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01-09-2014 | Original Article

Age estimation of immature human skeletal remains from the diaphyseal length of the long bones in the postnatal period

Authors: Hugo F. V. Cardoso, Joana Abrantes, Louise T. Humphrey

Published in: International Journal of Legal Medicine | Issue 5/2014

Abstract

Age at death in immature human skeletal remains has been estimated from the diaphyseal length of the long bones, but few studies have actually been designed specifically for the purpose of age estimation and those which have, show important caveats. This study uses regression and classical calibration to model the relationship between age and diaphyseal length of the six long bones, in a sample of 184 known sex and age individuals (72 females and 112 males), younger than 13 years of age, selected from Portuguese and English skeletal collections. Age estimation models based on classical calibration were obtained for each of the six long bones, and separately for each sex and for the sexes combined, and also for the entire sample and when it is subdivided into two subsamples at the age of 2 years. Comparisons between inverse and classical calibration show there is a systematic bias in age estimations obtained from inverse calibration. In the classical calibration models, the length of the femur provides the most accurate estimates of age. Age estimates are more accurate for the male subsample and for individuals under the age of 2 years. These results and a test of previously published methods caution against inverse calibration as a technique for developing age estimation methods even from the immature skeleton. Age estimation methods developed using cemetery collections of identified human skeletons should not be uncritically applied to present-day populations from the same region since many populations have experienced dramatic secular trends in growth and adult height over the last century.

Ubelaker DH (1987) Estimating age at death from immature human skeletons: an overview. J Forensic Sci 32(5):1254–1263PubMed

Lewis AB, Garn SM (1960) The relationship between tooth formation and other maturational factors. Angle Orthod 30:70–77

Lewis M, Flavel A (2006) Age assessment of child skeletal remains in forensic contexts. In: Schmitt A, Cunha E, Pinheiro J (eds) Forensic anthropology and medicine: complementary sciences from recovery to cause of death. Humana Press, New Jersey, pp 243–257CrossRef

Cardoso HFV (2007) Environmental effects on skeletal versus dental development: using a documented subadult skeletal sample to test a basic assumption in human osteological research. Am J Phys Anthropol 132:223–233PubMedCrossRef

Ferembach D, Schwidetzky I, Stloukal M (1980) Recommendations for age and sex diagnoses of skeletons. J Hum Evol 9:517–549CrossRef

Rösing FW, Graw M, Marré B, Ritz-Timme S, Rothschild MA, Rötzscher K, Schmeling A, Schröder I, Geserick G (2007) Recommendations for the forensic diagnosis of sex and age from skeletons. Homo 58:75–89PubMedCrossRef

Cunha E, Baccino E, Martrille L, Ramsthaler F, Prieto J, Schuliar Y, Lynnerup N, Cattaneo C (2009) The problem of aging human remains and living individuals: a review. Forensic Sci Int 193:1–13PubMedCrossRef

Franklin D (2010) Forensic age estimation in human skeletal remains: current concepts and future directions. Legal Med 12:1–7PubMedCrossRef

Maresh MM (1943) Growth of major long bones in healthy children. A preliminary report on successive roentgenograms of the extremities from early infancy to twelve years of age. Am J Dis Child 66:227–257CrossRef

10.

Maresh MM (1955) Linear growth of the long bones of extremities from infancy through adolescence. Am J Dis Child 89:725–742

11.

Maresh MM (1970) Measurements from roentgenograms. In: McCannon RW (ed) Human growth and development. Springfield, Illinois, pp 157–188

12.

Ghantus MK (1951) Growth of the shaft of the human radius and ulna during the first two years of life. Am Hum Biol 12:129–148

13.

Anderson M, Messener MB, Green WT (1964) Distribution of lengths of the normal femur and tibia in children from one to eighteen years of age. J Bone Joint Surg 46-A:1197–202

14.

Gindhart PS (1973) Growth standards for the tibia and radius in children aged one month through eighteen years. Am J Phys Anthropol 39:41–48PubMedCrossRef

15.

Johnston FE (1962) Growth of the long bones of infants and young children at Indian Knoll. Am J Phys Anthropol 20:249–254PubMedCrossRef

16.

Walker PL (1969) The linear growth of the long bones in late woodland Indian children. Proc Indiana Acad Sci 78:83–87

17.

Stloukal M, Hanáková H (1978) Die Länge der Längsknochen altslawischer Bevölkerungen unter besonderer Berücksichtigung von Wachstumsfragen. Homo 29:53–69

18.

Sundick RI (1978) Human skeletal growth and age determination. Homo 29:228–249

19.

Hoppa RD (1992) Evaluating human skeletal growth: an Anglo-Saxon example. Int J Osteoarchaeol 2:275–288CrossRef

20.

Fazekas IG, Kosa F (1978) Forensic fetal osteology. Akademiai Kiado, Budapest

21.

Stewart TD (1976) Identification by the skeletal structures. In: Camps FE (ed) Gradwohl’s legal medicine. Wright, Bristol, pp 123–154

22.

Hoffman JM (1979) Age estimations from diaphyseal lengths: two months to twelve years. J Forensic Sci 24:461–469PubMed

23.

Facchini F, Veschi S (2004) Age determination on long bones in a skeletal subadults samples (b–12 years). Coll Anthropol 1:89–98

24.

Rissech C, Schaefer M, Malgosa A (2008) Development of the femur—implications for age and sex determination. Forensic Sci Int 180:1–9PubMedCrossRef

25.

Rissech C, López-Costa O, Turbón D (2013) Humeral development from neonatal period to skeletal maturity—application in age and sex assessment. Int J Legal Med 127:201–212PubMedCrossRef

26.

López-Costas O, Rissech C, Trancho G, Turbón D (2012) Postnatal ontogenesis of the tibia. Implications for age and sex estimation. Forensic Sci Int 214:207.e1–11CrossRef

27.

Danforth ME, Wrobel GD, Armstrong CW, Swanson D (2009) Juvenile age estimation using diaphyseal long bone lengths among ancient Maya populations. Soc Am Arch 20:3–13

28.

Boccone S, Cremasco MM, Bortoluzzi S, Moggi-Cecchi J, Massa ER (2010) Age estimation in subadult Egyptian remains. Homo 61:337–358PubMedCrossRef

29.

Primeau C, Friis L, Sejrsen B, Lynnerup N (2012) A method for estimating age of Danish medieval sub-adults based on long bone length. Antrop Anz 69:317–333CrossRef

30.

Smith SL, Buschang PH (2005) Longitudinal models of long bone growth during adolescence. Am J Hum Biol 17:731–745PubMedCrossRef

31.

Smith SL, Buschang PH (2004) Variation in longitudinal diaphyseal long bone growth in children three to ten years of age. Am J Hum Biol 16:648–657PubMedCrossRef

32.

Aykroyd RG, Lucy D, Pollard AM, Solheim T (1997) Technical note: regression analysis in adult age estimation. Am J Phys Anthropol 104:259–265PubMedCrossRef

33.

Konigsberg LW, Frankenberg SR, Walker RB (1994) Regress what on what?: paleodemographic age estimation as a calibration problem. In: Paine RR (ed) Integrating archaeological demography: multidisciplinary approaches to prehistoric population. Southern Illinois University, Carbondale, pp 64–88

34.

Lucy D, Pollard A (1995) Further comments on the estimation of error associated with the Gustafson dental age estimation method. J Forensic Sci 40:222–227PubMed

35.

Lucy D (2005) Introduction to statistics for forensic scientists. Wiley, England, pp 75–93

36.

Cardoso HFV (2006) Brief communication: the collection of identified human skeletons housed at the Bocage museum (National Museum of Natural History), Lisbon, Portugal. Am J Phys Anthropol 129:173–176PubMedCrossRef

37.

Molleson T, Cox M, Waldron AH, Whittaker DK (1993) The Spitalfields project, Vol. 2: the anthropology: the middling sort. Council for British Archaeology, York

38.

Scheuer JL, Bowman JE (1995) Correlation of documentary and skeletal evidence in the St. Bride’s crypt population. In: Saunders SR, Herring A (eds) Grave reflections: portraying the past trough cemetery studies. Canadian Scholars’ Press, Toronto, pp 49–70

39.

Buikstra J, Ubelaker D (1994) Standards for data collection from human skeletal remains. Arkansas Archeological Survey, Arkansas

40.

Ulijaszek SJ, Kerr DA (1999) Anthropometric measurement error and the assessment of nutritional status. Br J Nutr 82:165–177PubMedCrossRef

41.

Humphrey LT (2003) Linear growth variation in the archaeological record. In: Thompson JL, Krovitz GE and Nelson AJ (eds) Patterns of growth variation in the genus Homo. Cambridge University Press, Cambridge, pp 144–169

42.

Huxley AK (1998) Analysis of shrinkage in human fetal diaphyseal lengths from fresh to dry bone using Petersohn and Kohler’s data. J Forensic Sci 43:423–426PubMed

43.

Scheuer J, Musgrave J, Evans S (1980) The estimation of late fetal and perinatal age from limb bone length by linear and logarithmic regression. Ann Hum Biol 7:257–65PubMedCrossRef

44.

Sherwood RJ, Meindl RS, Robinson HB, May RL (2000) Fetal age: methods of estimation and effects of pathology. Am J Phys Anthropol 113:305–315PubMedCrossRef

45.

Carneiro C, Curate F, Borralho P, Cunha E (2013) Radiographic fetal osteometry: approach on age estimation for the portuguese population. Forensic Sci Int. doi:10.1016/j.forsciint.2013.05.039 PubMed

46.

Humphrey L (2000) Growth studies of past populations: an overview and an example. In: Cox M, Mays S (eds) Human osteology in archaeology and forensic sciences. Greenwich Medical Media Ltd, London, pp 23–38

47.

Cole TJ (2000) Secular trends in growth. Proc Nutr Soc 59:317–324PubMedCrossRef

48.

Susanne C, Bodzsar E, Bielicki T, Hauspie B, Hulanicka B, Lepage Y, Rebato E, Vercauteren M (2001) Changements séculaires de la croissance et du développement en Europe. Antropo 0:71–90

49.

Cardoso HFV (2008) Secular changes in body height and weight of portuguese boys over one century. Am J Hum Biol 20:270–277PubMedCrossRef

50.

Cameron N (1979) The growth of London school children 1904–1966: an analysis of secular trend and intra-county variation. Ann Hum Biol 6:505–525PubMedCrossRef

51.

Saunders SR, Hoppa RD (1993) Growth deficit in survivors and non-survivors: biological mortality bias in subadult skeletal samples. Phys Anthropol 36:127–151CrossRef

52.

Rebato E (1998) The studies on secular trend in Spain: a review. In: Bodzsar E, Susanne C (eds) Secular growth changes in Europe. Eötvös University Press, Budapest, pp 279–317

Title: Age estimation of immature human skeletal remains from the diaphyseal length of the long bones in the postnatal period
Authors: Hugo F. V. Cardoso
Joana Abrantes
Louise T. Humphrey
Publication date: 01-09-2014
Publisher: Springer Berlin Heidelberg
Published in: International Journal of Legal Medicine / Issue 5/2014
Print ISSN: 0937-9827
Electronic ISSN: 1437-1596
DOI: https://doi.org/10.1007/s00414-013-0925-5

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Age estimation of immature human skeletal remains from the diaphyseal length of the long bones in the postnatal period

Abstract

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