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Nasty, Brutish, but Not Necessarily Short: A Reconsideration of the Statistical Methods Used to Calculate Age at Death from Adult Human Skeletal and Dental Age Indicators

Published online by Cambridge University Press:  20 January 2017

Robert G. Aykroyd ,
David Lucy ,
A. Mark Pollard  and
Charlotte A. Roberts
Robert G. Aykroyd
Affiliation:
Department of Statistics, School of Mathematics, University of Leeds, Leeds LS2 9JT, England
David Lucy
Affiliation:
Department of Archaeological Sciences, University of Bradford, Bradford BD7 1DP, England
A. Mark Pollard
Affiliation:
Department of Archaeological Sciences, University of Bradford, Bradford BD7 1DP, England
Charlotte A. Roberts
Affiliation:
Department of Archaeological Sciences, University of Bradford, Bradford BD7 1DP, England
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Abstract

It is generally assumed that life expectancy in antiquity was considerably shorter than it is now. In the limited number of cases where skeletal or dental age-at-death estimates have been made on adults for whom there are other reliable indications of age, there appears to be a clear systematic trend towards overestimating the age of young adults, and underestimating that of older individuals. We show that this might be a result of the use of regression-based techniques of analysis for converting age indicators into estimated ages. Whilst acknowledging the limitations of most age-at-death indicators in the higher age categories, we show that a Bayesian approach to converting age indicators into estimated age can reduce this trend of underestimation at the older end. We also show that such a Bayesian approach can always do better than regression-based methods in terms of giving a smaller average difference between predicted age and known age, and a smaller average 95-percent confidence interval width of the estimate. Given these observations, we suggest that Bayesian approaches to converting age indicators into age estimates deserve further investigation. In view of the generality and flexibility of the approach, we also suggest that similar algorithms may have a much wider application.

Résumé

Résumé

Está generalmente aceptado el postulado de que la expectativa de vida en la Antigüedad fue considerablemente más corta que la de ahora. En algunos casos, cuando era posible comprobar la edad estimada de adultos al momento de su muerte según el esqueleto y la dentadura era posible comprobarla con otros indicadores fiables de su edad, se nota una clara tendencia metodológica hacia la sobreestimación de la edad de adultos jóvenes y hacia la subestimación de edad en personas mayores. Demostramos que aquello puede ser resultado de la aplicación de técnicas de análisis que se utilizan para convertir indicadores de edad en edades estimadas. Reconociendo las limitaciones de la mayoría de los indicadores para determinar la edad en el momento de la muerte para las personas pertenecientes a las categorías de edades avanzadas, demostramos que el método Bayes utilizado para convertir indicadores de edad en la edad estimada, puede reducir tales tendencias de subestimación a edades avanzadas. Demostramos también que un método como el de Bayes siempre es mejor que cualquier método basado en la regresión, asegurando un menor promedio de diferencia entre la edad pronosticada y la edad conocida, así como el menor promedio de un confianza de 95% intervalo de amplitud de estimatión. Tomando en consideratión esas observaciones, proponemos que los métodos Bayes para recalcular los indicadores de edad en la edad estimada merezcan una investigatión adicional. Teniendo en cuenta la universalidad y la flexibilidad del método, pronosticamos también que los algoritmos similares puedan tener una aplicación mucho más amplia.

Type
Reports
Information
American Antiquity , Volume 64 , Issue 1 , January 1999 , pp. 55 - 70
Copyright
Copyright © The Society for American Archaeology 1999

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References

References Cited

Aiello, L. C., and Molleson, T. 1993 Are Microscopic Ageing Techniques more Accurate than Macroscopic Ageing Techniques? Journal of Archaeological Science 20: 689704.CrossRefGoogle Scholar
Aykroyd, R. G., Lucy, D., Pollard, A. M., and Solheim, T. 1997 Regression Analysis in Adult Age Estimation. American Journal of Physical Anthropology 104: 259265.3.0.CO;2-Z>CrossRefGoogle ScholarPubMed
Bang, G., and Ramm, E. 1970 Determination of Age in Humans from Root Dentine Transparency. Acta Odontologica Scandinavica 28: 335.CrossRefGoogle Scholar
Bedford, M. E., Russell, K. F., Lovejoy, C. O., Meindl, R. S., 1993 Test of the Multifactorial Aging Method using Skeletons with Known Ages-at- Death from the Grant Collection. American Journal of Physical Anthropology 91: 287297.CrossRefGoogle ScholarPubMed
Boddington, A. 1987 From Bones to Population: the Problem of Numbers. In Death, Decay, and Reconstruction: Approaches to Archaeology and Forensic Science, edited by Boddington, A., Garland, A. N., and Janaway, R. C., pp. 179197. Manchester University Press, Manchester.Google Scholar
Brooks, S., and Suchey, J. M. 1990 Skeletal Age Determination Based on the Os Pubis: Comparison of the Ascadi-Nemeskeri and Suchey-Brooks Methods. Human Evolution 5: 227238.CrossRefGoogle Scholar
Brothwell, D. R. 1981 Digging up Bones. British Museum (Natural History), London.Google Scholar
Brothwell, D. R. 1989 Relationship of Tooth Wear to Aging. In Age Markers in the Human Skeleton, edited by Iscan, M. Y., pp. 303316. Charles Thomas, Springfield, Illinois.Google Scholar
Buikstra, J. E., and Ubelaker, D. H. (editors) 1994 Standards for Data Collection in Human Skeletal Remains. Research Series 44. Arkansas Archaeological Survey, Fayetteville.Google Scholar
Carolan, V. A., Gardner, M. L. G., Lucy, D., and Pollard, A. M. 1997 Consideration of Age Estimation Errors in the Use of Amino Acid Racemization in Human Dentine as an Indicator of Age at Death. Journal of Forensic Sciences 42: 1016.CrossRefGoogle ScholarPubMed
Dudar, J. C. 1994 Identification of Rib Number and Assessment of Intercostal Variation at the Sternal Rib End. Journal of Forensic Sciences 38: 788797.Google Scholar
Dudar, J. C, Pfeiffer, S., and Saunders, S. R. 1993 Evaluation of Morphological and Histological Adult Skeletal Age-at-Death Estimation Techniques using Ribs. Journal of Forensic Sciences 38: 677685.CrossRefGoogle ScholarPubMed
Gilbert, B. M. and McKern, T. W. 1973 A Method for Aging the Female Os Pubis. American Journal of Physical Anthropology 38: 3138.CrossRefGoogle ScholarPubMed
Gillard, R. D., Hardman, S. M., Pollard, A. M., Sutton, P. A., 1991 Determinations of Age at Death in Archaeological Populations using the D/L Ratio of Aspartic Acid in Dental Collagen. In Archaeometry ‘90, edited by Pemicka, E. and Wagner, G.A. pp. 637644. Birkhauser Verlag, Berlin.Google Scholar
Goldstein, M. S. 1953 Some Vital Statistics Based on Skeletal Material. Human Biology 25: 312.Google ScholarPubMed
Gustafson, G. 1950 Age Determination on Teeth. Journal of the American Dental Association 41: 4554.CrossRefGoogle ScholarPubMed
Hedges, J. W. 1982 An Archaeodemographical Perspective on Isbister. Scottish Archaeological Review 1: 520.Google Scholar
Hoadley, B. 1970 A Bayesian Look at Inverse Linear Regression. Journal of the American Statistical Association 65: 356369.CrossRefGoogle Scholar
Hooton, E. A. 1930 The Indians of Pecos Pueblo. A Study of Their Skeletal Remains. Papers of the Phillips Academy Southwestern Expedition, No. 4. Yale University Press, New Haven.Google Scholar
Howell, N. 1982 Village Composition Implied by a Paleodemographic Life Table: The Libben Site. American Journal of Physical Anthropology 59: 263269.CrossRefGoogle Scholar
Iscan, M. Y, and Loth, S. R. 1989 Osteological Manifestations of Age in the Adult. In Reconstruction of Life from the Skeleton, edited by Iscan, M. Y. and A, K.. Kennedy, R., pp. 2340. Alan Liss, New York.Google Scholar
Iscan, M. Y, and Loth, S. R. 1971 Age Determinations from Human Teeth. Odontologisk Revy 22: Supplement 2.Google Scholar
Katz, D., and Suchey, J. M. 1986 Age Determination of the Male Os Pubis. American Journal of Physical Anthropology 69: 427135.CrossRefGoogle ScholarPubMed
Kerley, E. R. 1965 The Microscopic Determination of Age in Human Bone. American Journal of Physical Anthropology 23: 149164.CrossRefGoogle ScholarPubMed
Konigsberg, L. W., and Frankenberg, S. R. 1992 Estimation of Age Structure in Anthropological Demography. American Journal of Physical Anthropology 89: 235256.CrossRefGoogle ScholarPubMed
Konigsberg, L. W., Frankenberg, S. R., and Walker, R. B. 1997 Regress What on What?: Paleodemographic Age Estimation as a Calibration Problem. In Integrating Archaeological Demography: Multidisciplinary Approaches to Prehistoric Population, edited by Paine, R. R., pp. 6488. Occasional Paper No. 24. Center for Archaeological Investigations, Southern Illinois University, Carbondale.Google Scholar
Litton, C. D. and Buck, C. E. 1995 The Bayesian Approach to the Interpretation of Archaeological Data. Archaeometry 37: 124.CrossRefGoogle Scholar
Loth, S. R. 1995 Age Assessment of the Spitalfields Cemetery Population by Rib Phase-Analysis. American Journal of Human Biology 7: 465471.CrossRefGoogle ScholarPubMed
Loth, S.R., and Iscan, M.Y. 1989 Morphological Assessment of Age in the Adult: The Thoracic Region. In Age Markers in the Human Skeleton, edited by Isean, M. Y., pp. 105135. Charles Thomas, Springfield, Illinois.Google Scholar
Loth, S. R., Iscan, M. Y., and Scheuerman, E. H. 1994 Intercostal Variation at the Sternal Rib End. Forensic Science International 65: 135143.CrossRefGoogle Scholar
Lovejoy, C. O. 1985 Dental Wear in the Libben Population: Its Functional Pattern and Role in the Determination of Adult Skeletal Age at Death. American Journal of Physical Anthropology 68: 4756.CrossRefGoogle ScholarPubMed
Lovejoy, C. O., Meindl, R. S., Pryzbeck, T. R., Barton, T. S., 1977 Palaeodemography of the Libben Site, Ottawa County, Ohio. Science 198: 291293.CrossRefGoogle Scholar
Lovejoy, C. O., Meindl, R. S., Mensforth, R. P., and Barton, T. J. 1985 Multifactorial Determination of Skeletal Age at Death: A Method and Blind Tests of its Accuracy. American Journal of Physical Anthropology 68: 114.CrossRefGoogle Scholar
Lucy, D., and Pollard, A. M. 1995 Further Comments on the Estimation of Error Associated with the Gustafson Dental Age Estimation Method. Journal of Forensic Sciences 40: 222227.CrossRefGoogle ScholarPubMed
Lucy, D., Aykroyd, R. G., Pollard, A. M., and Solheim, T. 1996 A Bayesian Approach to Adult Human Age Estimation from Dental Observations by Johanson's Age Changes. Journal of Forensic Sciences 41: 189194.CrossRefGoogle ScholarPubMed
Lucy, D. 1997 Human Age Estimation from Skeletal and Dental Evidence. Ph.D. dissertation, Department of Archaeological Sciences, University of Bradford, Bradford, England.Google Scholar
Macchiarelli, R., and Bondioli, L. 1994 Linear Densitometry and Digital Image Processing of Proximal Femur Radiographs: Implications for Archaeological and Forensic Anthropology. American Journal of Physical Anthropology 93: 109122.CrossRefGoogle ScholarPubMed
Mann, R. W. 1993 A Method for Siding and Sequencing Ribs. Journal of Forensic Science 8: 151155.Google Scholar
Maples, W. R. 1989 The Practical Application of Age-Estimation Techniques. In Age Markers in the Human Skeleton, edited by Iscan, M. Y., pp. 319324. Charles Thomas, Springfield, Illinois.Google Scholar
Masset, C. 1989 Age Estimation on the Basis of Cranial Sutures. In Age Markers in the Human Skeleton, edited by Iscan, M. Y., pp. 71103. Charles Thomas, Springfield, Illinois.Google Scholar
McKern, T. W., and Stewart, T. D. 1957 The Inominate Bone. In Skeletal Age Changes in Young American Males Analysed from the Standpoint of Identification, edited by T. W McKern and T. D. Stewart, pp. 5388. Technical Report EP-45. U.S. Army Headquarters Quartermaster's Research and Development Command, Natwick, Massachusetts.CrossRefGoogle Scholar
Meindl, R. S., and Lovejoy, C. O. 1985 Ectocranial Suture Closure—A Revised Method for the Determination of Skeletal Age at Death Based on the Lateral-Anterior Sutures. American Journal of Physical Anthropology 68: 5766.CrossRefGoogle ScholarPubMed
Meindl, R. S., Lovejoy, C. O., Mensforth, R. P., 1985 A Revised Method of Age-Determination using the Os Pubis, with a Review and Tests of Accuracy of Other Current Methods of Pubic Symphyseal Aging. American Journal of Physical Anthropology 68: 2915.CrossRefGoogle ScholarPubMed
Molleson, T., Cox, M., Waldron, A. H., and Whittaker, D. K. 1993 77ie Spitalfields Report. Volume 2. The Anthropology: The Middling Sort. CBA Research Report 86. Council for British Archaeology, York.Google Scholar
Murray, K., and Murray, T. 1991 A Test of the Auricular Surface Aging Technique. Journal of Forensic Sciences 36: 11621169.CrossRefGoogle ScholarPubMed
Nathan, H. 1962 Osteophytes of the Vertebral Column. An Anatomical Study of their Development According to Age, Race, and Sex with Considerations as to their Etiology and Significance. Journal of Bone and Joint Surgery 44A: 243268.CrossRefGoogle Scholar
Owings Webb, P. A. O., and Suchey, J. M. 1985 Epiphyseal Union of the Anterior Iliac Crest and Medial Clavicle in a Modern Multiracial Sample of American Males and Females. American Journal of Physical Anthropology 68: 457466.CrossRefGoogle Scholar
Pollard, A.M., and Heron, C. 1996 Archaeological Chemistry. Royal Society of Chemistry, Cambridge.CrossRefGoogle Scholar
Reece, R. 1994 Are Bayesian Statistics Useful to Archaeological Reasoning? Antiquity 68: 848850.CrossRefGoogle Scholar
Ruff, C. B. 1981 A Reassessment of Demographic Estimates for Pecos Pueblo. American Journal of Physical Anthropology 54: 147151.CrossRefGoogle Scholar
Russell, K. F., Simpson, S. W., Genovese, J., Kinkel, M. D., 1993 Independent Test of the 4th Rib Aging Technique. American Journal of Physical Anthropology 92: 5362.CrossRefGoogle ScholarPubMed
Saunders, S. R., Fitzgerald, C., Rogers, T., Dudar, C., 1992 A Test of Several Methods of Skeletal Age Estimation using a Documented Archaeological Sample. Canadian Society of Forensic Science 25: 97118.CrossRefGoogle Scholar
Silverman, B. B. 1986 Density Estimation for Statistics and Data Analysis. Chapman and Hall, London.Google Scholar
Sorg, M. H., Andrews, R. P., and Iscan, M. Y. 1989 Radiographic Aging in the Adult. In Age Markers in the Human Skeleton, edited by Iscan, M. Y., pp. 169193. Charles Thomas, Springfield, Illinois.Google Scholar
Stewart, T. D. 1958 The Rate of Development of Vertebral Osteoarthritis in American Whites and its Significance in Skeletal Age Identification. The Leech 28: 144151.Google Scholar
Stout, S. 1992 Methods of Determining Age at Death using Bone Microstructure. In Skeletal Biology of Past Peoples, edited by Saunders, S. and Katzenberg, A., pp. 2135. Wiley-Liss, New York.Google Scholar
Todd, T. W 1920 Age Changes in the Pubic Bone. I: The Male White Pubis. American Journal of Physical Anthropology 3: 285334.CrossRefGoogle Scholar
Todd, T. W 1921a Age Changes in the Pubic Bone. II: The Pubis of the Negro-White Hybrid; III: The Pubis of the White Female; IV: The Pubis of the Female Negro-White Hybrid. American Journal of Physical Anthropology 4: 170.CrossRefGoogle Scholar
Todd, T. W 1921b Age Changes in the Pubic Bone. VI: Interpretation of Variations in the Symphyseal Area. American Journal of Physical Anthropology 4: 407424.CrossRefGoogle Scholar
Waldron, T. 1994 Counting the Dead. The Epidemiology of Skeletal Populations. John Wiley and Sons, New York.Google Scholar
Walker, P. L., Dean, G., and Shapiro, P. 1991 Estimating Age from Tooth Wear in Archaeological Populations. In Advances in Dental Anthropology, edited by Kelley, M. A. and Larsen, C.S. pp. 169178, Wiley-Liss, New York.Google Scholar
Walker, R. A., and Lovejoy, C. O. 1985 Radiographic Changes in the Clavicle and Proximal Femur and Their Use in Determination of Skeletal Age at Death. American Journal of Physical Anthropology 68: 6778.CrossRefGoogle ScholarPubMed
Wood, J. W., Milner, G. R., Harpending, H. C., and Weiss, K. M. 1992 The Osteological Paradox. Problems of Inferring Health from Skeletal Samples. Current Anthropology 33: 343370.CrossRefGoogle Scholar