Project 3 Physiologically-based pharmacokinetic/pharmacodynamic modeling of C60

项目3 基于生理学的C60药代动力学/药效学建模

• 批准号: 8066896
• 负责人: Harvey Joseph Clewell
• 金额: $ 26.94万
• 依托单位: RESEARCH TRIANGLE INSTITUTE
• 依托单位国家: 美国
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-09-27 至 2012-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8066896
• 关键词: Adult; Alveolar; Animal Experiments; Animals; Artificial nanoparticles; Biochemical Process; Biological Models; Brain; Breathing; Carbon Nanotubes; Cardiovascular system; Cells; Chemical Models; Chemicals; Computer Simulation; Data; Development; Diffusion; Discipline of Nursing; Dose; Drug Kinetics; Endocytosis; Endometrial; Endothelial Cells; Epithelial; Epithelial Cells; Evaluation; Exposure to; Fetus; Goals; Health Sciences; Human; Human Biology; Human Development; In Vitro; Inflammatory; Inflammatory Response; Institutes; Intravenous; Kinetics; Laboratories; Lactation; Life; Link; Manganese; Mediating; Milk; Modeling; Monkeys; Mosses; Mothers; Mus; Neonatal; Nickel; Nose; Oral; Particulate; Physiological; Placenta; Pregnancy; Principal Investigator; Process; Production; Rattus; Research; Risk; Risk Assessment; Rodent; Route; Scientist; Staging; Structure; Testing; Time; Tissues; Toxic effect; Translating; Validation; Vascular Endothelial Cell; abstracting; base; cytokine; design; dosimetry; experience; fetal; human data; in vivo; nanomaterials; nanoparticle; particle; pharmacodynamic model; pregnant; prototype; pup; research study; response; tool; uptake

Abstract The ultimate goal of Project 3 is to provide a firm basis for predicting exposure conditions in the human under which these materials could elicit effects in the maternal, fetal, or neonatal cardiovascular system. The research approach for this project is based on the hypothesis that an appropriate physiologically based pharmacokinetic and pharmacodynamic (PBPK/PD) model for the disposition and effects ofthe engineered nanoparticles (ENMs) in one species can be used to provide quantitative predictions for another species, including the human. In this case, a PBPK/PD model will be developed using rat data from Projects 1 and 2, and the predictive power ofthe model will be tested using mouse data from Project 2. By incorporating human biology and data from human cells from Project 1, the model will provide a capability for quantitative extrapolation ofthe results of animal experiments to characterize the potential for human toxicity. The development ofthe PBPK model for nanoparticles will be conducted in a rigorous, step-wise manner, beginning with modeling ofthe processes associated with cellular uptake, localization, and clearance of nanoparticles using the in vitro data collected during Project 1 for epithelial and endothelial cells (Specific Aim 1). In Specific Aim 2, the cellular dosimetry model will be embedded in a PBPK description of the physiological time-course for gestation and lactation. The in vivo disposition data collected during Project 2 will be used to identify the whole-body PK parameters for the models. We posit that the cellular dosimetry model developed from in vitro data will accurately describe cellular dosimetry in the in vivo situation as well. We will test this hypothesis using in vivo tissue disposition data from Project 2. A similar step-wise approach will be used for the development of PD models of the various direct and indirect tissue responses to nanoparticle exposure in Specific Aim 3. The PD models will be designed to test two alternative hypotheses regarding cardiovascular toxicity of nanomaterials: either 1) direct induction of inflammatory responses and toxicity in target cells by the nanoparticles themselves, or 2) an indirect effect on vascular endothelial cells mediated by circulating cytokines produced in response to nanoparticle exposure in the portal of entry (e.g., alveolar epithelial cells). We hypothesize that both of these mechanisms contribute to the toxic effects of nanoparticles in different target tissues. The first 2 years of the project will focus on the development of the PBPK/PD model for the rat to provide a consistent description ofthe disposition and cardiovascular effects ofthe nanomaterials across multiple routes of exposure (i.e., intravenous [i.v.], oral, and inspirafion) and life stages (i.e., non-pregnant adult, pregnant dam and fetus, lactafing dam and pup). Comparison of target tissue dosimetry across these experimental condifions will allow evaluation ofthe relafive contribution ofthe direct and indirect mechanisms of toxicity and identification of susceptible life stages. In Years 3 through 5, PBPK/PD model parameterizations for the mouse and human will be developed (Specific Aim 4). In addition, our model structures will provide tools for Principal Investigators (Pis) in other centers to evaluate the potential systemic distribution and toxicity of other nanoparticles.

抽象的 项目 3 的最终目标是为预测人类暴露条件提供坚实的基础，在这些条件下这些材料可能会对孕产妇、胎儿或新生儿心血管系统产生影响。该项目的研究方法基于这样的假设：一个适当的基于生理学的药代动力学和药效学 (PBPK/PD) 模型用于工程化药物的处置和效果。 一个物种中的纳米颗粒（ENM）可用于为包括人类在内的另一物种提供定量预测。在这种情况下，将使用项目 1 和 2 的大鼠数据开发 PBPK/PD 模型，并使用项目 2 的小鼠数据测试模型的预测能力。通过结合人类生物学和项目 1 的人类细胞数据，该模型将提供对动物实验结果进行定量外推的能力，以表征对人体的潜在毒性。纳米颗粒 PBPK 模型的开发将以严格的、逐步的方式进行 方式，首先使用项目 1 期间收集的上皮细胞和内皮细胞（具体目标 1）的体外数据对与纳米颗粒的细胞摄取、定位和清除相关的过程进行建模。在具体目标 2 中，细胞剂量测定模型将嵌入妊娠和哺乳生理时间过程的 PBPK 描述中。项目 2 期间收集的体内处置数据将 用于确定模型的全身 PK 参数。我们认为，根据体外数据开发的细胞剂量测定模型也将准确描述体内情况下的细胞剂量测定。我们将使用项目 2 中的体内组织处置数据来检验这一假设。类似的逐步方法将用于开发特定目标 3 中对纳米颗粒暴露的各种直接和间接组织反应的 PD 模型。PD 模型将旨在测试有关纳米材料心血管毒性的两种替代假设：1）直接诱导 纳米颗粒本身对靶细胞的炎症反应和毒性，或 2) 对血管内皮细胞的间接影响，这是由纳米颗粒暴露在入口（例如肺泡上皮细胞）中产生的循环细胞因子介导的。我们假设这两种机制都会导致纳米颗粒在不同靶组织中产生毒性作用。 该项目的前两年将重点开发大鼠 PBPK/PD 模型，以一致地描述纳米材料在多种暴露途径（即静脉注射 [i.v]、口服和吸入）中的处置和心血管影响。 ）和生命阶段（即非怀孕的成年动物、怀孕的母鼠和胎儿、哺乳期的母鼠和幼崽）。在这些实验条件下比较靶组织剂量测定将允许评估直接和间接毒性机制的相对贡献并识别易感生命阶段。在第 3 年到第 5 年，将开发小鼠和人类的 PBPK/PD 模型参数化（具体目标 4）。此外，我们的模型结构将为其他中心的首席研究员（Pi）提供工具，以评估其他纳米颗粒的潜在系统分布和毒性。