Potential dietary, non-metabolic accumulation of arsenic (As) in seaweed-eating sheep's teeth

Implications for archaeological studies

Magdalena Blanz, Kate Britton, Karen Grant, Joerg Feldmann

Research output: Contribution to journalArticle

5 Downloads (Pure)

Abstract

Evaluating the extent of an individual’s exposure to arsenic, (potentially) indicative of proximity to smelting activities, poisoning, or dietary history, has proven difficult in archaeological contexts due to uncertainties surrounding how arsenic biogenically accumulates in the tissues commonly found at archaeological sites such as bone and tooth, in addition to issues of diagenesis. In this study, teeth of modern sheep naturally exposed to high amounts of arsenic by means of seaweed in their diet are compared to the teeth of a less exposed ‘control group’ of modern sheep consuming predominantly grass.
Through analysis of total arsenic and other element concentrations in samples of enamel, cementum and dentine by hydride generation atomic fluorescence spectrometry (HG-AFS), as well as by bioimaging of radial tooth sections of sheep molars by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS), this research demonstrates that arsenic in the teeth of sheep exposed to dietary arsenic predominantly accumulatesin the infundibulum and occlusal dentine. The major route of uptake of arsenic in these teeth is therefore likely not by ingestion and metabolisation during growth of the tooth, as is thought to be the case for lead and barium, but rather due to direct surface contact, potentially even occurring during mastication. The implications of this type of in vivo chemical alteration of teeth for archaeological trace element studies are explored.
Original languageEnglish
Pages (from-to)21-31
Number of pages11
JournalJournal of Archaeological Science
Volume94
Early online date12 Apr 2018
DOIs
Publication statusPublished - Jun 2018

Fingerprint

eating behavior
uncertainty
contact
Group
Arsenic
Teeth
Archaeology

Keywords

  • dentine
  • animal husbandry
  • environmental pollution monitoring
  • LA-ICP-MS bioimaging
  • North Ronaldsay sheep
  • Lead (Pb)
  • trace elements

Cite this

@article{b371f57e9ab24b33bfc2b9444212ef02,
title = "Potential dietary, non-metabolic accumulation of arsenic (As) in seaweed-eating sheep's teeth: Implications for archaeological studies",
abstract = "Evaluating the extent of an individual’s exposure to arsenic, (potentially) indicative of proximity to smelting activities, poisoning, or dietary history, has proven difficult in archaeological contexts due to uncertainties surrounding how arsenic biogenically accumulates in the tissues commonly found at archaeological sites such as bone and tooth, in addition to issues of diagenesis. In this study, teeth of modern sheep naturally exposed to high amounts of arsenic by means of seaweed in their diet are compared to the teeth of a less exposed ‘control group’ of modern sheep consuming predominantly grass.Through analysis of total arsenic and other element concentrations in samples of enamel, cementum and dentine by hydride generation atomic fluorescence spectrometry (HG-AFS), as well as by bioimaging of radial tooth sections of sheep molars by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS), this research demonstrates that arsenic in the teeth of sheep exposed to dietary arsenic predominantly accumulatesin the infundibulum and occlusal dentine. The major route of uptake of arsenic in these teeth is therefore likely not by ingestion and metabolisation during growth of the tooth, as is thought to be the case for lead and barium, but rather due to direct surface contact, potentially even occurring during mastication. The implications of this type of in vivo chemical alteration of teeth for archaeological trace element studies are explored.",
keywords = "dentine, animal husbandry, environmental pollution monitoring, LA-ICP-MS bioimaging, North Ronaldsay sheep, Lead (Pb), trace elements",
author = "Magdalena Blanz and Kate Britton and Karen Grant and Joerg Feldmann",
note = "MB gratefully acknowledges support in form of a PhD stipend from the European Social Fund and Scottish Funding Council as part of Developing Scotland’s Workforce in the Scotland 2014-2020 European Structural and Investment Fund Programme. MB would also like to thank Benjamin Blanz for his assistance in creating the diagram of a sheep’s molar, and Ruth Mackay for taking photographic images of the sheep’s teeth. Hoy and North Ronaldsay tooth samples were kindly contributed by Prof Keith Dobney.",
year = "2018",
month = "6",
doi = "10.1016/j.jas.2018.03.008",
language = "English",
volume = "94",
pages = "21--31",
journal = "Journal of Archaeological Science",
issn = "0305-4403",
publisher = "Academic Press Inc.",

}

TY - JOUR

T1 - Potential dietary, non-metabolic accumulation of arsenic (As) in seaweed-eating sheep's teeth

T2 - Implications for archaeological studies

AU - Blanz, Magdalena

AU - Britton, Kate

AU - Grant, Karen

AU - Feldmann, Joerg

N1 - MB gratefully acknowledges support in form of a PhD stipend from the European Social Fund and Scottish Funding Council as part of Developing Scotland’s Workforce in the Scotland 2014-2020 European Structural and Investment Fund Programme. MB would also like to thank Benjamin Blanz for his assistance in creating the diagram of a sheep’s molar, and Ruth Mackay for taking photographic images of the sheep’s teeth. Hoy and North Ronaldsay tooth samples were kindly contributed by Prof Keith Dobney.

PY - 2018/6

Y1 - 2018/6

N2 - Evaluating the extent of an individual’s exposure to arsenic, (potentially) indicative of proximity to smelting activities, poisoning, or dietary history, has proven difficult in archaeological contexts due to uncertainties surrounding how arsenic biogenically accumulates in the tissues commonly found at archaeological sites such as bone and tooth, in addition to issues of diagenesis. In this study, teeth of modern sheep naturally exposed to high amounts of arsenic by means of seaweed in their diet are compared to the teeth of a less exposed ‘control group’ of modern sheep consuming predominantly grass.Through analysis of total arsenic and other element concentrations in samples of enamel, cementum and dentine by hydride generation atomic fluorescence spectrometry (HG-AFS), as well as by bioimaging of radial tooth sections of sheep molars by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS), this research demonstrates that arsenic in the teeth of sheep exposed to dietary arsenic predominantly accumulatesin the infundibulum and occlusal dentine. The major route of uptake of arsenic in these teeth is therefore likely not by ingestion and metabolisation during growth of the tooth, as is thought to be the case for lead and barium, but rather due to direct surface contact, potentially even occurring during mastication. The implications of this type of in vivo chemical alteration of teeth for archaeological trace element studies are explored.

AB - Evaluating the extent of an individual’s exposure to arsenic, (potentially) indicative of proximity to smelting activities, poisoning, or dietary history, has proven difficult in archaeological contexts due to uncertainties surrounding how arsenic biogenically accumulates in the tissues commonly found at archaeological sites such as bone and tooth, in addition to issues of diagenesis. In this study, teeth of modern sheep naturally exposed to high amounts of arsenic by means of seaweed in their diet are compared to the teeth of a less exposed ‘control group’ of modern sheep consuming predominantly grass.Through analysis of total arsenic and other element concentrations in samples of enamel, cementum and dentine by hydride generation atomic fluorescence spectrometry (HG-AFS), as well as by bioimaging of radial tooth sections of sheep molars by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS), this research demonstrates that arsenic in the teeth of sheep exposed to dietary arsenic predominantly accumulatesin the infundibulum and occlusal dentine. The major route of uptake of arsenic in these teeth is therefore likely not by ingestion and metabolisation during growth of the tooth, as is thought to be the case for lead and barium, but rather due to direct surface contact, potentially even occurring during mastication. The implications of this type of in vivo chemical alteration of teeth for archaeological trace element studies are explored.

KW - dentine

KW - animal husbandry

KW - environmental pollution monitoring

KW - LA-ICP-MS bioimaging

KW - North Ronaldsay sheep

KW - Lead (Pb)

KW - trace elements

U2 - 10.1016/j.jas.2018.03.008

DO - 10.1016/j.jas.2018.03.008

M3 - Article

VL - 94

SP - 21

EP - 31

JO - Journal of Archaeological Science

JF - Journal of Archaeological Science

SN - 0305-4403

ER -