暴露于铟及其化合物的肺部影响:暴露工人的横断面调查和啮齿动物的实验结果。

IF 7.2 1区 医学 Q1 TOXICOLOGY
Nan Liu, Yi Guan, Yan Yu, Gai Li, Ling Xue, Weikang Li, Xiaoyu Qu, Ning Li, Sanqiao Yao
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引用次数: 1

摘要

背景:许多研究表明,职业性接触铟及其化合物可诱发肺部疾病。虽然动物毒理学研究和人类流行病学研究表明,接触铟可能导致肺损伤、炎症、肺纤维化、肺气肿、肺泡蛋白沉积症,甚至肺癌,但目前从人类收集的相关数据有限,而且仅限于单一工作场所,接触对肺部的早期影响尚未得到很好的了解。目的:本研究采用群体研究和动物实验相结合的方法,探讨铟与肺损伤的关系及其作用机制。对来自中国的铟暴露工人进行了一项横断面流行病学研究,以评估职业性铟暴露与早期影响的血清生物标志物之间的关系。本研究还比较和分析了铟化合物暴露引起的人血清生物标志物变化和铟暴露相关大鼠肺部病理生物学的因果关系,并探讨了可能的识别和预防途径。方法:这是一项对来自铟锭生产厂的57名暴露工人(每天至少6小时,持续一年)和63名对照工人的研究。采用电感耦合等离子体质谱法测定血清、尿液和空气中铟浓度作为暴露指标。采用ELISA法检测肺损伤、炎症和氧化应激的16种血清生物标志物。分析血清铟与16种血清生物标志物的相关性,探讨铟对暴露工人肺损伤的作用机制。采用动物实验方法测定大鼠支气管肺泡灌洗液(BALF)中炎症因子水平及肺组织蛋白表达。建立4种不同形式的铟化合物暴露大鼠模型(每周气管内注射2次,暴露8周,恢复8周)。型号一:0、1.2、3、6 mg/kg bw氧化铟锡组;模型II: 0、1.2、3和6 mg/kg bw氧化铟(In2O3)组;模型三:0、0.523、1.046、2.614 mg/kg bw硫酸铟(In2(SO4)3)组;模型四:0、0.065、0.65和1.3 mg/kg bw三氯化铟(InCl3)组。采用苏木精伊红染色、周期性席夫染色、马松染色、透射电镜观察肺组织病理变化,免疫组织化学检测肺组织蛋白变化。结果:生产车间空气中铟浓度为78.4 μg/m3。铟暴露工人血清铟和尿铟水平分别为39.3 μg/L和11.0 ng/g。在暴露于铟的工人中发现肺损伤标志物、氧化应激标志物和炎症标志物增加。血清铟水平与血清SP-A、IL-1β、IL-6水平呈正相关。其中SP-A表现出持续-反应模式。动物实验结果显示,随着剂量的增加,各模型组大鼠血清中镉、肺中镉水平显著升高,IL - 1β、IL -6、IL - 10、TNF - α的BALF水平显著升高,SP-A、SP-D、KL-6、GM-CSF、NF-κB p65、HO-1蛋白表达上调。透射电镜显示,In2(SO4)3和InCl3是可溶的,在肺组织中没有发现颗粒,而不溶性化合物(ITO和In2O3)则相反。在In2(SO4)3和InCl3暴露组的肺组织中未发现pas染色阳性物质,而ITO和In2O3大鼠模型支持人类铟肺病中肺泡蛋白沉积和间质纤维化的发现。ITO和InCl3可加速间质纤维化。我们的体内研究结果表明,表面活性剂的肺泡内积聚(免疫组织化学)和铟肺病的特征性胆固醇裂口肉芽肿(PAS染色)是由一种特定形式的铟(ITO和In2O3)引发的。结论:在暴露于铟的工人中,生物标志物发现表明肺损伤、氧化应激和炎症反应。在工作场所遇到的四种形式的铟的大鼠模型中,生物标志物对所有化合物的反应总体上与人类一致。此外,在大鼠模型中,暴露于氧化铟锡和氧化铟后发现肺泡蛋白沉积,暴露于氧化铟锡和三氯化铟后发现间质纤维化,支持先前关于人类疾病的报道。血清SP-A水平与铟暴露呈正相关,可能被认为是暴露工人暴露和影响的潜在生物标志物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Pulmonary effects of exposure to indium and its compounds: cross-sectional survey of exposed workers and experimental findings in rodents.

Pulmonary effects of exposure to indium and its compounds: cross-sectional survey of exposed workers and experimental findings in rodents.

Pulmonary effects of exposure to indium and its compounds: cross-sectional survey of exposed workers and experimental findings in rodents.

Pulmonary effects of exposure to indium and its compounds: cross-sectional survey of exposed workers and experimental findings in rodents.

Background: Many studies have shown that occupational exposure to indium and its compounds could induce lung disease. Although animal toxicological studies and human epidemiological studies suggest indium exposure may cause lung injury, inflammation, pulmonary fibrosis, emphysema, pulmonary alveolar proteinosis, and even lung cancer, related data collected from humans is currently limited and confined to single workplaces, and the early effects of exposure on the lungs are not well understood.

Objectives: This study combined population studies and animal experiments to examine the links of indium with pulmonary injury, as well as its mechanism of action. A cross-sectional epidemiological study of indium-exposed workers from China was conducted to evaluate associations between occupational indium exposure and serum biomarkers of early effect. This study also compares and analyzes the causal perspectives of changes in human serum biomarkers induced by indium compound exposure and indium exposure-related rat lung pathobiology, and discusses possible avenues for their recognition and prevention.

Methods: This is a study of 57 exposed (at least 6 h per day for one year) workers from an indium ingot production plant, and 63 controls. Indium concentration in serum, urine, and airborne as exposure indices were measured by inductively coupled plasma-mass spectrometry. Sixteen serum biomarkers of pulmonary injury, inflammation, and oxidative stress were measured using ELISA. The associations between serum indium and 16 serum biomarkers were analyzed to explore the mechanism of action of indium on pulmonary injury in indium-exposed workers. Animal experiments were conducted to measure inflammatory factors levels in bronchoalveolar lavage fluid (BALF) and lung tissue protein expressions in rats. Four different forms of indium compound-exposed rat models were established (intratracheal instillation twice per week, 8 week exposure, 8 week recovery). Model I: 0, 1.2, 3, and 6 mg/kg bw indium tin oxide group; Model II: 0, 1.2, 3, and 6 mg/kg bw indium oxide (In2O3) group; Model III: 0, 0.523, 1.046, and 2.614 mg/kg bw indium sulfate (In2(SO4)3) group; Model IV: 0, 0.065, 0.65, and 1.3 mg/kg bw indium trichloride (InCl3) group. Lung pathological changes were assessed by hematoxylin & eosin, periodic acid Schiff, and Masson's staining, transmission electron microscopy, and the protein changes were determined by immunohistochemistry.

Results: In the production workshop, the airborne indium concentration was 78.4 μg/m3. The levels of serum indium and urine indium in indium-exposed workers were 39.3 μg/L and 11.0 ng/g creatinine. Increased lung damage markers, oxidative stress markers, and inflammation markers were found in indium-exposed workers. Serum indium levels were statistically and positively associated with the serum levels of SP-A, IL-1β, IL-6 in indium-exposed workers. Among them, SP-A showed a duration-response pattern. The results of animal experiments showed that, with an increase in dosage, indium exposure significantly increased the levels of serum indium and lung indium, as well as the BALF levels of IL‑1β, IL‑6, IL‑10, and TNF‑α and up-regulated the protein expression of SP-A, SP-D, KL-6, GM-CSF, NF-κB p65, and HO-1 in all rat models groups. TEM revealed that In2(SO4)3 and InCl3 are soluble and that no particles were found in lung tissue, in contrast to the non-soluble compounds (ITO and In2O3). No PAS-staining positive substance was found in the lung tissue of In2(SO4)3 and InCl3 exposure groups, whereas ITO and In2O3 rat models supported findings of pulmonary alveolar proteinosis and interstitial fibrosis seen in human indium lung disease. ITO and InCl3 can accelerate interstitial fibrosis. Findings from our in vivo studies demonstrated that intra-alveolar accumulation of surfactant (immunohistochemistry) and characteristic cholesterol clefts granulomas of indium lung disease (PAS staining) were triggered by a specific form of indium (ITO and In2O3).

Conclusions: In indium-exposed workers, biomarker findings indicated lung damage, oxidative stress and an inflammatory response. In rat models of the four forms of indium encountered in a workplace, the biomarkers response to all compounds overall corresponded to that in humans. In addition, pulmonary alveolar proteinosis was found following exposure to indium tin oxide and indium oxide in the rat models, and interstitial fibrosis was found following exposure to indium tin oxide and indium trichloride, supporting previous report of human disease. Serum SP-A levels were positively associated with indium exposure and may be considered a potential biomarker of exposure and effect in exposed workers.

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来源期刊
CiteScore
15.90
自引率
4.00%
发文量
69
审稿时长
6 months
期刊介绍: Particle and Fibre Toxicology is an online journal that is open access and peer-reviewed. It covers a range of disciplines such as material science, biomaterials, and nanomedicine, focusing on the toxicological effects of particles and fibres. The journal serves as a platform for scientific debate and communication among toxicologists and scientists from different fields who work with particle and fibre materials. The main objective of the journal is to deepen our understanding of the physico-chemical properties of particles, their potential for human exposure, and the resulting biological effects. It also addresses regulatory issues related to particle exposure in workplaces and the general environment. Moreover, the journal recognizes that there are various situations where particles can pose a toxicological threat, such as the use of old materials in new applications or the introduction of new materials altogether. By encompassing all these disciplines, Particle and Fibre Toxicology provides a comprehensive source for research in this field.
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