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International Journal of Legal Medicine

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31.01.2019 | Original Article

3D analysis of computed tomography (CT)–derived lumbar spine models for the estimation of sex

verfasst von: Summer J. Decker, Robert Foley, Joshua M. Hazelton, Jonathan M. Ford

Erschienen in: International Journal of Legal Medicine | Ausgabe 5/2019

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Abstract

When skeletal remains are found scattered or in fragmentary conditions, the establishment of a biological profile of unknown individuals can be proven difficult. Consequently, multiple methods to ascertain the sex of the individual must be developed. The purpose of this study was to demonstrate that computed tomographic (CT)–derived 3D models of lumbar vertebrae could capture the unique morphologies of all five lumbar vertebrae to create equations for sex identification. The models were selected from a modern population consisting of 154 males and females that measured 30 standard linear measurements, the vertebral body wedging angle, and five aspect ratios. These measurements were then used to develop discriminant function equations for sex identification. Each lumbar level was analyzed individually as well as part of the entire lumbar spinal column. The results of this study showed that L1–L5 vertebrae can be used in sex determination with an 81.2–85.1% accuracy. When all five vertebrae are used in conjunction, the accuracy is 92.2%. The accuracy of the sex estimation found in this study for all lumbar vertebrae reinforces the distinct dimorphism between sexes while also providing forensic practitioners with more options or tools for their analyses.

Iscan MY, Steyn M (2013) The human skeleton in forensic medicine. Charles C Thomas Publisher, Springfield

Haas J, Buikstra JE, Ubelaker DH, Aftandilian D, History FMN, Survey AA (1994) Standards for data collection from human skeletal remains: proceedings of a seminar at the field museum of natural history, organized by Jonathan Haas. Arkansas Archeological Survey, Fayetteville

Brooks S, Suchey JM (1990) Skeletal age determination based on the os pubis: a comparison of the Acsádi-Nemeskéri and Suchey-Brooks methods. Hum Evol 5:227–238CrossRef

France DL (1998) Observational and metric analysis of sex in the skeleton. In: Reichs KJ (ed) Forensic osteology: Advances in the identification of human remains, Charles C. Thomas, Springfield, p 163–186

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

Byard RW, James RA, Gilbert JD (2002) Diagnostic problems associated with cadaveric trauma from animal activity. Am J Forensic Med Pathol 23:238–244CrossRef

Crainic K, Paraire F, Leterreux M, Durigon M, De Mazancourt P (2002) Skeletal remains presumed submerged in water for three years identified using PCR-STR analysis. J Forensic Sci 47:1–3CrossRef

Rutty GN, Robinson C, Morgan B, Black S, Adams C, Webster P (2009) Fimag: the United Kingdom disaster victim/forensic identification imaging system. J Forensic Sci 54:1438–1442CrossRef

Rutty GN, Robinson CE, BouHaidar R, Jeffery AJ, Morgan B (2007) The role of mobile computed tomography in mass fatality incidents. J Forensic Sci 52:1343–1349PubMed

10.

Holland TD (1986) Sex determination of fragmentary crania by analysis of the cranial base. Am J Phys Anthropol 70:203–208CrossRef

11.

Kelley MA (1979) Sex determination with fragmented skeletal remains. J Forensic Sci 24:154–158CrossRef

12.

Frutos LR (2005) Metric determination of sex from the humerus in a Guatemalan forensic sample. Forensic Sci Int 147:153–157CrossRef

13.

İşcan MY, Loth SR, King CA, Shihai D, Yoshino M (1998) Sexual dimorphism in the humerus: a comparative analysis of Chinese, Japanese and Thais. Forensic Sci Int 98:17–29CrossRef

14.

İşcan MY, Shihai D (1995) Sexual dimorphism in the Chinese femur. Forensic Sci Int 74:79–87CrossRef

15.

Özer I, Katayama K, Sahgir M, Güleç E (2006) Sex determination using the scapula in medieval skeletons from East Anatolia. Coll Antropol 30:415–419PubMed

16.

Özer Ý, Katayama K (2008) Sex determination using the femur in an ancient Japanese population. Coll Antropol 32:67–72PubMed

17.

Falsetti AB (1995) Sex assessment from metacarpals of the human hand. J Forensic Sci 40:774–776CrossRef

18.

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

19.

Rogers TL (1999) A visual method of determining the sex of skeletal remains using the distal humerus. J Forensic Sci 44:57–60CrossRef

20.

Rogers TL (2009) Sex determination of adolescent skeletons using the distal humerus. Am J Phys Anthropol 140:143–148CrossRef

21.

Rösing FW, Graw M, Marré B et al (2007) Recommendations for the forensic diagnosis of sex and age from skeletons. HOMO-J Comparative Human Biol 58:75–89CrossRef

22.

Garn SM (1970) The earlier gain and the later loss of cortical bone, in nutritional perspective. Thomas, Springfield

23.

Seeman E (2001) Sexual dimorphism in skeletal size, density, and strength. J Clin Endocrinol Metab 86:4576–4584CrossRef

24.

Allbright AS (2007) Sexual dimorphism in the vertebral column.

25.

Marino EA (1995) Sex estimation using the first cervical vertebra. Am J Phys Anthropol 97:127–133CrossRef

26.

Wescott DJ (2000) Sex variation in the second cervical vertebra. J Forensic Sci 45:462–466CrossRef

27.

Yu SB, Lee UY, Kwak DS et al (2008) Determination of sex for the 12th thoracic vertebra by morphometry of three-dimensional reconstructed vertebral models. J Forensic Sci 53:620–625. https://doi.org/10.1111/j.1556-4029.2008.00701.x CrossRef

28.

Zheng WX, Cheng FB, Cheng KL et al (2012) Sex assessment using measurements of the first lumbar vertebra. Forensic Sci Int 219(285):e1–e5. https://doi.org/10.1016/j.forsciint.2011.11.022

29.

Ostrofsky KR, Churchill SE (2015) Sex determination by discriminant function analysis of lumbar vertebrae. J Forensic Sci 60:21–28. https://doi.org/10.1111/1556-4029.12543 CrossRef

30.

Frykberg ER (2002) Medical management of disasters and mass casualties from terrorist bombings: how can we cope? J Trauma Acute Care Surg 53:201–212CrossRef

31.

Hay O, Dar G, Abbas J et al (2015) The lumbar lordosis in males and females, revisited. PloS one 10:e0133685CrossRef

32.

Bailey JF, Sparrey CJ, Been E, Kramer PA (2016) Morphological and postural sexual dimorphism of the lumbar spine facilitates greater lordosis in females. J Anat 229:82–91CrossRef

33.

Ramsthaler F, Kettner M, Gehl A, Verhoff M (2010) Digital forensic osteology: morphological sexing of skeletal remains using volume-rendered cranial CT scans. Forensic Sci Int 195:148–152CrossRef

34.

Decker SJ, Davy-Jow SL, Ford JM, Hilbelink DR (2011) Virtual determination of sex: metric and nonmetric traits of the adult pelvis from 3D computed tomography models. J Forensic Sci 56:1107–1114CrossRef

35.

Uysal S, Gokharman D, Kacar M, Tuncbilek I, Kosar U (2005) Estimation of sex by 3D CT measurements of the foramen magnum. J Forensic Sci 50:JFS2005058–JFS2005055

36.

Inamori-Kawamoto O, Ishikawa T, Michiue T et al (2016) Possible application of CT morphometry of the calcaneus and talus in forensic anthropological identification. Int J Legal Med 130:575–585CrossRef

37.

Djorojevic M, Roldán C, García-Parra P, Alemán I, Botella M (2014) Morphometric sex estimation from 3D computed tomography os coxae model and its validation in skeletal remains. Int J Legal Med 128:879–888CrossRef

38.

Reid A, Schneider-Kolsky ME, O’Donnell CJ (2008) Comparison of computed radiography and multi-detector computed tomography in the detection of post mortem metacarpal index. Forensic Sci Int 177:192–198CrossRef

39.

Ford JM, Decker SJ (2016) Computed tomography slice thickness and its effects on three-dimensional reconstruction of anatomical structures. J Forensic Radiol Imaging 4:43–46CrossRef

40.

Verhoff MA, Ramsthaler F, Krähahn J et al (2007) Digital forensic osteology. Forensic Sci Int 169:S47CrossRef

41.

Ekizoglu O, Inci E, Erdil I et al (2016) Computed tomography evaluation of the iliac crest apophysis: age estimation in living individuals. Int J Legal Med 130:1101–1107CrossRef

42.

Janssen I, Heymsfield SB, Wang Z, Ross R (2000) Skeletal muscle mass and distribution in 468 men and women aged 18–88 yr. J Appl Physiol 89:81–88CrossRef

Titel: 3D analysis of computed tomography (CT)–derived lumbar spine models for the estimation of sex
verfasst von: Summer J. Decker
Robert Foley
Joshua M. Hazelton
Jonathan M. Ford
Publikationsdatum: 31.01.2019
Verlag: Springer Berlin Heidelberg
Erschienen in: International Journal of Legal Medicine / Ausgabe 5/2019
Print ISSN: 0937-9827
Elektronische ISSN: 1437-1596
DOI: https://doi.org/10.1007/s00414-019-02001-8

Springer Medizin

3D analysis of computed tomography (CT)–derived lumbar spine models for the estimation of sex

Abstract

Neu im Fachgebiet Rechtsmedizin

Molekularpathologische Untersuchungen im Wandel der Zeit

Vergleichende Pathologie in der onkologischen Forschung

Gastrointestinale Stromatumoren

Personalisierte Medizin in der Onkologie

Springer Medizin

Abstract

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