Top

Published in:

01-05-2015 | Original Article

Sex estimation from the tarsal bones in a Portuguese sample: a machine learning approach

Authors: David Navega, Ricardo Vicente, Duarte N. Vieira, Ann H. Ross, Eugénia Cunha

Published in: International Journal of Legal Medicine | Issue 3/2015

Abstract

Sex estimation is extremely important in the analysis of human remains as many of the subsequent biological parameters are sex specific (e.g., age at death, stature, and ancestry). When dealing with incomplete or fragmented remains, metric analysis of the tarsal bones of the feet has proven valuable. In this study, the utility of 18 width, length, and height tarsal measurements were assessed for sex-related variation in a Portuguese sample. A total of 300 males and females from the Coimbra Identified Skeletal Collection were used to develop sex prediction models based on statistical and machine learning algorithm such as discriminant function analysis, logistic regression, classification trees, and artificial neural networks. All models were evaluated using 10-fold cross-validation and an independent test sample composed of 60 males and females from the Identified Skeletal Collection of the 21st Century. Results showed that tarsal bone sex-related variation can be easily captured with a high degree of repeatability. A simple tree-based multivariate algorithm involving measurements from the calcaneus, talus, first and third cuneiforms, and cuboid resulted in 88.3 % correct sex estimation both on training and independent test sets. Traditional statistical classifiers such as the discriminant function analysis were outperformed by machine learning techniques. Results obtained show that machine learning algorithm are an important tool the forensic practitioners should consider when developing new standards for sex estimation.

Bruzek J (2002) A method for visual determination of sex, using the human hip bone. Am J Phys Anthropol 117:157–168CrossRefPubMed

Murail P, Bruzek J, Houët F, Cunha E (2005) DSP: A tool for probabilistic sex diagnosis using worldwide variability in hip-bone measurements. Bull Mém Société D’Anthropologie Paris 167–176

Franklin D, Cardini A, Flavel A, Kuliukas A (2012) The application of traditional and geometric morphometric analyses for forensic quantification of sexual dimorphism: preliminary investigations in a Western Australian population. Int J Legal Med 126:549–558CrossRefPubMed

Macaluso PJ Jr, Lucena J (2014) Estimation of sex from sternal dimensions derived from chest plate radiographs in contemporary Spaniards. Int J Legal Med 128:389–395CrossRefPubMed

Ross AH, Ubelaker DH, Kimmerle EH (2011) Implications of dimorphism, population variation, and secular change in estimating population affinity in the Iberian Peninsula. Forensic Sci Int 206(214):e1–e5PubMed

Masotti S, Succi-Leonelli E, Gualdi-Russo E (2013) Cremated human remains: is measurement of the lateral angle of the meatus acusticus internus a reliable method of sex determination? Int J Legal Med 127:1039–1044CrossRefPubMed

Tuller H, Đurić M (2006) Keeping the pieces together: comparison of mass grave excavation methodology. Forensic Sci Int 156:192–200CrossRefPubMed

Bidmos MA, Asala SA (2004) Sexual dimorphism of the calcaneus of South African blacks. J Forensic Sci 49:446–450PubMed

Harris SM, Case DT (2012) Sexual dimorphism in the tarsal bones: implications for sex determination. J Forensic Sci 57:295–305CrossRefPubMed

10.

Steele DG (1976) The estimation of sex on the basis of the talus and calcaneus. Am J Phys Anthropol 45:581–588CrossRefPubMed

11.

Riepert T, Drechsler T, Schild H, Nafe B, Mattern R (1996) Estimation of sex on the basis of radiographs of the calcaneus. Forensic Sci Int 77:133–140CrossRefPubMed

12.

Gualdi-Russo E (2007) Sex determination from the talus and calcaneus measurements. Forensic Sci Int 171:151–156CrossRefPubMed

13.

Wilbur AK (1998) The utility of hand and foot bones for the determination of sex and the estimation of stature in a prehistoric population from west-central Illinois. Int J Osteoarchaeol 8:180–191CrossRef

14.

Murphy AMC (2002) The calcaneus: sex assessment of prehistoric New Zealand Polynesian skeletal remains. Forensic Sci Int 129:205–208CrossRefPubMed

15.

Murphy AMC (2002) The talus: sex assessment of prehistoric New Zealand Polynesian skeletal remains. Forensic Sci Int 128:155–158CrossRefPubMed

16.

Murphy AMC (2005) The articular surfaces of the hindfoot: sex assessment of prehistoric New Zealand Polynesian skeletal remains. Forensic Sci Int 151:19–22CrossRefPubMed

17.

Bidmos MA, Dayal MR (2004) Further evidence to show population specificity of discriminant function equations for sex determination using the talus of South African blacks. J Forensic Sci 49:1165–1170PubMed

18.

Bidmos MA, Dayal MR (2003) Sex determination from the talus of South African whites by discriminant function analysis. Am J Forensic Med Pathol 24:322–328CrossRefPubMed

19.

Bidmos MA, Asala SA (2003) Discriminant function sexing of the calcaneus of the South African whites. J Forensic Sci 48:1213–1218PubMed

20.

Chao-Ying Joanne Peng T-SHS (2002) Logistic regression analysis and reporting: a primer. Underst Stat Education:31–70

21.

Moss GP, Shah AJ, Adams RG, Davey N, Wilkinson SC, Pugh WJ, Sun Y (2012) The application of discriminant analysis and machine learning methods as tools to identify and classify compounds with potential as transdermal enhancers. Eur J Pharm Sci Off J Eur Fed Pharm Sci 45:116–127

22.

Du Jardin P, Ponsaillé J, Alunni-Perret V, Quatrehomme G (2009) A comparison between neural network and other metric methods to determine sex from the upper femur in a modern French population. Forensic Sci Int 192(127):e1–e6PubMed

23.

Mahfouz M, Badawi A, Merkl B, Fatah EEA, Pritchard E, Kesler K, Moore M, Jantz R, Jantz L (2007) Patella sex determination by 3D statistical shape models and nonlinear classifiers. Forensic Sci Int 173:161–170CrossRefPubMed

24.

Hefner JT, Ousley SD (2014) Statistical classification methods for estimating ancestry using morphoscopic traits. J Forensic Sci n/a–n/a

25.

Mitchell TM (1997) Machine learning. McGraw Hill, Burr Ridge

26.

Witten IH, Frank E, Hall MA (2011) Data mining: practical machine learning tools and techniques. Elsevier, New York

27.

Hastie T, Tibshirani R, Friedman J (2009) The elements of statistical learning: data mining, inference, and prediction, second edition. Springer, New YorkCrossRef

28.

McBride DG, Dietz MJ, Vennemeyer MT, Meadors SA, Benfer RA, Furbee NL (2001) Bootstrap methods for sex determination from the os coxae using the ID3 algorithm. J Forensic Sci 46:427–431PubMed

29.

Moore MK, Schaefer E (2011) A comprehensive regression tree to estimate body weight from the skeleton. J Forensic Sci 56:1115–1122CrossRefPubMed

30.

Corsini M-M, Schmitt A, Bruzek J (2005) Aging process variability on the human skeleton: artificial network as an appropriate tool for age at death assessment. Forensic Sci Int 148:163–167CrossRefPubMed

31.

Buk Z, Kordik P, Bruzek J, Schmitt A, Snorek M (2012) The age at death assessment in a multi-ethnic sample of pelvic bones using nature-inspired data mining methods. Forensic Sci Int 220(294):e1–294.e9PubMed

32.

Hefner JT, Spradley MK, Anderson B (2014) Ancestry assessment using random forest modeling. J Forensic Sci 59:583–589CrossRefPubMed

33.

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

34.

Duda RO, Hart PE, Stork DG (2000) Pattern classification, 2nd edn. Wiley, New York

35.

Bishop CM (2006) Pattern recognition and machine learning. Springer, New York

36.

Fielding A (2007) Cluster and classification techniques for the biosciences. Cambridge University Press, Cambridge

37.

Hall M, Frank E, Holmes G, Pfahringer B, Reutemann P, Witten IH (2009) The WEKA data mining software: an update. SIGKDD Explor Newsl 11:10–18CrossRef

38.

Spradley MK, Jantz RL (2011) Sex estimation in forensic anthropology: skull versus postcranial elements. J Forensic Sci 56:289–296CrossRefPubMed

Title: Sex estimation from the tarsal bones in a Portuguese sample: a machine learning approach
Authors: David Navega
Ricardo Vicente
Duarte N. Vieira
Ann H. Ross
Eugénia Cunha
Publication date: 01-05-2015
Publisher: Springer Berlin Heidelberg
Published in: International Journal of Legal Medicine / Issue 3/2015
Print ISSN: 0937-9827
Electronic ISSN: 1437-1596
DOI: https://doi.org/10.1007/s00414-014-1070-5

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Sex estimation from the tarsal bones in a Portuguese sample: a machine learning approach

Abstract

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 3/2015

Alagille syndrome case report: implications for forensic pathology and anthropology

The auditory ossicles as a DNA source for genetic identification of highly putrefied cadavers

Postmortem CT morphometry of great vessels with regard to the cause of death for investigating terminal circulatory status in forensic autopsy

Is the persistence of an epiphyseal scar of the knee a reliable marker of biological age?

Different degrees of ischaemic injury in the right and left ventricle in cases of severe, nonfatal, pulmonary embolism

Age estimation based on pictures and videos presumably showing child or youth pornography