Modeling of clearance, retention, and translocation of inhaled gold nanoparticles in rats.

IF 2 4区 医学 Q4 TOXICOLOGY Inhalation Toxicology Pub Date : 2022-01-01 DOI:10.1080/08958378.2022.2115592
A Krikas, P Neofytou, G P Gakis, I Xiarchos, C Charitidis, L Tran
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引用次数: 4

Abstract

Objective: The increasing exposure to gold nanoparticles (AuNPs), due to their wide range of applications, has led to the need for thorough understanding of their biodistribution, following exposure. The objective of this paper is to develop a PBK model in order to study the clearance, retention and translocation of inhaled gold nanoparticles in rats, providing a basis for the understanding of the absorption, distribution, metabolism and elimination (ADME) mechanisms of AuNPs in various organs.Materials and methods: A rat PBK computational model was developed, connected to a detailed respiratory model, including the olfactory, tracheobronchial, and alveolar regions. This model was coupled with a Multiple Path Particle Dosimetry (MPPD) model to appropriately simulate the exposure to AuNPs. Three existing in vivo experimental datasets from scientific literature for the biodistribution of inhaled AuNPs for different AuNP sizes and exposure scenarios were utilized for model calibration and validation.Results and Discussion: The model was calibrated using two individual datasets for nose only inhaled and intratracheally instilled AuNPs, while an independent dataset for nose only inhaled AuNPs was used as external validation. The overall fitting over the three datasets was proved acceptable as shown by the relevant statistical metrics. The influence of several physiological parameters is also studied via a sensitivity analysis, providing useful insights into the mechanisms of NP pharmacokinetics. The key aspects of the inhaled AuNPs biodistribution are discussed, revealing the key mechanisms for the AuNPs absorption routes, the AuNP uptake by secondary organs and the influence of the AuNP size on the translocation from the lungs to blood circulation.Conclusions: The model results together with the model sensitivity analysis clarified the key mechanisms for the inhaled AuNPs biodistribution to secondary organs. It was observed that nose-only inhaled AuNPs of smaller size can enter the blood circulation through secondary routes, such as absorption through the gastrointestinal (GI) lumen, showing that such translocations should not be underestimated in biodistribution modelling. Finally, the computational framework presented in this study can be used as a basis for a more wide investigation of inhaled nanoparticles biodistribution, including interspecies extrapolation of the resulting PBK model for the inhalation and subsequent biodistribution of AuNPs in humans.

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大鼠吸入金纳米颗粒的清除、滞留和易位建模。
目的:由于金纳米颗粒(AuNPs)的广泛应用,人们越来越多地接触它们,因此需要彻底了解它们在接触后的生物分布。本文旨在建立PBK模型,研究吸入金纳米颗粒在大鼠体内的清除、滞留和转运,为了解AuNPs在各器官的吸收、分布、代谢和消除(ADME)机制提供基础。材料和方法:建立了大鼠PBK计算模型,并与包括嗅觉、气管支气管和肺泡区在内的详细呼吸模型相连接。该模型与多路径粒子剂量学(MPPD)模型相结合,以适当地模拟AuNPs的暴露。利用科学文献中已有的三个体内实验数据集,对不同AuNP大小和暴露情景下吸入AuNP的生物分布进行了模型校准和验证。结果和讨论:该模型使用仅鼻子吸入和气管内灌注的两个单独数据集进行校准,而仅鼻子吸入的AuNPs则使用独立数据集作为外部验证。相关统计指标表明,三个数据集的总体拟合是可以接受的。通过敏感性分析研究了几种生理参数的影响,为NP药代动力学机制提供了有用的见解。讨论了吸入AuNP生物分布的关键方面,揭示了AuNP吸收途径的关键机制,次要器官对AuNP的吸收以及AuNP大小对从肺到血液循环转运的影响。结论:模型结果及模型敏感性分析明确了吸入AuNPs向次生器官生物分布的关键机制。我们观察到,仅通过鼻子吸入的较小尺寸的AuNPs可以通过次要途径进入血液循环,例如通过胃肠道(GI)管腔吸收,这表明在生物分布模型中不应低估这种易位。最后,本研究中提出的计算框架可作为更广泛的吸入纳米颗粒生物分布研究的基础,包括由此得出的PBK模型对人体吸入和随后的AuNPs生物分布的种间外推。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Inhalation Toxicology
Inhalation Toxicology 医学-毒理学
CiteScore
4.10
自引率
4.80%
发文量
38
审稿时长
6-12 weeks
期刊介绍: Inhalation Toxicology is a peer-reviewed publication providing a key forum for the latest accomplishments and advancements in concepts, approaches, and procedures presently being used to evaluate the health risk associated with airborne chemicals. The journal publishes original research, reviews, symposia, and workshop topics involving the respiratory system’s functions in health and disease, the pathogenesis and mechanism of injury, the extrapolation of animal data to humans, the effects of inhaled substances on extra-pulmonary systems, as well as reliable and innovative models for predicting human disease.
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