诱导更多的氧化应激和引起更大的炎症效应，所有这些都表明需要更好地了解这些颗粒对身体的影响。碳纳米管预计将在未来5年内被纳入价值数万亿美元的制成品中。有限的研究报告了SWCNTs暴露后的毒性和纤维化，这强烈表明迫切需要更全面地了解这些材料在生物系统中可能兼容或毒性的情况。我们的研究计划的目标是阐明吸入SWCNTs的不同颗粒特性和暴露/剂量指标（如颗粒质量、表面积和大小）对生物命运和毒性的作用。我们假设吸入SWCNTs可引起局部细胞损伤，并通过直接颗粒相互作用和促炎介质释放介导的氧化应激改变呼吸道的生化稳态。进一步假设，这些影响在很大程度上是由粒子特征、化学和形态（即金属污染物、表面缺陷、悬空键、表面积、活性官能团和大小）与重要细胞结构的分子相互作用驱动的。我们的研究计划将实施一些材料合成和雾化的新方法，以及在区域、细胞和分子水平上可视化肺中swcnts细胞相互作用。本研究计划的目的是验证以下具体假设：(1)吸入SWCNTs会导致暴露动物呼吸系统的细胞损伤、氧化应激和生化稳态改变；(2) swcnts颗粒保留模式和巨噬细胞功能受损与细胞毒性和细胞重塑的区域模式有关；(3)颗粒物理化学，特别是铁含量、结构缺陷和形态，影响暴露于空气中碳基纳米颗粒的动物肺部细胞损伤和氧化应激的程度；(4)脂膜完整性受损、抗氧化能力降低和诱导脂质过氧化导致吸入SWCNTs引起的肺内区域细胞毒性。这个实验设计将汇集一些新的方法来解决吸入工程纳米材料的潜在健康影响的关键问题。该研究项目将提供独特的新信息，以更全面地了解这些材料在工业、消费者使用和环境设置中对人类健康构成的潜在风险，以及选定的工程纳米材料的物理和化学特性，这些特性可能会导致潜在危害。我们的工作将为吸入的超细或纳米颗粒如何通过呼吸系统和其他靶器官的物理或化学颗粒-细胞相互作用产生影响提供更广泛的应用理解。我们设想，我们的方法可以通过物理-化学-活性模式广泛应用，以确定其他工程纳米材料的毒性机制，并将有助于根据反映最敏感的健康结果和相关暴露途径的数据制定未来的职业和环境标准。更好地了解颗粒物理化学、运输模式和肺及其他器官的细胞反应之间的动态关系，将为建立毒性或生物相容性的预测措施和评估潜在人类健康风险的框架提供未来的基础。