Lund Rasmussen Kaare, Skytte Lilian, D'imporzano Paolo, Orla Thomsen Per, Søvsø Morten, Lier Boldsen Jesper
Department of Physics, Chemistry and Pharmacy, University of Southern Denmark, Campusvej 55, DK-5230 Odense M, Denmark.
Faculteit der aard- en levenswetenschappen (cluster diepe aarde), Vrije Universiteit Amsterdam, Holland.
Am J Phys Anthropol. 2017 Jan;162(1):90-102. doi: 10.1002/ajpa.23099. Epub 2016 Sep 15.
The differences in trace element concentrations among 19 different bone elements procured from 10 archaeologically derived human skeletons have been investigated. The 10 individuals are dated archaeologically and some by radiocarbon dating to the medieval and post-medieval period, an interval from ca. AD 1150 to ca. AD 1810. This study is relevant for two reasons. First, most archaeometric studies analyze only one bone sample from each individual; so to what degree are the bones in the human body equal in trace element chemistry? Second, differences in turnover time of the bone elements makes the cortical tissues record the trace element concentrations in equilibrium with the blood stream over a longer time earlier in life than the trabecular. Therefore, any differences in trace element concentrations between the bone elements can yield what can be termed a chemical life history of the individual, revealing changes in diet, provenance, or medication throughout life.
Thorough decontamination and strict exclusion of non-viable data has secured a dataset of high quality. The measurements were carried out using Inductively Coupled Plasma Mass Spectrometry (for Fe, Mn, Al, Ca, Mg, Na, Ba, Sr, Zn, Pb and As) and Cold Vapor Atomic Absorption Spectroscopy (for Hg) on ca. 20 mg samples.
Twelve major and trace elements have been measured on 19 bone elements from 10 different individuals interred at five cemeteries widely distributed in medieval and renaissance Denmark. The ranges of the concentrations of elements were: Na (2240-5660 µg g ), Mg (440-2490 µg g ), Al (9-2030 µg g ), Ca (22-36 wt. %), Mn (5-11450 µg g ), Fe (32-41850 µg g ), Zn (69-2610 µg g ), As (0.4-120 µg g ), Sr (101-815 µg g ), Ba (8-880 µg g ), Hg (7-78730 ng g ), and Pb (0.8-426 µg g ).
It is found that excess As is mainly of diagenetic origin. The results support that Ba and Sr concentrations are effective provenance or dietary indicators. Migrating behavior or changes in diet have been observed in four individuals; non-migratory or non-changing diet in six out of the 10 individuals studied. From the two most mobile (most changing diet) individuals in the study, it is deduced that the fastest turnover is seen in the trabecular tissues of the long bones and the hands and the feet, and that these bone elements have higher turnover rates than centrally placed trabecular bone tissue, such as from the ilium or the spine. Comparing Sr and published bone turnover times, it is concluded that the differences seen in Sr concentrations are not caused by diagenesis, but by changes of diet or provenance. Finally, it is concluded that there can be two viable interpretations of the Pb concentrations, which can either be seen as an indicator for social class or a temporal development of increased Pb exposure over the centuries.
对从10具考古发掘出的人类骨骼中获取的19种不同骨元素的微量元素浓度差异进行了研究。这10个人经过考古年代测定,部分还通过放射性碳年代测定法确定为中世纪和中世纪后期,时间跨度约为公元1150年至公元1810年。这项研究具有重要意义,原因有二。其一,大多数考古测量研究仅分析每个个体的一个骨样本;那么人体中的骨骼在微量元素化学方面究竟在多大程度上是相同的呢?其二,骨元素更新时间的差异使得皮质组织比小梁组织在生命早期更长时间内记录与血流平衡的微量元素浓度。因此,骨元素之间微量元素浓度的任何差异都可以得出个体的化学生活史,揭示其一生中饮食、来源或用药的变化。
经过彻底去污并严格排除无效数据,获得了高质量的数据集。使用电感耦合等离子体质谱法(用于测定铁、锰、铝、钙、镁、钠、钡、锶、锌、铅和砷)和冷蒸气原子吸收光谱法(用于测定汞)对约20毫克的样本进行测量。
对广泛分布于中世纪和文艺复兴时期丹麦的五个墓地中10个不同个体的19种骨元素测量了12种主要和微量元素。元素浓度范围为:钠(2240 - 5660微克/克)、镁(440 - 2490微克/克)、铝(9 - 2030微克/克)、钙(22 - 36重量%)、锰(5 - 11450微克/克)、铁(32 - 41850微克/克)、锌(69 - 2610微克/克)、砷(0.4 - 120微克/克)、锶(101 - 815微克/克)、钡(8 - 880微克/克)、汞(7 - 78730纳克/克)和铅(0.8 - 426微克/克)。
发现过量的砷主要源于成岩作用。结果表明钡和锶的浓度是有效的来源或饮食指标。在四个个体中观察到了迁移行为或饮食变化;在研究的10个个体中,有6个个体没有迁移或饮食没有变化。从研究中两个迁移性最强(饮食变化最大)的个体推断,长骨以及手和脚的小梁组织更新最快,并且这些骨元素的更新率高于诸如髂骨或脊柱等位于身体中部的小梁骨组织。将锶与已发表的骨更新时间进行比较后得出结论,锶浓度的差异不是由成岩作用引起的,而是由饮食或来源的变化导致的。最后得出结论,对于铅浓度有两种可行的解释,既可以将其视为社会阶层的指标,也可以看作是几个世纪以来铅暴露增加的时间发展情况。
