The effect of iron status on gadolinium deposition in the rat brain: mechanistic implications.

IF 3.6 Q2 TOXICOLOGY
Frontiers in toxicology Pub Date : 2024-08-26 eCollection Date: 2024-01-01 DOI:10.3389/ftox.2024.1403031
John P Prybylski, Olivia Jastrzemski, Michael Jay
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Abstract

Introduction: Sites associated with gadolinium (Gd) deposition in the brain (e.g., the globus pallidus) are known to contain high concentrations of ferric iron. There is considerable debate over the mechanism of Gd deposition in the brain. The role of iron transport mechanisms in Gd deposition has not been determined. Thus, we seek to identify if Gd deposition can be controlled by modifying iron exposure. Methods: Female Sprague-Dawley rats were given diets with controlled iron levels at 2-6 ppm, 6 ppt (20 g/kg Fe carbonyl) or 48 ppm for 3 weeks to induce iron deficiency, overload or normalcy. They were kept on those diets while receiving a cumulative 10 mmol/kg dose of gadodiamide intravenously over 2 weeks, then left to washout gadodiamide for 3 days or 3 weeks before tissues were harvested. Gd concentrations in tissues were analyzed by ICP-MS. Results: There were no significant effect of dietary iron and total Gd concentrations in the organs, but there was a significant effect of iron status on Gd distribution in the brain. For the 3-week washout cohort, there was a non-significant trend of increasing total brain deposition and decreasing dietary iron, and about 4-fold more Gd in the olfactory bulbs of the low iron group compared to the other groups. Significant brain accumulation was observed in the low iron group total brain Gd in the 3-week washout group relative to the 3-day washout group and no accumulation was observed in other tissues. There was a strong negative correlation between femur Gd concentrations and concentrations in other organs when stratifying by dietary iron. Discussion: Gd brain deposition from linear Gd-based contrast agents (GBCAs) are dependent upon iron status, likely through variable transferrin saturation. This iron dependence appears to be associated with redistribution of peripheral deposited Gd (e.g., in the bone) into the brain.

铁状态对大鼠脑内钆沉积的影响:机理意义。
简介已知大脑中与钆(Gd)沉积有关的部位(如苍白球)含有高浓度的铁。关于 Gd 在大脑中沉积的机理存在很大争议。铁的运输机制在钆沉积中的作用尚未确定。因此,我们试图确定是否可以通过改变铁暴露来控制钆沉积。研究方法给雌性 Sprague-Dawley 大鼠喂食铁含量控制在 2-6 ppm、6 ppt(20 克/千克羰基铁)或 48 ppm 的食物 3 周,以诱导缺铁、铁过载或正常。小白鼠吃这些食物的同时,在 2 周内静脉注射累积剂量为 10 mmol/kg 的钆二胺,然后让小白鼠在 3 天或 3 周内洗掉钆二胺,然后再采集组织。组织中的钆浓度通过 ICP-MS 进行分析。结果显示膳食中的铁对器官中的总钆浓度没有明显影响,但铁的状态对大脑中钆的分布有明显影响。在为期 3 周的冲洗组群中,大脑总沉积量呈上升趋势,而膳食铁含量则呈下降趋势,但这一趋势并不明显;与其他组群相比,低铁组群嗅球中的钆含量高出约 4 倍。相对于 3 天冲洗组,低铁组在 3 周冲洗组中观察到脑部总钆显著累积,而在其他组织中未观察到累积。按膳食铁分层时,股骨钆浓度与其他器官的钆浓度之间存在很强的负相关。讨论:线性钆基造影剂(GBCAs)的钆脑沉积取决于铁的状态,可能是通过不同的转铁蛋白饱和度。这种铁依赖性似乎与外周沉积的 Gd(如骨骼中的 Gd)重新分布到大脑有关。
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
CiteScore
3.80
自引率
0.00%
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审稿时长
13 weeks
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