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Between Roundhouse and Villa: Assessing Perinatal and Infant Burials from Piddington, Northamptonshire

Published online by Cambridge University Press:  11 May 2017

Claire M. Hodson*
Affiliation:
Department of Archaeology, Durham [email protected]

Abstract

The discovery of perinatal and infant individuals is common in the excavation of Iron Age and Romano-British domestic sites. In recent years, the discovery of many such burials has led to interpretations of infanticide and unceremonious disposal. Although this has been a widely discussed phenomenon, much of the literature has focused on the funerary context, and the biological age and sex estimates of these individuals, with little consideration of the palaeopathological evidence. This article provides a detailed analysis of 17 perinates/infants from the late Iron Age/early Roman site of Piddington, Northants. It discusses the skeletal evidence for poor health and growth, and highlights the potential of these remains to reveal alternative insights into perinatal and infant death. Evidence of growth changes and pathological lesions were identified, suggesting that these individuals experienced chronic episodes of poor health that affected their skeletal development. The study explores the implications of these findings within the context of Iron Age and Roman Britain. At Piddington, the death of these infants is not associated with the cultural practice of infanticide, but occurred due to poor health, highlighting the precarious nature of infant survival in the past.

Type
Articles
Copyright
Copyright © The Author(s) 2017. Published by The Society for the Promotion of Roman Studies 

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References

BIBLIOGRAPHY

Abu-Saad, K., and Fraser, D. 2010: ‘Maternal nutrition and birth outcomes’, Epidemiological Review 32, 525Google Scholar
AlQahtani, S.J., Hector, M.P., and Liversidge, H.M. 2010: ‘The London atlas of human tooth development and eruption’, American Journal of Physical Anthropology 142, 481–90Google Scholar
Armelagos, G.J., Goodman, R.H., Harper, K.N., and Blakey, M.L. 2009: ‘Enamel hypoplasia and early mortality: bioarchaeological support for the Barker hypothesis’, Evolutionary Anthropology 18, 261–71Google Scholar
Aufderheide, A.C., and Rodriguez-Martín, C. 2008: The Cambridge Encyclopedia of Human Palaeopathology, CambridgeGoogle Scholar
Barker, D.J. 1997: ‘Maternal nutrition, fetal nutrition, and disease in later life’, Nutrition 13, 807–13Google Scholar
Barker, D.J. 2012: ‘Developmental origins of chronic disease’, Public Health 126, 185–9Google Scholar
Becker, M.J. 2006: ‘The archaeology of infancy and childhood; integrating and expanding research into the past’, American Journal of Archaeology 110.4, 655–8Google Scholar
Beilke-Voigt, I. 2008: ‘Burials of children in houses and settlements during the Roman Iron Age and early medieval period in northern Germany and Denmark’, in Dommasnes and Wrigglesworth 2008, 1635Google Scholar
Bogin, B. 1999: Patterns of Human Growth (2nd edn), CambridgeGoogle Scholar
Bogin, B., and Loucky, J. 1997: ‘Plasticity, political economy, and physical growth status of Guatemala Maya children living in the United States’, American Journal of Physical Anthropology 102, 1732Google Scholar
Bogin, B., Smith, P., Orden, A.B., Varela Silva, M.I., and Loucky, J. 2002: ‘Rapid change in height and body proportions of Maya American children’, American Journal of Human Biology 14, 753–61Google Scholar
Brickley, M., and Ives, R. 2006: ‘Skeletal manifestations of infantile scurvy’, American Journal of Physical Anthropology 29, 163–72Google Scholar
Cameron, N., and Bogin, B. 2012: Human Growth and Development (2nd edn), LondonGoogle Scholar
Cameron, N., and Demerath, E.W. 2002: ‘Critical periods in human growth and their relationship to diseases of aging’, Yearbook of Physical Anthropology 45, 159–84Google Scholar
Carroll, M. 2011: ‘Infant death and burial in Roman Italy’, Journal of Roman Archaeology 24, 99120Google Scholar
Carroll, M. 2012: ‘“No part in earthly things”. The death, burial and commemoration of newborn children and infants in Roman Italy’, in Harlow and Larsson Loven 2012, 41–63Google Scholar
Carroll, M., and Graham, E.-J. (eds) 2014: Infant Health and Death in Roman Italy and Beyond, Journal of Roman Archaeology Supplementary Series 96, Portsmouth, RIGoogle Scholar
Dancause, K.N., Cao, X.J., Veru, F., Xu, S., Long, H., Yu, C., Laplante, D.P., Walker, C.D., and King, S. 2012: ‘Prenatal and early postnatal stress exposure influences long bone length in adult rat offspring’, American Journal of Physical Anthropology 149, 307–11Google Scholar
Davies, D., Gardner, A., and Lockyear, K. (eds) 2001: TRAC 2000: Proceedings of the Tenth Annual Theoretical Roman Archaeology Conference, OxfordGoogle Scholar
Dommasnes, L.H., and Wrigglesworth, M. (eds) 2008: Children, Identity and the Past, NewcastleGoogle Scholar
Fazekas, I.G., and Kósa, F. 1978: Forensic Foetal Osteology, BudapestGoogle Scholar
Garn, S.M., Lewis, A.B., and Polacheck, D.L. 1960: ‘Interrelations in dental development. I. Interrelationships within the dentition’, Journal of Dental Research 39, 1049–55Google Scholar
Gowland, R.L. 2001: ‘Playing dead: implications of mortuary evidence for the social construction of childhood in Roman Britain’, in Davies et al. 2001, 152–68Google Scholar
Gowland, R.L. 2004: ‘The social identity of health in late Roman Britain’, in Croxford, B., Eckardt, H., Meade, J. and Weekes, J. (eds), TRAC 2003: Proceedings of the Thirteenth Annual Theoretical Roman Archaeology Conference, Oxford, 135–46Google Scholar
Gowland, R.L. 2015: ‘Entangled lives: implications of the developmental origins of health and disease hypothesis for bioarchaeology and the life course’, American Journal of Physical Anthropology 158, 530–40Google Scholar
Gowland, R.L., and Chamberlain, A.T. 2002: ‘A Bayesian approach to ageing perinatal skeletal material from archaeological sites: implications for the evidence for infanticide in Roman-Britain’, Journal of Archaeological Science 29, 677–85Google Scholar
Gowland, R.L., Chamberlain, A.T., and Redfern, R.C. 2014: ‘On the brink of being: re-evaluating infant death and infanticide in Roman Britain’, in Carroll and Graham 2014, 6988Google Scholar
Griffin, R., Pitts, M., Smith, R., and Brook, A. 2011: ‘Inequality at late Roman Baldock, UK. The impact of social factors on health and diet’, Journal of Anthropological Research 67, 533–56Google Scholar
Harding, J.E., and Johnston, B.M. 1995: ‘Nutrition and fetal growth’, Reproduction, Fertility and Development 7.3, 539–48Google Scholar
Harlow, M., and Larsson Loven, L. (eds) 2012: Families in the Roman and Late Antique World, LondonGoogle Scholar
Heinke, D., and Kuzawa, C.W. 2008: ‘Self-reported illness and birth weight in the Philippines: implications for hypotheses of adaptive fetal plasticity’, American Journal of Human Biology 20, 538–44Google Scholar
Heneage Cocks, A. 1921: ‘A Romano-British homestead in the Hambleden Valley, Buckinghamshire’, Archaeologia 71, 141–66Google Scholar
Hillson, S.W. 1979: ‘Diet and dental disease’, World Archaeology 11.2, Food and Nutrition, 147–62Google Scholar
Hillson, S.W. 2005: Teeth (2nd edn), CambridgeGoogle Scholar
Hillson, S.W. 2014: Tooth Development in Human Evolution and Bioarchaeology, CambridgeGoogle Scholar
Hoffman, C. 2016: ‘Stress, the placenta, and fetal programming of behaviour: genes’ first encounter with the environment’, American Journal of Psychiatry 173, 655–7Google Scholar
Hopkins, K. 1983: Death and Renewal, CambridgeGoogle Scholar
Lewis, M.E. 2004: ‘Endocranial lesions in non-adult skeletons: understanding their aetiology’, International Journal of Osteoarchaeology 14, 8297Google Scholar
Lewis, M.E. 2007: The Bioarchaeology of Children: Perspectives from Biological and Forensic Anthropology, CambridgeGoogle Scholar
Maresh, M.M. 1970: ‘Measurements from roentgenograms’, in McCammon, R.W. (ed.), Human Growth and Development, Springfield, 157200Google Scholar
Massler, M., and Schour, I. 1944: Atlas of the Mouth and Adjacent Parts in Health and Disease, ChicagoGoogle Scholar
Mays, S. 1993: ‘Infanticide in Roman Britain’, Antiquity 67, 883–8Google Scholar
Mays, S. 2000: ‘The archaeology and history of infanticide, and its occurrence in earlier British populations’, in Sofaer Derevenski, J. (ed.), Children and Material Culture, London, 180–90Google Scholar
Mays, S., and Eyers, J. 2011: ‘Perinatal infant death at the Roman villa site at Hambleden, Buckinghamshire, England’, Journal of Archaeological Science 38, 1931–8Google Scholar
Mays, S., and Faerman, M. 2001: ‘Sex identification of some putative infanticide victims from Roman Britain using ancient DNA’, Journal of Archaeological Science 28, 555–9Google Scholar
Meade, J. 2010: The Middle and Upper Ouse Valley in the Late Iron Age and Romano-British Periods: Divergent Identities?, BAR British Series 512, OxfordGoogle Scholar
Miller, Z.E.S. 2012: ‘The infant burials from Piddington: a case study of differential infant burial’, in Friendship-Taylor, R.M. and Friendship-Taylor, D.E. (eds), Iron Age and Roman Piddington: Human Burials of the Late Iron Age/Early Roman Infants, Cremations and Anglo-Saxon Burials from the Piddington Romano-British Villa, The Upper Nene Archaeological Society 2012, Fascicule 12, 3768Google Scholar
Millett, M., and Gowland, R. 2015: ‘Infant and child burial rites in Roman Britain: a study from East Yorkshire’, Britannia 46, 171–89Google Scholar
Molleson, T.I. 1999: ‘Archaeological evidence for attitudes to disability in the past’, Archaeological Review from Cambridge 15, 6972Google Scholar
Moore, A. 2009: ‘Hearth and home: the burial of infants within Romano-British domestic contexts’, Childhood in the Past 2, 3354Google Scholar
Moorrees, C.F.A., Fanning, E.A., and Hunt, E.E. 1963a: ‘Formation and resorption of three deciduous teeth in children’, American Journal of Physical Anthropology 21, 205–13Google Scholar
Moorrees, C.F.A., Fanning, E.A., and Hunt, E.E. 1963b: ‘Age variation of formation stages for ten permanent teeth’, Journal of Dental Research 42, 1490–502Google Scholar
Non, A.L., Hollister, B.M., Humphreys, K.L., Childebayeva, A., Esteves, K., Zeanah, C.H., Fox, N.A., Nelson, C.A., and Drury, S.S. 2016: ‘DNA methylation at stress-related genes is associated with exposure to early life institutionalization’, American Journal of Physical Anthropology 161, 8493Google Scholar
Ortner, D.J. 2003: Identification of Pathological Conditions in Human Skeleton Remains, San DiegoGoogle Scholar
Ortner, D.J., and Ericksen, M.F. 1997: ‘Bone changes in the human skull probably resulting from scurvy in infancy and childhood’, International Journal of Osteoarchaeology 7, 212–20Google Scholar
Ortner, D.J., Kimmerle, E.H., and Dies, M. 1999: ‘Probable evidence of scurvy in subadults from archaeological sites in Peru’, American Journal of Physical Anthropology 108, 321–31Google Scholar
Pearce, J. 1999: ‘The dispersed dead: preliminary observations on burial and settlement space in rural Roman Britain’, in Baker, P., Forcey, C., Jundi, S. and Witcher, R. (eds), TRAC 98: Proceedings of the Eighth Annual Theoretical Roman Archaeology Conference: Leicester 1998, Oxford, 151–62Google Scholar
Pearce, J. 2001: ‘Infants, cemeteries and communities in the Roman provinces’, in Davies et al. 2001, 125–42Google Scholar
Rawson, B. 1986: ‘Children in the Roman familia’, in Rawson, B. (ed.), The Family in Ancient Rome: New Perspectives, New York, 170200Google Scholar
Rawson, B. 2003: Children and Childhood in Roman Italy, OxfordGoogle Scholar
Redfern, R.C. 2007: ‘The influence of culture upon childhood: an osteological study of Iron Age and Romano-British Dorset’, in Harlow, M. and Laurence, R. (eds), Age and Ageing in the Roman Empire, Journal of Roman Archaeology Supplementary Series 64, Portsmouth, RI, 171–94Google Scholar
Redfern, R.C., and DeWitte, S.N. 2011: ‘A new approach to the study of Romanization in Britain: a regional perspective of cultural change in Late Iron Age and Roman Dorset using the Siler and Gompertz-Makeham models of mortality’, American Journal of Physical Anthropology 144, 269–85Google Scholar
Redfern, R.C., and Gowland, R.L. 2012: ‘A bioarchaeological perspective on the pre-adult stages of the life course: implications for the care and health of children in the Roman Empire’, in Harlow and Larsson Loven 2012, 111–40Google Scholar
Redfern, R.C., Millard, A.R., and Hamlin, C. 2012: ‘A regional investigation of subadult dietary patterns and health in late Iron Age and Roman Dorset, England’, Journal of Archaeological Science 39, 1249–59Google Scholar
Roberts, C., and Manchester, K. 2010: The Archaeology of Disease, StroudGoogle Scholar
Ruff, C.B., Garofalo, E., and Holmes, M.A. 2013: ‘Interpreting skeletal growth in the past from a functional and physiological perspective’, American Journal of Physical Anthropology 150, 2937Google Scholar
Sandman, C.A., Glynn, L.M., and Poggi Davis, E. 2016: ‘Neurobehavioral consequences of fetal exposure to gestational stress’, in Reissland, N. and Kisilevsky, B.S. (eds), Fetal Development: Research on Brain and Behavior, Environmental Influences, and Emerging Technologies, Switzerland, 229–65Google Scholar
Schaefer, M., Black, S., and Scheuer, L. 2009: Juvenile Osteology: A Laboratory and Field Manual, LondonGoogle Scholar
Scheuer, L., and Black, S. 2000: Developmental Juvenile Osteology, OxfordGoogle Scholar
Scheuer, L., Musgrave, J.H., and Evans, S.P. 1980: ‘The estimation of late fetal and perinatal age from limb bone length by linear and logarithmic regression’, Annals of Human Biology 7.3, 257–65Google Scholar
Schour, I., and Massler, M. 1941: ‘The development of the human dentition’, Journal of the American Dental Association 28, 1153–60Google Scholar
Scott, E. 1991: ‘Animal and infant burials in Romano-British villas: revitalization movement’, in Garwood, P., Jennings, D., Skeates, R. and Toms, J. (eds), Sacred and Profane: Proceedings of a Conference on Archaeology, Ritual and Religion, Oxford 1989, Oxford University Committee for Archaeology Monograph 32, Oxford, 115–21Google Scholar
Scott, E. 1999: The Archaeology of Infancy and Infant Death, BAR International Series 819, OxfordGoogle Scholar
Shrader, R.E., and Zemen, F.J. 1973: ‘Skeletal development in rats as affected by maternal protein deprivation and postnatal food supply’, The Journal of Nutrition 103, 792801Google Scholar
Smith, B.H. 1991: ‘Standards of human tooth formation and dental age assessment’, in Kelley, M.A. and Larsen, C.S. (eds), Advances in Dental Anthropology, New York, 143–68Google Scholar
Smith, S.L., and Buschang, P.H. 2004: ‘Variation in longitudinal diaphyseal long bone growth in children three to ten years of age’, American Journal of Human Biology 16, 648–57Google Scholar
Tanner, J.M. 1978: Foetus into Man: Physical Growth from Conception to Maturity, LondonGoogle Scholar
Thorsell, A., and Nätt, D. 2016: ‘Maternal stress and diet may influence affective behavior and stress-response in offspring via epigenetic regulation of central peptidergic function’, Environmental Epigenetics 2.3, 110Google Scholar
Ubelaker, D.H. 1978: Human Skeletal Remains: Excavation, Analysis, Interpretation, ChicagoGoogle Scholar
Webster, J. 2005: ‘Archaeologies of slavery and servitude: bringing “New World” perspectives to Roman Britain’, Journal of Roman Archaeology 18, 161–79Google Scholar
White, T.D., and Folkens, P.A. 2005: The Human Bone Manual, LondonGoogle Scholar
Wiedemann, T. 1989: Adults and Children in the Roman Empire, AbingdonGoogle Scholar
Wu, G., Imhoff-Kunsch, B., and Webb Girard, A. 2012: ‘Biological mechanisms for nutritional regulation of maternal health and fetal development’, Paediatric and Perinatal Epidemiology 26.1, 426Google Scholar