Sub-acute Inhalation Exposure to Aluminum Oxide Nanoparticles and its Effects on Wistar Rats as Opposed to the Micro-sized Chemical Analog.

Q2 Pharmacology, Toxicology and Pharmaceutics

Pharmaceutical nanotechnology Pub Date : 2024-01-01 DOI:10.2174/0122117385258822230926043845

Marina Aleksandrovna Zemlyanova, Nina Vladimirovna Zaitseva, Mark Sergeevich Stepankov, Anna Mikhailovna Ignatova

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引用次数: 0

Abstract

Introduction: Aluminum oxide nanoparticles (Al₂O₃ NPs) are widely used in various productions. Simultaneously, many research works report the toxic effects of this nanomaterial. Given that, there is a growing risk of negative effects produced by Al₂O₃ NPs on public health.

Aims: This study aims to investigate the toxic effects of Al₂O₃ NPs as opposed to the micro-sized chemical analogue under sub-acute inhalation exposure.

Materials and methods: We identified the physical properties of Al₂O₃ NPs as opposed to the micro- sized chemical analogue, including size, specific surface area, and total pore volume. Inhalation exposure to Al₂O₃ NPs was simulated on Wistar rats in a chamber for whole-body. The animals were exposed for 4 hours each day for 28 days. NPs and MPs concentrations in the chamber were kept at ~ 1/4000 from LC₅₀. Rats' behavior was examined prior to the exposure period and after it; after the last daily exposure, we examined biochemical and hematological blood indicators, NPs and MPs bioaccumulation, and pathomorphological changes in organ tissues.

Results: The tested Al₂O₃ sample is a nanomaterial according to its analyzed physical properties. Rats' behavior changed more apparently under exposure to NPs compared to MPs. Aluminum levels, which were 1.62-55.20 times higher than the control, were identified in the lungs, liver, brain, and blood under exposure to NPs. These levels were also 1.55-7.65 times higher than the control under exposure to MPs. Biochemical indicators of rats' blood also changed under exposure to NPs against the control. We identified more active ALT, AST, ALP, and LDH, elevated levels of GABA, MDA, and conjugated bilirubin, and a lower level of Glu. As opposed to exposure to MPs, ALT, AST, and ALP were more active; GABA and MDA levels were higher; Glu level was lower. Under exposure to NPs, the number of platelets grew, whereas no similar effect occurred under exposure to MPs. We established pathomorphological changes in tissues of the lungs, brain, heart, and liver under exposure to Al₂O₃ NPs; similar changes occurred only in the lungs under exposure to MPs. Exposure to NPs induced changes in tissue structures in a wider range of various organs, and these changes were more apparent than under exposure to MPs.

Conclusion: Greater toxicity of Al₂O₃ NPs as opposed to MPs is evidenced by a wider range of organs where their bioaccumulation occurs, more apparent pathomorphological and pathological functional changes. Established peculiarities of toxic effects produced by the analyzed nanomaterial should be considered when developing hygienic recommendations aimed at preventing and mitigating adverse impacts of Al₂O₃ NPs on human health under inhalation exposure.

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亚急性吸入氧化铝纳米颗粒及其对 Wistar 大鼠的影响（与微小尺寸的化学类似物相比）。

简介纳米氧化铝（Al2O3 NPs）被广泛应用于各种生产中。与此同时，许多研究报告都指出了这种纳米材料的毒性作用。目的：本研究旨在探讨亚急性吸入接触 Al2O3 NPs 与微尺寸化学类似物相比的毒性效应：我们确定了 Al2O3 NPs 与微型化学类似物的物理性质，包括尺寸、比表面积和总孔隙度。我们模拟了 Wistar 大鼠全身吸入 Al2O3 NPs 的情况。动物每天暴露 4 小时，持续 28 天。室内的 NPs 和 MPs 浓度保持在 LC50 的约 1/4000 左右。在每天最后一次接触后，我们对大鼠的血液生化指标、NPs 和 MPs 的生物累积以及器官组织的病理形态学变化进行了检测：结果：根据分析的物理性质，测试的 Al2O3 样品属于纳米材料。与 MPs 相比，大鼠在接触 NPs 后的行为变化更为明显。在接触 NPs 的情况下，肺、肝、脑和血液中的铝含量比对照组高出 1.62-55.20 倍。在接触 MPs 的情况下，这些含量也比对照组高出 1.55-7.65 倍。与对照组相比，暴露于 NPs 的大鼠血液中的生化指标也发生了变化。我们发现 ALT、AST、ALP 和 LDH 更活跃，GABA、MDA 和共轭胆红素水平升高，Glu 水平降低。与接触 MPs 相比，ALT、AST 和 ALP 更活跃；GABA 和 MDA 水平更高；Glu 水平更低。在暴露于 NPs 的情况下，血小板数量增加，而在暴露于 MPs 的情况下则没有类似的效果。暴露于 Al2O3 NPs 时，我们发现肺、脑、心脏和肝脏组织发生了病理形态学变化；而暴露于 MPs 时，只有肺部发生了类似的变化。与暴露于 MPs 相比，暴露于 NPs 会导致更多器官的组织结构发生变化，而且这些变化更为明显：结论：相对于 MPs，Al2O3 NPs 的毒性更大，这表现在发生生物蓄积的器官范围更广，病理形态和病理功能变化更明显。在制定旨在预防和减轻吸入接触 Al2O3 NPs 对人体健康的不利影响的卫生建议时，应考虑到所分析的纳米材料所产生的毒性效应的既定特殊性。

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

Pharmaceutical nanotechnology Pharmacology, Toxicology and Pharmaceutics-Pharmaceutical Science

CiteScore

4.20

自引率

0.00%

发文量

期刊介绍： Pharmaceutical Nanotechnology publishes original manuscripts, full-length/mini reviews, thematic issues, rapid technical notes and commentaries that provide insights into the synthesis, characterisation and pharmaceutical (or diagnostic) application of materials at the nanoscale. The nanoscale is defined as a size range of below 1 µm. Scientific findings related to micro and macro systems with functionality residing within features defined at the nanoscale are also within the scope of the journal. Manuscripts detailing the synthesis, exhaustive characterisation, biological evaluation, clinical testing and/ or toxicological assessment of nanomaterials are of particular interest to the journal’s readership. Articles should be self contained, centred around a well founded hypothesis and should aim to showcase the pharmaceutical/ diagnostic implications of the nanotechnology approach. Manuscripts should aim, wherever possible, to demonstrate the in vivo impact of any nanotechnological intervention. As reducing a material to the nanoscale is capable of fundamentally altering the material’s properties, the journal’s readership is particularly interested in new characterisation techniques and the advanced properties that originate from this size reduction. Both bottom up and top down approaches to the realisation of nanomaterials lie within the scope of the journal.