Centre for Advanced Discovery & Experimental Therapeutics, Division of Cardiovascular Sciences, School of Medical Sciences, Faculty of Biology, Medicine and Health, The University of Manchester, Manchester Academic Health Science Centre, Manchester M19 9NT, UK.
School of Biological Sciences, Faculty of Science, University of Auckland, Private Bag 92 019, Auckland 1142, New Zealand.
Metallomics. 2020 Jun 24;12(6):952-962. doi: 10.1039/d0mt00048e.
Studies of neurodegenerative conditions such as Alzheimer's disease (AD) using post mortem brain tissues have uncovered several perturbations in metals such as copper, iron, and zinc. However, studies of the effects of key, potentially confounding variables on these tissues are currently lacking. Moreover, human-brain tissues have limited availability, further enhancing the difficulty of matching potentially-significant variables including age, sex-matching, post-mortem delay (PMD), and neuropathological stage. This study aimed to investigate the effects of such factors and how they might influence metal concentrations in post-mortem brains. Cingulate gyrus from AD cases and matched controls was obtained from two brain banks, based in Auckland, New Zealand and Manchester, UK. Inductively-coupled plasma mass spectrometry (ICP-MS) was employed to measure levels of nine essential metals in brain tissues, and compared concentrations between cases and controls, and between cohorts, to analyse effects of age, sex, Braak stage, brain weight, and PMD. The same methods were used to investigate the effects of PMD under more controlled conditions using ex vivo healthy adult rat-brain tissue. Metal concentrations in human brain were found to be unmodified by differences in age, sex-matching, Braak stage, brain weight, and PMD between cohorts. Some metals were, however, found to vary significantly across different regions in rat brains. These results indicate that investigations of metal homeostasis in AD and other neurodegenerative conditions can be reliably performed using brain tissues without confounding by varying PMD, age, sex-matching, brain weight, and Braak stage. However, regions of study should be selected carefully.
使用死后脑组织研究神经退行性疾病(AD)等疾病,发现了铜、铁和锌等金属的几种失调。然而,目前缺乏对这些组织中关键的、潜在的混杂变量的影响的研究。此外,人脑组织的可用性有限,进一步增加了匹配潜在显著变量(包括年龄、性别匹配、死后延迟(PMD)和神经病理学阶段)的难度。本研究旨在调查这些因素的影响以及它们如何影响死后大脑中的金属浓度。AD 病例和匹配对照的扣带回皮质组织分别从新西兰奥克兰和英国曼彻斯特的两个脑库获得。使用电感耦合等离子体质谱(ICP-MS)测量脑组织中 9 种必需金属的水平,并比较病例和对照组以及队列之间的浓度,以分析年龄、性别、Braak 阶段、脑重和 PMD 的影响。相同的方法用于使用体外健康成年大鼠脑组织在更受控的条件下研究 PMD 的影响。在不同队列中,金属浓度不受年龄、性别匹配、Braak 阶段、脑重和 PMD 的差异影响。然而,在大鼠大脑的不同区域发现一些金属的浓度存在显著差异。这些结果表明,使用没有混杂 PMD、年龄、性别匹配、脑重和 Braak 阶段影响的脑组织,可以可靠地进行 AD 和其他神经退行性疾病中金属动态平衡的研究。然而,应该仔细选择研究区域。
