Neurological Intensive Care Unit, Department of Neurology, Innsbruck Medical University, Innsbruck, Austria.
Division of Clinical Biochemistry, Biocenter, Innsbruck Medical University, Innsbruck, Austria.
Neurocrit Care. 2022 Feb;36(1):171-179. doi: 10.1007/s12028-021-01278-1. Epub 2021 Aug 9.
The amount of intracranial blood is a strong predictor of poor outcome after subarachnoid hemorrhage (SAH). Here, we aimed to measure iron concentrations in the cerebral white matter, using the cerebral microdialysis (CMD) technique, and to associate iron levels with the local metabolic profile, complications, and functional outcome.
For the observational cohort study, 36 patients with consecutive poor grade SAH (Hunt & Hess grade of 4 or 5, Glasgow Coma Scale Score ≤ 8) undergoing multimodal neuromonitoring were analyzed for brain metabolic changes, including CMD iron levels quantified by graphite furnace atomic absorption spectrometry. The study time encompassed 14 days after admission. Statistical analysis was performed using generalized estimating equations.
Patients were admitted in a poor clinical grade (n = 26, 72%) or deteriorated within 24 h (n = 10, 28%). The median blood volume in the subarachnoid space was high (SAH sum score = 26, interquartile range 20-28). Initial CMD iron was 44 µg/L (25-65 µg/L), which significantly decreased to a level of 25 µg/L (14-30 µg/L) at day 4 and then constantly increased over the remaining neuromonitoring days (p < 0.01). A higher intraventricular hemorrhage sum score (≥ 5) was associated with higher CMD iron levels (Wald-statistic = 4.1, df = 1, p = 0.04) but not with the hemorrhage load in the subarachnoid space (p = 0.8). In patients developing vasospasm, the CMD iron load was higher, compared with patients without vasospasm (Wald-statistic = 4.1, degree of freedom = 1, p = 0.04), which was not true for delayed cerebral infarction (p = 0.4). Higher iron concentrations in the brain extracellular fluid (34 µg/L, 36-56 µg/L vs. 23 µg/L, 15-37 µg/L) were associated with mitochondrial dysfunction (CMD lactate to pyruvate ratio > 30 and CMD-pyruvate > 70 µM/L, p < 0.001). Brain extracellular iron load was not associated with functional outcome after 3 months (p > 0.5).
This study suggests that iron accumulates in the cerebral white matter in patients with poor grade SAH. These findings may support trials aiming to scavenger brain extracellular iron based on the hypothesis that iron-mediated neurotoxicity may contribute to acute and secondary brain injury following SAH.
颅内出血量是蛛网膜下腔出血(SAH)后预后不良的强预测因子。在这里,我们旨在使用脑微透析(CMD)技术测量脑白质中的铁浓度,并将铁水平与局部代谢谱、并发症和功能结果相关联。
对于观察性队列研究,分析了 36 名连续患有不良分级 SAH(Hunt 和 Hess 分级 4 或 5 级,格拉斯哥昏迷量表评分≤8)的患者的脑代谢变化,包括通过石墨炉原子吸收光谱法定量的 CMD 铁水平。研究时间涵盖入院后 14 天。使用广义估计方程进行统计分析。
患者的临床分级较差(n=26,72%)或在 24 小时内恶化(n=10,28%)。蛛网膜下腔的血容量中位数较高(SAH 总和评分=26,四分位距 20-28)。初始 CMD 铁为 44μg/L(25-65μg/L),第 4 天降至 25μg/L(14-30μg/L),随后在剩余的神经监测天数中持续增加(p<0.01)。更高的脑室内出血总和评分(≥5)与更高的 CMD 铁水平相关(Wald 统计量=4.1,自由度=1,p=0.04),但与蛛网膜下腔的出血负荷无关(p=0.8)。发生血管痉挛的患者的 CMD 铁负荷高于无血管痉挛的患者(Wald 统计量=4.1,自由度=1,p=0.04),但迟发性脑梗死患者则不然(p=0.4)。脑细胞外液中铁浓度较高(34μg/L,36-56μg/L 与 23μg/L,15-37μg/L)与线粒体功能障碍相关(CMD 乳酸/丙酮酸比值>30 和 CMD-丙酮酸>70μM/L,p<0.001)。脑细胞外铁负荷与 3 个月后的功能结果无关(p>0.5)。
本研究表明,在分级较差的 SAH 患者中,铁在脑白质中积累。这些发现可能支持基于铁介导的神经毒性可能导致 SAH 后急性和继发性脑损伤的假说,以清除脑细胞外铁为目标的试验。
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