Strontium isotopes as an indicator of human migration – easy questions, difficult answers

Krzysztof Szostek; Katarzyna Mądrzyk; Beata Cienkosz-Stepańczak

doi:10.1515/anre-2015-0010

Authors

Krzysztof Szostek Department of Anthropology, Institute of Zoology, Jagiellonian University, ul. Gronostajowa 9, 30-387 Kraków, Poland
Katarzyna Mądrzyk Department of Anthropology, Institute of Zoology, Jagiellonian University, ul. Gronostajowa 9, 30-387 Kraków, Poland
Beata Cienkosz-Stepańczak Department of Anthropology, Institute of Zoology, Jagiellonian University, ul. Gronostajowa 9, 30-387 Kraków, Poland

DOI:

https://doi.org/10.1515/anre-2015-0010

Keywords:

human mobility, stable isotopes, 87Sr/86Sr, local isotope range

Abstract

Isotope analyses of bones and teeth allow us to study phenomena which occurred in the history of human species and which are difficult to capture by traditional anthropological methods. Measuring oxygen, nitrogen and carbon isotope levels in the skeleton makes it possible to reconstruct climatic changes, diet and/or the weaning process. Among isotopes used in such analyses are strontium isotopes, helpful in analysing migration and studying the mobility of historical and prehistoric human populations. In this respect, the proportion of two isotopes, the heavier ⁸⁷Sr and the lighter ⁸⁶Sr, is measured, following their extraction from the bioapatite of the bone mineral. Released from rocks in the weathering process, strontium permeates individual components of inanimate and animate environments, and then finds its way, together with food, to the human body. Thanks to comprehensive environmental studies and the measurement of the strontium ratio ⁸⁷Sr/⁸⁶Sr in various animal tissues it is possible to determine the local isotope background for the environment. Values obtained by analysing human skeletons referenced against the range of environmental isotope variability enable researchers to trace back the location inhabited by the individual or group.

Downloads

Download data is not yet available.

References

Andrew Royle J, Rubenstein DR. 2004. The role of species abundance in determining breeding origins of migratory birds with stable isotopes. Ecol Appl 14(6):1780–88.
View in Google Scholar

Andrushko VA, Buzon MR, Simonetti A, Creaser RA. 2009. Strontium isotope evidence for prehistoric migration at Chokepukio, Valley of Cuzco, Peru. Lat Am Antiq 57–75.
View in Google Scholar

Anthony DW. 1990. Migration in archeology: The baby and the bathwater. Am Anthropol 92(4):895–914.
View in Google Scholar

Audi G, Bersillon O, Blachot J, Wapstra AH. 2003. The NUBASE evaluation of nuclear and decay properties. Nuclear Physics A 729(1):3–128.
View in Google Scholar

Balter V. 2004. Allometric constraints on Sr/Ca and Ba/Ca partitioning in terrestrial mammalian trophic chains. Oecologia 139(1):83–88.
View in Google Scholar

Bastos MQ, Souza SM, Santos RV, Lima BA, Santos RV, Rodrigues-Carvalho C. 2011. Human mobility on the Brazilian coast: an analysis of strontium isotopes in archaeological human remains from Forte Marechal Luz sambaqui. An Acad Bras Cienc 83(2):731–43.
View in Google Scholar

Becker JS. 2002. State-of-the-art and progress in precise and accurate isotope ratio measurements by ICP-MS and LA-ICP-MS Plenary Lecture. J Anal At Spectrom 17(9):1172–85.
View in Google Scholar

Bentley RA, Buckley HR, Spriggs M, Bedford S, Ottley CJ, Nowell GM et al. 2007. Lapita migrants in the Pacific’s oldest cemetery: isotopic analysis at Teouma, Vanuatu. Am Atiq 645–56.
View in Google Scholar

Bentley RA, Krause R, Price TD, Kaufmann B. 2003. Human Mobility at the early Neolithic settlement of Vaihingen, Germany: evidence from strontium isotope analysis. Archaeometry 45(3):471–86.
View in Google Scholar

Bentley RA, Price TD, Stephan E. 2004. Determining the ‘local’ 87Sr/86Sr range for archaeological skeletons: a case study from Neolithic Europe. J Archaeol Sci 31(4):365–75.
View in Google Scholar

Bentley RA., 2006. Strontium isotopes from the earth to the archaeological skeleton: a review. J Archaeol Method Th 13(3):135–87.
View in Google Scholar

Blum JD, Taliaferro EH, Weisse MT, Holmes RT. 2000. Changes in Sr/Ca, Ba/Ca and 87Sr/86Sr ratios between trophic levels in two forest ecosystems in the northeastern USA. Biogeochemistry 49(1):87–101.
View in Google Scholar

Brettell R, Montgomery J, Evans J. 2012. Brewing and stewing: the effect of culturally mediated behaviour on the oxygen isotope composition of ingested fluids and the implications for human provenance studies. J Anal Atom Spectrom 27:778–85.
View in Google Scholar

Budd P, Millard A, Chenery C, Lucy S, Roberts C. 2004. Investigating population movement by stable isotope analysis: a report from Britain. Antiquity 78(299): 127–41.
View in Google Scholar

Capo RC, Stewart BW, Chadwick OA. 1998. Strontium isotopes as tracers of ecosystem process: theory and methods. Geoderma 82.
View in Google Scholar

Chenery C, Müldner G, Evans J, Eckardt H, Lewis M. 2010. Strontium and stable isotope evidence for diet and mobility in Roman Gloucester, UK. J Archaeol Sci 37:150–63.
View in Google Scholar

Chua LS, Abdul-Rahaman NL, Sarmidi MR, Aziz R. 2012. Multi-elemental composition and physical properties of honey samples from Malaysia. Food Chem 135(3):880–87.
View in Google Scholar

Chudzinska M, Baralkiewicz D. 2010. Estimation of honey authenticity by multielements characteristics using inductively coupled plasma-mass spectrometry (ICP-MS) combined with chemometrics. Food Chem Toxicol 48:284–90.
View in Google Scholar

Chudzinska M, Baralkiewicz D. 2011. Application of ICP-MS method of determination of 15 elements in honey with chemometric approach for the verification of their authenticity. Food Chem Toxicol 49(11):2741–49.
View in Google Scholar

Cox G, Sealy J. 1997. Investigating identity and life histories: isotopic analysis and historical documentation of slave skeletons found on the Cape Town foreshore, South Africa. Int J Hist Archaeol 1(3):207–24.
View in Google Scholar

Daux V, LéCuyer C, Adam F, Martineau F, Vimeux F. 2005. Oxygen Isotope Composition Of Human Teeth And The Record Of Climate Changes In France (Lorraine) During The Last 1700 Years. Climatic Change 70:445–64.
View in Google Scholar

de Souza GF, Reynolds BC, Kiczka M, Bourdon B. 2010. Evidence for mass-dependent isotopic fractionation of strontium in a glaciated granitic watershed. Geochimica et Cosmochimica Acta 74(9):2596–614.
View in Google Scholar

DeNiro MJ. 1987. Stable isotopy and archaeology. Am Sci 182–91.
View in Google Scholar

Dupras TL, Tocheri MW. 2007. Reconstructing infant weaning histories at Roman period Kellis, Egypt using stable isotope analysis of dentition. Am J Phys Anthropol 134:63–74.
View in Google Scholar

Eerkens JW, Rosenthal JS, Stevens NE, Cannon A, Brown EL, Spero HJ. 2010. Stable isotope provenance analysis of Olivella shell beads from the Los Angeles Basin and San Nicolas Island. Journal of Island & Coastal Archaeology 5(1):105–19.
View in Google Scholar

Ehrlich S, Gavrieli I, Dor LB, Halicz L. 2001. Direct high-precision measurements of the 87Sr/86Sr isotope ratio in natural water, carbonates and related materials by multiple collector inductively coupled plasma mass spectrometry (MC-ICP-MS). J Anal At Spectrom 16(12):1389–92.
View in Google Scholar

English NB, Betancourt JL, Dean JS, Quade J. 2001. Strontium isotopes reveal distant sources of architectural timber in Chaco Canyon, New Mexico. Proceedings of the National Academy of Sciences 98(21):11891–96.
View in Google Scholar

Ericson JE. 1985. Strontium isotope characterization in the study of prehistoric human ecology. J Hum Evol 14(5): 503–14.
View in Google Scholar

Ericson JE. 1989. Some problems and potentials of strontium isotope analysis for human and animal ecology. In: Stable isotopes in ecological research. Springer New York. 252–59.
View in Google Scholar

Evans JA, Tatham S. 2004. Defining ‘local signature’ in terms of Sr isotope composition using a tenth-to twelfth-century Anglo-Saxon population living on a Jurassic clay-carbonate terrain, Rutland, UK. Geological Society, London, Special Publications 232(1): 237–48.
View in Google Scholar

Ezzo JA, Johnson CM, Price TD. 1997. Analytical perspectives on prehistoric migration: a case study from east-central Arizona. J Archaeol Sci 24(5): 447–66.
View in Google Scholar

Ezzo JA, Price TD. 2002. Migration, regional reorganization, and spatial group composition at Grasshopper Pueblo, Arizona. J Archaeol Sci 29:499–520.
View in Google Scholar

Faure G. 1986. Principles of isotope geology (Vol. 589). New York: Wiley.
View in Google Scholar

Fenner JN. 2008. The use of stable isotope ratio analysis to distinguish multiple prey kill events from mass kill events. J Archaeol Sci 35(3):704–16.
View in Google Scholar

Fietzke J, Eisenhauer A. 2006. Determination of temperature-dependent stable strontium isotope (88Sr/86Sr) fractionation via bracketing standard MC-ICP-MS. Geochemistry, Geophysics, Geosystems 7:1–6.
View in Google Scholar

Fricke HC, Clyde WC, O’Neil JR, Gingerich PD. 1998. Evidence for rapid climate change in North America during the latest Paleocene thermal maximum: oxygen isotope compositions of biogenic phosphate from the Bighorn Basin (Wyoming). Earth Planet Sc Lett 160(1):193–208.
View in Google Scholar

Fry B, Scala RS, Winter JK, Parker PL. 1982. Sulphur uptake by salt grasses, mangroves, and seagrasses in anaerobic sediments. Geochimica et Cosmochimica Acta 46(6):1121–24.
View in Google Scholar

Gorokhov IM, Siedlecka A, Roberts D, Melnikov NN, Turchenko TL. 2001. Rb–Sr dating of diagenetic illite in Neoproterozoic shales, Varanger Peninsula, northern Norway. Geological Magazine 138(05):541–62.
View in Google Scholar

Gosz JR, Moore DI, 1989. Strontium isotope studies of atmospheric inputs to forested watersheds in New Mexico. Biogeochemistry 8(2):115–34.
View in Google Scholar

Gregoricka LA. 2013. Residential mobility and social identity in the periphery: strontium isotope analysis of archaeological tooth enamel from southeastern Arabia. J Archaeol Sci 40(1):452–64.
View in Google Scholar

Grupe G, Price TD, Schröter P, Söllner F, Johnson CM, Beard BL. 1997. Mobility of Bell Beaker people revealed by strontium isotope ratios of tooth and bone: a study of southern Bavarian skeletal remains. Appl Geochemi 12(4):517–25.
View in Google Scholar

Gulson BL, Jameson WW, Gillings BR. 1997. Stable lead isotopes in teeth as indicators of past domicile-a potential new tool in forensic science? J Forensic Sci 42:787–91.
View in Google Scholar

Haak W, Brandt G, de Jong HN, Meyer C, Ganslmeier R, Heyd V et al. 2008. Ancient DNA, Strontium isotopes, and osteological analyses shed light on social and kinship organization of the Later Stone Age. Proceedings of the National Academy of Sciences 105(47):18226–31.
View in Google Scholar

Halicz L, Segal I, Fruchter N, Stein M, Lazar B. 2008. Strontium stable isotopes fractionate in the soil environments? Earth Planet Sc Lett 272(1):406–11.
View in Google Scholar

Haverkort CM, Weber A, Katzenberg MA, Goriunova OI, Simonetti A, Creaser RA. 2008. Hunter-gatherer mobility strategies and resource use based on strontium isotope (87Sr/86Sr) analysis: a case study from Middle Holocene Lake Baikal, Siberia. J Archaeol Sci 35(5): 1265–80.
View in Google Scholar

Hedman K, Hargrave EA, Ambrose SH. 2002. Late Mississippian diet in the American Bottom: stable isotope analyses of bone collagen and apatite. MidCont J Archaeol 237–71.
View in Google Scholar

Hernández OM, Fraga JMG, Jimenez AI, Jimenez F, Arias JJ. 2005. Characterization of honey from the Canary Islands: determination of the mineral content by atomic absorption spectrophotometry. Food Chem 93(3):449–58.
View in Google Scholar

Hobson KA. 1999. Tracing origins and migration of wildlife using stable isotopes: a review. Oecologia 120(3):314–26.
View in Google Scholar

Hodell DA, Quinn RL, Brenner M, Kamenov G. 2004. Spatial variation of strontium isotopes (87Sr/86Sr) in the Maya region: a tool for tracking ancient human migration. J Archaeol Sci 31(5):585–601.
View in Google Scholar

Holobinko A. 2012. Forensic human identification in the United States and Canada: A review of the law, admissible techniques, and the legal implications of their application in forensic cases. Forensic Sci Int 222. 394.e1–394.e13.
View in Google Scholar

Hoogewerff J, Papesch W, Kralik M, Berner M, Vroon P, Miesbauer H, et al. 2001. The last domicile of the Iceman from Hauslabjoch: a geochemical approach using Sr, C and O isotopes and trace element signatures. J Archaeol Sci 28(9): 983–89.
View in Google Scholar

Hoppe KA, Koch PL, Furutani TT. 2003. Assessing the preservation of biogenic strontium in fossil bones and tooth enamel. Int J Osteoarchaeol 13.
View in Google Scholar

Horn P, Hölzl S, Storzer D. 1994. Habitat determination on a fossil stag’s mandible from the site of Homo erectus heidelbergensis at Mauer by use of 87Sr/86Sr. Naturwissenschaften, 81(8):360–62.
View in Google Scholar

Julien MA, Bocherens H, Burke A, Drucker DG, Patou-Mathis M, Krotova O et al. 2012. Were European steppe bison migratory? 18O, 13C and Sr intra-tooth isotopic variations applied to a palaeoethological reconstruction. Quaternary International 271:106–19.
View in Google Scholar

Kamenov G, Macfarlane AW, Riciputi L. 2002. Sources of lead in the San Cristobal, Pulacayo, and Potosi mining districts, Bolivia, and a reevaluation of regional ore lead isotope provinces. Economic Geology 97(3):573–92.
View in Google Scholar

Kendall EJ, Montgomery J, Evans JA, Stantis C, Mueller V. 2013. Mobility, mortality, and the middle ages: Identification of migrant individuals in a 14th century black death cemetery population. Am J Phys Anthropol 150(2): 210–22.
View in Google Scholar

Kennedy BP, Chamberlain CP, Blum JD, Nislow KH, Folt CL. 2005. Comparing naturally occurring stable isotopes of nitrogen, carbon, and strontium as markers for the rearing locations of Atlantic salmon (Salmo salar). Can J Fish Aquat Sci 62(1):48–57.
View in Google Scholar

Kenoyer JM, Price TD, Burton JH. 2013. A new approach to tracking connections between the Indus Valley and Mesopotamia: initial results of strontium isotope analyses from Harappa and Ur. J Archaeol Sci 40(5):2286–97.
View in Google Scholar

King CL, Tayles N, Gordon KC. 2011. Re-examining the chemical evaluation of diagenesis in human bone apatite. J Archaeol Sci 38:2222–30.
View in Google Scholar

King GA. 2012. Isotopes as palaeoeconomic indicators: new applications in archaeoentomology. J Archaeol Sci 39(2):511–20.
View in Google Scholar

Knudson KJ, Gardella KR, Yaeger J. 2012a. Provisioning Inka feasts at Tiwanaku, Bolivia: the geographic origins of camelids in the Pumapunku complex. J Archaeol Sci 39(2):479–91.
View in Google Scholar

Knudson KJ, O’Donnabhain B, Carver C, Cleland R, Price TD. 2012b. Migration and Viking Dublin: paleomobility and paleodiet through isotopic analyses. J Archaeol Sci 39(2):308–20.
View in Google Scholar

Knudson KJ, Price TD, Buikstra JE, Blom DE. 2004. The use of strontium isotope analysis to investigate Tiwanaku migration and mortuary ritual in Bolivia and Peru. Archaeometry 46(1):5–18.
View in Google Scholar

Knudson KJ, Tung TA, Nystrom KC, Price TD, Fullagar PD. 2005. The origin of the Juch’uypampa Cave mummies: strontium isotope analysis of archaeological human remains from Bolivia. J Archaeol Sci 32(6):903–13.
View in Google Scholar

Knudson KJ, Williams HM, Buikstra JE, Tomczak PD, Gordon GW, Anbar AD. 2010. Introducing δ88/86Sr analysis in archaeology: a demonstration of the utility of strontium isotope fractionation in paleodietary studies. J Archaeol Sci 37(9):2352–64.
View in Google Scholar

Kontak DJ, Ansdell K, Dostal J, Halter W, Martin R, Williams-Jones AE. 2001. The nature and origin of pegmatites in a fluorine-rich leucogranite, East Kemptville tin deposit, Nova Scotia, Canada. Earth and Environmental Science Transactions of the Royal Society of Edinburgh 92(02):173–200.
View in Google Scholar

Kutschera W, Müller W. 2003. “Isotope language” of the Alpine Iceman investigated with AMS and MS. Nuclear Instruments and Methods in Physics Research B 204.
View in Google Scholar

Lee-Thorp J, Sponheimer M. 2003. Three case studies used to reassess the reliability of fossil bone and enamel isotope signals for paleodietary studies. J Anthropol Archaeol 22:208–16.
View in Google Scholar

Lee-Thorp J, Sealy J. 2008. Beyond documenting diagenesis: The fifth international bone diagenesis workshop. Palaeogeography, Palaeoclimatology, Palaeoecology 266:129–33.
View in Google Scholar

Liu HC, You CF, Chen CY, Liu YC, Chung MT. 2014. Geographic determination of coffee beans using multi-element analysis and isotope ratios of boron and strontium. Food Chem 142:439–45.
View in Google Scholar

Longinelli A. 1984. Oxygen isotopes in mammal bone phosphate: a new tool for paleohydrological and paleoclimatological research? Geochimica et Cosmochimica Acta 48:385–90.
View in Google Scholar

Macfarlane AW. 1999. Isotopic studies of northern Andean crustal evolution and ore metal sources. Geology and Ore Deposits of the Central Andes (Skinner, BJ editor). Society of Economic Geologists, Special Publication 7:195–217.
View in Google Scholar

Madejczyk M, Baralkiewicz D. 2008. Characterization of Polish rape and honeydew honey according to their mineral contents using ICP-MS and F-AAS/AES. Analytica Chimica Acta 617(1):11–17.
View in Google Scholar

Maziarski S, Nowicki Z. 1954. Narząd zębowy człowieka. PZWL.
View in Google Scholar

McGlynn G. 2007. Using δ13C, δ15N, δ18O stable isotope analysis of human bone tissue to identify transhumance, high altitude habitation and reconstruct palaeodiet for the early medieval Alpine population at Volders, Austria. PhD Thesis.
View in Google Scholar

Mitchell PD, Millard AR. 2009. Migration to the medieval Middle East with the Crusades. Am J Phys Anthropol 140(3):518–25.
View in Google Scholar

Müller W, Fricke H, Halliday AN, McCulloch MT, Wartho JA. 2003. Origin and Migration of the Alpine Iceman. Science 302(5646):862–66.
View in Google Scholar

Négrel P, Deschamps P. 1996. Natural and anthropogenic budgets of a small watershed in the Massif Central (France): chemical and strontium isotopic characterization of water and sediments. Aquatic Geochem 2(1):1–27.
View in Google Scholar

Niedźwiedzki T, Kuryszko JJ. 2007. Biologia kości. Wydawnictwo Naukowe PWN.
View in Google Scholar

Nowak A, Wagner B, Bulska E. 2008. Analiza pierwiastkowa szkieł historycznych: możliwości i ograniczenia spektrometrii mas z jonizacją próbki w plazmie indukcyjnie sprzężonej po ablacji laserowej (LA ICP MS), VIII konferencja „Analiza chemiczna w ochronie zabytków”.
View in Google Scholar

Oelze VM, Nehlich O, Richards MP. 2012. ‘There’s no place like home’— no isotopic evidence for mobility at the early bronze age cemetery of Singen, Germany. Archaeometry 54(4):752–78.
View in Google Scholar

Pate FD, Brodie R, Owen TD. 2002. Determination of geographic origin of unprovenanced Aboriginal skeletal remains in South Australia employing stable carbon and nitrogen isotope analysis. Australian Archaeology 1–7.
View in Google Scholar

Pate FD. 1994. Bone chemistry and paleodiet. J Archaeol Method Th1(2):161–209.
View in Google Scholar

Porder S, Paytan A, Hadly EA. 2003. Mapping the origin of faunal assemblages using strontium isotopes. Journal Information 29(2).
View in Google Scholar

Price TD, Burton JH, Bentley RA. 2002. The characterization of biologically available strontium isotope ratios for the study of prehistoric migration. Archaeometry 44(1):117–35.
View in Google Scholar

Price TD, Burton JH, Fullagar PD, Wright LE, Buikstra JE, Tiesler V. 2008. Strontium isotopes and the study of human mobility in ancient Mesoamerica. Lat Am Antiq 167–80.
View in Google Scholar

Price TD, Burton JH, Sharer RJ, Buikstra JE, Wright LE, Traxler LP, et al. 2010. Kings and commoners at Copan: Isotopic evidence for origins and movement in the Classic Maya period. J Anthropol Archaeol 29(1):15–32.
View in Google Scholar

Price TD, Johnson CM, Ezzo JA, Ericson J, Burton JH. 1994. Residential mobility in the prehistoric southwest United States: a preliminary study using strontium isotope analysis. J Archaeol Sci, 21(3):315–30.
View in Google Scholar

Price TD, Manzanilla L, Middleton WD. 2000. Immigration and the ancient city of Teotihuacan in Mexico: a study using strontium isotope ratios in human bone and teeth. J Archaeol Sci 27(10):903–13.
View in Google Scholar

Price TD, Wahl J, Bentley RA. 2006. Isotopic evidence for mobility and group organization among Neolithic farmers at Talheim, Germany, 5000 BC. European Journal of Archaeology 9(2–3):259–84.
View in Google Scholar

Probst A, El Gh’mari A, Aubert D, Fritz B, McNutt R. 2000. Strontium as a tracer of weathering processes in a silicate catchment polluted by acid atmospheric inputs, Strengbach, France. Chemical Geology 170(1):203–19.
View in Google Scholar

Prohaska T, Latkoczy C, Schultheis G, Teschler-Nicola M, Stingeder G. 2002. Investigation of Sr isotope ratios in prehistoric human bones and teeth using laser ablation ICP-MS and ICP-MS after Rb/Sr separation. J Anal Atom Spectrom 17(8):887–91.
View in Google Scholar

Rashed MN, Soltan ME. 2004. Major and trace elements in different types of Egyptian mono-floral and non-floral bee honeys. J Food Compost Anal 17(6):725–35.
View in Google Scholar

Ravikant V, Bajpai S. 2010. Strontium isotope evidence for the age of Eocene fossil whales of Kutch, western India. Geological Magazine 147(03):473–77.
View in Google Scholar

Reinhardt EG, Stanley DJ, Schwarcz HP. 2001. Human-induced desalinization of Manzala Lagoon, Nile Delta, Egypt: evidence from isotopic analysis of benthic invertebrates. Journal of Coastal Research 431–42.
View in Google Scholar

Richards M, Harvati K, Grimes V, Smith C, Smith T, Hublin JJ, et al. 2008. Strontium isotope evidence of Neanderthal mobility at the site of Lakonis, Greece using laser-ablation PIMMS. J Archaeol Sci 35(5):1251–56.
View in Google Scholar

Roberts CA, Millard AR, Nowell GM, Gröcke DR, Macpherson CG, Pearson DG et al. 2013. Isotopic tracing of the impact of mobility on infectious disease: The origin of people with treponematosis buried in hull, England, in the late medieval period. Am Journal Phys Anthropol 150:273–85.
View in Google Scholar

Rüggeberg A, Fietzke J, Liebetrau V, Eisenhauer A, Dullo WC, Freiwald A. 2008. Stable strontium isotopes (δ88/86Sr) in cold-water corals – a new proxy for reconstruction of intermediate ocean water temperatures. Earth Planet. Sci. Lett. 269:570–75.
View in Google Scholar

Rummel S, Hoelzl S, Horn P, Rossmann A, Schlicht C. 2010. The combination of stable isotope abundance ratios of H, C, N and S with 87Sr/86Sr for geographical origin assignment of orange juices. Food Chem 118(4):890–900.
View in Google Scholar

Sanusi A, Wortham H, Millet M, Mirabel P. 1996. Chemical composition of rainwater in eastern France. Atmospheric Environment 30(1):59–71.
View in Google Scholar

Scheeres M, Knipper C, Hauschild M, Schönfelder M, Siebel W, Vitali D, et al. 2013. Evidence for “Celtic migrations”? Strontium isotope analysis at the early La Tène (LT B) cemeteries of Nebringen (Germany) and Monte Bibele (Italy). J Archaeol Sci 40(10):3614–25.
View in Google Scholar

Schellenberg A, Chmielus S, Schlicht C, Camin F, Perini M, Bontempo L, et al. 2010. Multielement stable isotope ratios (H, C, N, S) of honey from different European regions. Food Chem121(3):770–77.
View in Google Scholar

Scherer AK, Wright LE, Yoder CJ. 2007. Bioarchaeological evidence for social and temporal differences in diet at Piedras Negras, Guatemala. Lat Am Antiq 85–104.
View in Google Scholar

Schoeninger MJ, Moore K. 1992. Bone stable isotope studies in archaeology. J World Prehist 6(2):247–96.
View in Google Scholar

Schutkowski H. 2001. Subsistence, social status and stature – Approaches from Historical Anthrology to the reconstruction and significance of dietary patterns. Jahrbuch für Wirtschaftsgeschichte/Economic History Yearbook 41(1):13–28.
View in Google Scholar

Schutkowski H. 2002. Mines, meals, and movement – a human ecological approach to the interface of history and biology. In: M Smith, editor. Society for the Study of Human Biology, Series: 42. Cambridge University Press.
View in Google Scholar

Schweissing MM, Grupe G. 2000. Local or nonlocal? A research of strontium isotope ratios of theeth and bones on skeletal remains with artificial deformed skulls. Anthropol Anz 99–103.
View in Google Scholar

Schweissing MM, Grupe G. 2003. Stable strontium isotopes in human teeth and bone: a key to migration events of the late Roman period in Bavaria. J Archaeol Sci 30(11):1373–83.
View in Google Scholar

Shantal Rodríguez Flores M, Escuredo O, Carmen Seijo M. 2014. Assessment of physicochemical and antioxidant characteristics of Quercus pyrenaica honeydew honeys. Food Chem 166:101–6.
View in Google Scholar

Shaw B, Buckley H, Summerhayes G, Anson D, Garling S, Valentin F et al. 2010. Migration and mobility at the Late Lapita site of Reber–Rakival (SAC), Watom Island using isotope and trace element analysis: a new insight into Lapita interaction in the Bismarck Archipelago. J Archaeol Sci 37(3):605–13.
View in Google Scholar

Shaw B, Buckley H, Summerhayes G, Stirling C, Reid M. 2011. Prehistoric migration at Nebira, South Coast of Papua New Guinea: New insights into interaction using isotope and trace element concentration analyses. J Archaeol Sci 30(3): 344–58.
View in Google Scholar

Sillen A, Hall G, Armstrong R. 1995. Strontium calcium ratios (Sr/Ca) and strontium isotopic ratios (87Sr/86Sr) of Australopithecus robustus and Homo sp. from Swartkrans. J Hum Evol 28(3):277–85.
View in Google Scholar

Sillen A, Hall G, Richardson S, Armstrong R. 1998. 87Sr/86Sr ratios in modern and fossil food-webs of the Sterkfontein Valley: implications for early hominid habitat preference. Geochimica et Cosmochimica Acta 62(14):2463–73.
View in Google Scholar

Sjögren KG, Price TD, Ahlström T. 2009. Megaliths and mobility in south-western Sweden. Investigating relationships between a local society and its neighbours using strontium isotopes. J Anthropol Archaeol 28(1):85–101.
View in Google Scholar

Spence MW, White CD. 2009. Mesoamerican bioarchaeology: past and future. Ancient Mesoamerica 20(02):233–40.
View in Google Scholar

Stanley JD, Krom MD, Cliff RA, Woodward JC. 2003. Short contribution: Nile flow failure at the end of the Old Kingdom, Egypt: strontium isotopic and petrologic evidence. Geoarchaeology 18(3):395–402.
View in Google Scholar

Stepańczak B, Mądrzyk K, Szczepanek A, Szostek K. 2013. Analiza proporcji trwałych izotopów tlenu (18O/16O) w kościach szkieletów ludzkich. In: MM Przybyła, A Szczepanek, P Włodarczak, editors. Ocalonoe dziedzictwo archeologiczne 4. Koszyce, stanowisko 3 Przemoc i rytuał u schyłku Neolitu. Kraków-Pękowice: Wydawnictwo i Pracownia Archeologiczna PROFIL-ARCHEO: 125–34.
View in Google Scholar

Stepańczak B, Szostek K, Pawlyta J. 2014. The human bone oxygen isotope ratio changes with aging. Geochronometria 41(2): 147–59.
View in Google Scholar

Stepańczak B. 2012. Zastosowania stabilnych izotopów tlenu w badaniach antropologicznych mieszkańców przedlokacyjnego Krakowa. PhD Thesis.
View in Google Scholar

Stern RJ, Hedge CE. 1985. Geochronologic and isotopic constraints on late Precambrian crustal evolution in the Eastern Desert of Egypt. Am J Sci 285(2):97–127.
View in Google Scholar

Szlasa-Byczek A, Orłowska B, Wagner B. 2008. Dramatyczne skutki zabiegów chemicznych na obiektach zabytkowych. Analiza chemiczna, jako pomoc w doborze sposobu ich ratowania, VIII konferencja „Analiza chemiczna w ochronie zabytków”.
View in Google Scholar

Szostek K, Głąb H, Lorkiewicz W, Grygiel R, Bogucki P. 2005. The diet and social paleostratigraphy of Neolitic agricultural population of the Lengyel culture from Osłonki (Poland) . Anthropol Rev 68:29–43.
View in Google Scholar

Szostek K, Haduch E, Stepańczak B, Kruk J, Szczepanek A, Pawlyta J, et al. 2014. Isotopic composition and identification of the origins of individuals buried in a Neolithic collective grave at Bronocice (southern Poland). HOMO 65(2): 115–30.
View in Google Scholar

Szostek K. 2009. Chemical signals and reconstruction of life strategies from ancient human bones and teeth-problems and perspectives. Anthropol Rev 72(1): 3–30.
View in Google Scholar

Thornton EK, Defrance SD, Krigbaum J, Williams PR. 2011. Isotopic evidence for Middle Horizon to 16th century camelid herding in the Osmore Valley, Peru. Int J Osteoarchaeol 21(5):544–67.
View in Google Scholar

Thornton EK. 2011. Reconstructing ancient Maya animal trade through strontium isotope (87Sr/86Sr) analysis. J Archaeol Sci 38(12):3254–63.
View in Google Scholar

Tung TA, Knudson KJ. 2011. Identifying locals, migrants, and captives in the Wari Heartland: A bioarchaeological and biogeochemical study of human remains from Conchopata, Peru. J Anthropol Archaeol 30(3):247–61.
View in Google Scholar

Voerkelius S, Lorenz GD, Rummel S, Quétel CR, Heiss G, Baxter M et al. 2010. Strontium isotopic signatures of natural mineral waters, the reference to a simple geological map and its potential for authentication of food. Food Chem 118(4):933–40.
View in Google Scholar

Vroon PZ, Van Der Wagt B, Koornneef JM, Davies GR. 2008. Problems in obtaining precise and accurate Sr isotope analysis from geological materials using laser ablation MC-ICPMS. Anal Biochem 390(2):465–76.
View in Google Scholar

Wagner B, Bulska E. 1999. Zastosowanie nowoczesnych metod instrumentalnych w badaniach zabytków rękopiśmiennych, I konferencja „Analiza chemiczna w ochronie zabytków”.
View in Google Scholar

Walczyk T. 2004. TIMS versus multicollector-ICP-MS: coexistence or struggle for survival?. Analytical and bioanalytical chemistry 378(2):229–31.
View in Google Scholar

Waterman AJ, Peate DW, Silva AM, Thomas JT. 2014. In search of homelands: using strontium isotopes to identify biological markers of mobility in late prehistoric Portugal. J Archaeol Sci 42:119–27.
View in Google Scholar

West JB, Hurley JM, Dudás FÖ, Ehleringer JR. 2009. The stable isotope ratios of marijuana. II. Strontium isotopes relate to geographic origin. J Forensic Sci 54(6):1261–69.
View in Google Scholar

White CD, Longstaffe FJ, Law KR. 2004b. Exploring the effects of environment, physiology and diet on oxygen isotope ratios in ancient Nubian bones and teeth. J Archaeol Sci 31:233–50.
View in Google Scholar

White CD, Price TD, Longstaffe FJ. 2007. Residential histories of the human sacrifices at the Moon Pyramid, Teotihuacan. Ancient Mesoamerica 18(01):159–72.
View in Google Scholar

White CD, Spence MW, Longstaffe FJ, Law KR. 2004c. Demography and ethnic continuity in the Tlailotlacan enclave of Teotihuacan: the evidence from stable oxygen isotopes. J Archaeol Sci 23/385–403.
View in Google Scholar

White CD, Storey R, Longstaffe FJ, Spence MW. 2004a. Immigration, assimilation, and status in the ancient city of Teotihuacan: Stable isotopic evidence from Tlajinga 33. Lat Am Antiq 176–98.
View in Google Scholar

Williams JS, White CD. 2006. Dental modification in the Postclassic population from Lamanai, Belize. Ancient Mesoamerica 17(01):139–51.
View in Google Scholar

Wilson AS, Taylor T, Ceruti MC, Chavez JA, Reinhard J, Grimes V et al. 2007. Stable isotope and DNA evidence for ritual sequences in Inca child sacrifice. Proceedings of the National Academy of Sciences 104(42):16456–61.
View in Google Scholar

Wright LE, Schwarcz HP. 1996. Infrared and isotopic evidence for diagenesis of bone apatite at Dos Pilas, Guatemala: palaeodietary implications. J Archaeol Sci 23:933–44.
View in Google Scholar

Wright LE. 2005a. Identifying immigrants to Tikal, Guatemala: defining local variability in strontium isotope ratios of human tooth enamel. J Archaeol Sci 32(4):555–66.
View in Google Scholar

Wright LE. 2005b. In search of Yax Nuun Ayiin I. Ancient Mesoamerica 16:89–100.
View in Google Scholar

Wright LE. 2012. Immigration to Tikal, Guatemala: Evidence from stable strontium and oxygen isotopes. J Anthropol Archaeol 31(3):334–52.
View in Google Scholar

Yücel Y, Sultanoğlu P. 2013. Characterization of Hatay honeys according to their multi-element analysis using ICP-OES combined with chemometrics. Food Chem 140(1):231–37.
View in Google Scholar