Enamel hypoplasia in a Mesolithic (5900±100 BC) individual from Woźna Wieś (Poland): a case study

Authors

  • Jacek Tomczyk Department of Human Ecology, Cardinal Stefan Wyszyński University, Warsaw, Poland
  • Agnieszka Ostrowska Analytical Center, Warsaw University of Life Science, Warsaw, Poland

DOI:

https://doi.org/10.2478/anre-2018-0014

Keywords:

Mesolithic, Woźna Wieś, enamel hypoplasia

Abstract

Modern anthropological research includes very sophisticated diagnostic methods. They allow us to obtain information that has not been available so far. The aim of this paper is to analyze, using current microscopic technologies, the Mesolithic dental material of one adult individual from Woźna Wieś (Poland). The present case study will focus on the analysis of enamel hypoplasia. A scanning electron microscope (SEM) was used to count the number of perikymata building on the hypoplastic line. Linear enamel hypoplasia (LEH) was diagnosed only on the right mandibular canine. The time of occurrence of environmental disturbance was estimated between about 4.2 and 4.9 years of age. The occlusal wall built the enamel hypoplasia with no more than three to four perikymata, meaning that the physiological stress had to have occurred over a fairly short period of time (about 30–40 days).

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References

Al-Nazhan S. 1991. Two root canals in a maxillary central incisor with enamel hypoplasia. J Endodon 9:469–71.
View in Google Scholar

Anthonappa RP, King NM. 2015. Enamel defects in the permanent dentition: prevalence and etiology. In BK Drummond and N Kilpatrick, editors. Planning and care for children and adolescents with dental enamel defects. Etiology, research and contemporary management. 1st edition. Berlin: Springer. 15–30.
View in Google Scholar

Berbesque JC, Doran GH. 2008. Brief communication: physiological stress in the Florida Archaic – enamel hypoplasia and patterns of developmental insult in early North American hunter-gatherers. Am J Phys Anthropol 136:351–6.
View in Google Scholar

Berbesque LC, Marlowe FW, Shaw P, Thompson P. 2014. Hunter-gatherers have less famine than agriculturalists. Biol Lett 10:20120853.
View in Google Scholar

Berbesque JC, Hoover KC. 2018. Frequency and developmental timing of linear enamel hypoplasia defects in Early Archaic Texan hunter-gatherers. PeerJ DOI:10.7717/peerj.4367.
View in Google Scholar

Clayton F, Sealy J, Pfeiffer S. 2006. Weaning age among foragers at Matjes river rock shelter, South Africa, from stable nitrogen and carbon isotope analyses. Am J Phys Anthropol 129:311–7.
View in Google Scholar

Dalitz GD. 1962. The hardness of dentine related to age. Aust Dent J 7:463–4.
View in Google Scholar

Drusini AG. 2008. The coronal pulp cavity index: A forensic tool for age determination in human adults. Cuad Med Forensic 14:235–49.
View in Google Scholar

FDI, Fédération Dentaire International. 1971. Two-digit system of designating teeth. Int Dent J 34:312.
View in Google Scholar

FDI, Fédération Dentaire International. 1982. An epidemiological index of developmental defects of dental enamel (DDE Index). Int Dent J 32:159–67.
View in Google Scholar

Fitzgerald CM, Rose JC. 2008. Reading between the lines: dental development and subadult age assessment using the microstructural growth markers of teeth. In MA Katzenberg and SR Saunders, editors. Biological anthropology of the human skeleton. 2nd edition. New Jersey: Willey&Sons. 237–63.
View in Google Scholar

Gamble JA, Boldsen JL, Hoppa RD. 2017. Stressing out in medieval Denmark: An investigation of dental enamel defects and age at death in two medieval Danish cemeteries. Int J Paleopathol 17:52–66.
View in Google Scholar

Goodman AH, Pelto GH, Allen LH, Chavez A. 1992. Socioeconomic and anthropometric correlates of linear enamel hypoplasia in children from Solis, Mexico. In: AH Goodman and LL Capasso, editors. 1st edition. Journal of Paleopathology Monographic Publications 2:373–80.
View in Google Scholar

Guatelli-Steinberg D. 2008. Using perikymata to estimate the duration of growth disruptions in fossil hominin teeth: issues of methodology and interpretation. In JD Irish and GC Nelson, editors. Technique and application in dental anthropology. 1st edition. Cambridge: Cambridge University Press. 71–86.
View in Google Scholar

Guatelli-Steinberg D, Stinespring-Harris A, Reid DJ, Larsen CS, Hutchinson DL, Smith TM. 2014. Chronology of linear enamel hypoplasia formation in the Krapina neanderthals. PaleoAnthropol 2014:431–45.
View in Google Scholar

Gustafson G. 1950. Age determination of teeth. J Am Den Assoc 41:45–54.
View in Google Scholar

Herring DA, Saunders SR, Katzenberg MA. 1998. Investigating the weaning process in past populations. Am J Phys Anthropol 105:425–39.
View in Google Scholar

Hillson S, Bond S. 1997. Relationship of enamel hypoplasia to the pattern of tooth crown growth: a discussion. Am J Phys Anthropol 104:89–103.
View in Google Scholar

Hillson S. 2002. Dental Anthropology. 3th edition. Cambridge: Cambridge University Press.
View in Google Scholar

Hillson S. 2008. Dental pathology. In MA Katzenberg and SR Saunders, editors. Biological anthropology of the human skeleton. 2nd edition. New Jersey: Willey&Sons. 301–40.
View in Google Scholar

Hillson S. 2014. Tooth development in human evolution and bioarchaeology. 1st edition. Cambridge: Cambridge University Press.
View in Google Scholar

Jackes M. 2009. Teeth and the past in Portugal: Pathology and the Mesolithic-Neolithic transition. In: T Koppe, G Meyer and KW Alt, editors. Comparative Dental Morphology. 1st edition. Basel: Karger. 167–72.
View in Google Scholar

Jankauskas R. 1994. Lithuanian Mesolithic and Neolithic graves: Date on the transition from a foraging to food-producing economy. Anthropologie 33:165–8.
View in Google Scholar

Keenleyside A, Panayotova K. 2006. Cribra orbitalia and porotic hyperostosis in a Greek colonial population (5th to 3rd centuries BC) from the Black Sea. Int J Osteoarchaeol 16: 373–84.
View in Google Scholar

King T, Hillson S, Humphrey LT. 2002. A detailed study of enamel hypoplasia in a post-medieval adolescent of known age and sex. Arch Oral Biol 47:29–39.
View in Google Scholar

King T, Humphrey LT, Hillson S. 2005. Linear enamel hypoplasias as indicators of systemic physiological stress: evidence from two know age-at-death and sex populations from postmedieval London. Am J Phys Anthropol 128:547–59.
View in Google Scholar

Kozłowski T. 1998. A Mesolithic human skeleton discovered at Kamieńskie, site 1, Orzesze commune, Suwałki province. Sprawozdania Archeologiczne 50:131–33.
View in Google Scholar

Krenz-Niedbała M, Kozłowski T. 2013. Comparing the chronological distribution of enamel hypoplasia in Rogowo, Poland (2nd century AD) using two methods of defect timing estimation. Int J Osteoarchaeol 23:410–20.
View in Google Scholar

Larsen CS. 1995. Biological changes in human populations with agriculture. Ann Rev Anthropol 24:185–213.
View in Google Scholar

Liebe-Harkort C. 2012. Cribra orbitalia, sinusitis and linear enamel hypoplasia in Swedish Roman Iron Age adults and subadults. Int J Osteoarchaeol 22:387–97.
View in Google Scholar

Lillie MC. 1996. Mesolithic and Neolithic populations of Ukraine: indications of diet from dental pathology. Curr Anthropol 37:135–42.
View in Google Scholar

Maples WR. 1978. An improved technique using dental histology for estimation of adult age. J Forensic Sci 23:784–70.
View in Google Scholar

Marlowe FW. 2005. Hunter-gatherers and human evolution. Evol Anthropol 14:54–67.
View in Google Scholar

Merrett DC, Zhang H, Xiao Z, Zhang Q, Wei D, Wang L, Zhu H, Yang DY. 2016. Enamel hypoplasia in Northeast China: Evidence from Houtaomuga. Quatern Int 405:11–21.
View in Google Scholar

Morales-Pérez JV, Salazar-Gracía DC, de Miguel Ibáňez MP, Miret i Estruch C, Jordá Pardo JF, Verdasco Cebrián CC, Pérez Ripoll M, Aura Tortosa JE. 2017. Funerary practices or food delicatessen? Human remains with anthropic marks from the Western Mediterranean Mesolithic. J Anthropol Archaeol 45:115–30.
View in Google Scholar

Nakayama N. 2016. The Relationship between linear enamel hypoplasia and social status in 18th to 19th century Edo, Japan. Int J Osteoarchaeol 26:1034–44.
View in Google Scholar

Nunn J. 2001. Nutrition and dietary challenges in oral health. Nutrition 17:426–27.
View in Google Scholar

Pȇtersone-Gordina E, Gerhards G, Jakob T. 2013. Nutrition-related health problems in a wealthy 17–18th century German community in Jelgava, Latvia. Int J Paleopathol 3:30–8.
View in Google Scholar

Pindborg JJ. 1992. Aetiology of developmental enamel defects not related to fluorosis. Int Dent J 32:123–34.
View in Google Scholar

Piontek J, Kozłowski T. 2002. Frequency of cribra orbitalia in the subadult Medieval population from Gruczno, Poland. Int J Osteoarchaeol 12:202–8
View in Google Scholar

Piontek J. 1999. Body size and proportions in the Upper Paleolithic-Neolithic transition: evidence from Central Europe. In: D Jankowska, M Krenz-Niedbała, J Piontek and J Wierzbicki, editors. Biological and cultural consequences of the transition to agriculture in Central Europe. 1st editon. Poznań: Wyd. UAM. 61–84.
View in Google Scholar

Pitsios T, Ζafiri V. 2012. Frequency and distribution of enamel hypoplasia in ancient skulls from different eras and areas in Greece. Int J Car Sci 5:179–90.
View in Google Scholar

Reid DJ, Dean MC. 2000. Brief communication: the timing of linear hypoplasias on human anterior teeth. Am J Phys Anthropol 113:135–9.
View in Google Scholar

Reid DJ, Dean MC. 2006. Variation in modern human enamel formation times. J Hum Evol 50:329–46.
View in Google Scholar

Ritzman TB, Baker BJ, Schwartz GT. 2008. A fine line: a comparison of methods for estimating ages of linear enamel hypoplasia formation. Am J Phys Anthropol 135:348–61.
View in Google Scholar

Smith BH. 1984. Patterns of molar wear in hunter-gatherers and agriculturalists. Am J Phys Anthropol 63:39–56
View in Google Scholar

Smith MO, Kurtenbach KJ, Vermaat CJ. 2016. Linear enamel hypoplasia in Schroeder Mounds (11HE177): A Late Woodland period site in Illinois. Int J Paleopathol 14:10–23.
View in Google Scholar

Smits L, van der Plicht H. 2009. Mesolithic and Neolithic human remains in the Netherlands: physical anthropological and stable isotope investigations. J Archaeol Low Count 1:55–85.
View in Google Scholar

Stanaszek ŁM, Mańkowska-Pliszka H. 2015. A New osteological analysis of Janisławice Man. Tagungen des Lanndesmuseums für Vorgeschichte Halle 13:1–8.
View in Google Scholar

Suckling GW, Herbison P, Brown RH. 1987. Etiological factors influencing the prevalence of developmental defects of dental enamel in nine–year–old New Zealand children participating in a health and development study. J Dent Res 66:1466–9.
View in Google Scholar

Sulgostowska Z. 1990. Pochowek mezolityczny z okresu atlantyckiego w Woźnej Wsi, woj. Łomżyńskie. Archeologia Polski 35:47–56.
View in Google Scholar

Sullivan A. 2005. Prevalence and etiology of acquired anemia in Medieval York, England. Am J Phys Anthropol 128:252–72.
View in Google Scholar

Šlaus M, Bedić Ž, Šikanjić PR, Vodanović M, Kunić AD. 2011. Dental health at the transition from the Late Antique to the early Medieval period on Croatia’s eastern Adriatic Coast. Int J Osteoarchaeol 21:577–90.
View in Google Scholar

Temple DH. 2010. Patterns of systematic stress during the agricultural transition in prehistoric Japan. Am J Phys Anthropol 142:112–24.
View in Google Scholar

Terberger T, Kotula A, Lorenz S, Schult M, Burger J, Jungklaus B. 2015.Standing upright to all eternity – The Mesolithic burial site at Groß Fredenwalde, Brandenburg (NE Germany). Quartär 62:133–53.
View in Google Scholar

Tomczyk J, Tomczyk-Gruca M, Zalewska M. 2012, Frequency and chronological distribution of linear enamel hypoplasia (LEH) in the Late Neolithic and Early Bronze Age population from Żerniki Górne (Poland) – preliminary report. Anthropol Rev 75:61–73.
View in Google Scholar

Tomczyk J. 2016. Biological transformation among historical populations that inhabited the Syrian Lower Euphrates Valley: from the Early Bronze Age to the modern period. In JA Daniels, editor. Advances in environmental research Vol.50. 1st edition. New York: Nova Science Publishers. 139–75.
View in Google Scholar

Tomczyk J, Myszka A, Borowska-Strugińska B, Zalewska M, Turska-Szybka A, Olczak-Kowalczyk D. 2018. Periodontitis in the historical population of Radom (Poland) from the 11th to 19th centuries. Int J Osteorachaeol DOI:10.1002/oa.2664.
View in Google Scholar

Ungar PS, Crittenden AN, Rose JC. 2017. Toddlers in transition: linear enamel hypoplasias in the Hadza of Tanzania. Int J Osteoarchaeol 27:638–49.
View in Google Scholar

Witzel C, Kierdorf U, Schultz M, Kierdorf H. 2008. Insights from the inside: histological analysis of abnormal enamel microstructure associated with hypoplastic enamel defects in human teeth. Am J Phys Anthropolo 136:400–14.
View in Google Scholar

Wood JW, Milner GR, Harpending HC, Weiss KM. 1992. The osteological paradox. Problems of inferring prehistoric health from skeletal samples. Curr Anthropol 33:343–70.
View in Google Scholar

Wright LE, Yoder CJ. 2003. Recent progress in bioarchaeology: approaches to the osteological paradox. J Archaeol Res 11:43–70.
View in Google Scholar

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Published

2018-06-30

How to Cite

Tomczyk, J., & Ostrowska, A. (2018). Enamel hypoplasia in a Mesolithic (5900±100 BC) individual from Woźna Wieś (Poland): a case study. Anthropological Review, 81(2), 191–201. https://doi.org/10.2478/anre-2018-0014

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