Linking the physical and chemical characteristics of Qdots to their toxicity

将 Qdot 的物理和化学特性与其毒性联系起来

• 批准号: 8274474
• 负责人: Terrance J Kavanagh
• 金额: $ 109.01万
• 依托单位: UNIVERSITY OF WASHINGTON
• 依托单位国家: 美国
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-09-24 至 2015-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8274474
• 关键词: A/J Mouse; Air; Apoptosis; Arsenic; Benign; Bioinformatics; Biological; Biological Markers; Biology; Breathing; Cadmium; Carbon; Carbon Nanotubes; Cell Culture System; Cell Line; Cell Survival; Cell model; Cells; Characteristics; Charge; Chemicals; Chromosome Mapping; Complementary DNA; Computer software; Conceptus; Custom; Data; Development; Dose; Elements; Embryo; Endothelial Cells; Engineering; Environment; Environmental Exposure; Epigenetic Process; Epithelial; Epithelial Cells; Epithelium; Excretory function; Exposure to; Female; Fluorescent Dyes; Gene Expression; Genetic Polymorphism; Genomics; Goals; Gold; Health; Heart; Heavy Metals; Hepatocyte; Histopathology; Human; Hydrophobicity; Hypersensitivity; In Vitro; Inbred Mouse; Inbred Strains Mice; Inflammatory; Kidney; Lead; Link; Liquid substance; Liver; Lung; Maps; Materials Testing; Measures; Mercury; Metabolism; Methods; Mitochondria; Modeling; Mus; Nanosphere; Nanotubes; National Institute of Environmental Health Sciences; Nature; Necrosis; Occupational; Oxidation-Reduction; Oxidative Stress; Pathway Analysis; Pathway interactions; Phase; Poison; Proteins; Quantum Dots; Request for Applications; Research; Risk; Risk Assessment; Selenium; Semiconductors; Shapes; Signal Pathway; Signal Transduction; Silver; Site; Small Interfering RNA; Spleen; Splenocyte; Sports Equipment; Stress; Structure; Sunscreening Agents; Surface; Surface Properties; System; Techniques; Tellurium; Testing; Testis Brain; Thymus Gland; Tissues; Toxic effect; Toxicology; Transfection; Tubular formation; Vascular Endothelial Cell; Wound Healing; absorption; aerosolized; base; cell type; ceric oxide; chemical property; cytokine; cytotoxicity; design; epigenomics; genetic technology; human tissue; imaging modality; in vivo; in vivo Model; insight; interest; iron oxide; kidney epithelial cell; lymph nodes; macrophage; male; member; metal oxide; nanoGold; nanocrystal; nanofiber; nanomaterials; nanoparticle; nanoparticulate; nanorod; nanosilver; optical imaging; particle; physical property; predictive modeling; pregnant; programs; resistant strain; response; sertoli cell; titanium dioxide; uptake

DESCRIPTION (provided by applicant): Engineered nanomaterials are being used or are being proposed for use in a large number of commercial products. Because of their highly diverse physical and chemical characteristics, and their small size, concerns have been raised regarding their potential to cause harm to human health or the environment. One important class of ENMs are quantum dots (Qdots) which are luminescent semiconductor nanocrystals composed of heavy metal cores (e.g. CdSe, CdTe, HgTe) with cap and coating structures that vary greatly, depending upon the characteristics required for various applications. Certain characteristics are known to be determinants for the interaction of nanoparticles with cells and tissues, including shape, size, hydrophobicity, and surface charge. Because of the highly variable nature of these and other engineered nanomaterials, it will be nonetheless difficult to predict their toxicity. Modern advances in genomics, epigenetics and bioinformatics, and the availability of multiple strains of inbred mice with well characterized polymorphisms and regulatory sequences have made it possible to map and predict toxicity pathways for many toxic substances including nanomaterials. The research proposed herein will utilize in vitro and in vivo models of airway exposure to aerosolized quantum dot nanoparticles to 1) define the physical and chemical characteristics that govern their absorption, distribution, metabolism, excretion and toxicity; 2) using multiple inbred strains of mice, map toxicity pathways associated with these characteristics; and 3) incorporate the information that is obtained from these in vitro and in vivo models into a risk assessment paradigm that will be used to predict nanomaterial toxicity to humans. Such information will not only define which physical and chemical characteristics are important for the adverse biological effects of quantum dots, but will also simultaneously advance the fields of nanomaterial toxicology and functional epigenomics. These advances can then be used in safe design and manufacturing of nanomaterials so as to maximize their utility for many applications.

描述（由申请人提供）：正在使用或建议在大量商业产品中使用工程纳米材料。由于它们的物理和化学特征高度多样，并且对它们的尺寸小，因此对它们造成对人类健康或环境造成伤害的潜力提出了担忧。一类重要类的ENM是量子点（QDOT），它们是发光的半导体纳米晶体，由重金属芯（例如CDSE，CDSE，CDTE，HGTE，HGTE）组成，带有盖和涂层结构，这些结构差异很大，具体取决于各种应用所需的特性。已知某些特征是纳米颗粒与细胞和组织相互作用的决定因素，包括形状，大小，疏水性和表面电荷。由于这些和其他工程的纳米材料的性质高度可变，因此很难预测它们的毒性。现代基因组学，表观遗传学和生物信息学的进步，以及具有良好特征性多态性和调节序列的多种近交小鼠菌株的可用性，使得能够绘制和预测包括纳米材料在内的许多毒性物质的毒性途径。本文提出的研究将利用体外和体内气道暴露于雾化的量子点纳米颗粒至1）定义其吸收，分布，代谢，排泄和毒性的物理和化学特征； 2）使用多种近交菌株的小鼠，地图与这些特征相关的毒性途径； 3）将这些信息从这些体外和体内模型中获得的信息纳入风险评估范式中，该范式将用于预测对人类的纳米材料毒性。这些信息不仅将定义哪些物理和化学特征对于量子点的不良生物学作用很重要，而且还将同时推进纳米材料毒理学和功能表观基因组学的领域。然后可以将这些进步用于纳米材料的安全设计和制造，以最大程度地利用其用于许多应用的实用程序。