CT-scan vs. 3D surface scanning of a skull: first considerations regarding reproducibility issues

ABSTRACT Three-dimensional surface scanning (3DSS) and multi-detector computed tomography (MDCT) are two techniques that are used in legal medicine for digitalizing objects, a body or body parts such as bones. While these techniques are more and more commonly employed, surprisingly little information is known about the quality rendering of digitalized three-dimensional (3D) models provided by each of them. This paper presents findings related to the measurement precision of 3D models obtained through observation of a study case, where a fractured skull reconstructed by an anthropologist was digitalized using both post-mortem imaging methods. Computed tomography (CT) scans were performed using an 8-row MDCT unit with two different slice thicknesses. The variability of 3D CT models superimposition allowed to assess the reproducibility and robustness of this digitalization technique. Furthermore, two 3D surface scans were done using a professional high resolution 3D digitizer. The comparison of 3D CT-scans with 3D surface scans by superimposition demonstrated several regions with significant differences in topology (average difference between +1.45 and −1.22 mm). When comparing the reproducibility between these two digitalizing techniques, it appeared that MDCT 3D models led in general to greater variability for measurement precision between scanned surfaces. Also, the reproducibility was better achieved with the 3D surface digitizer, showing 3D models with fewer and less pronounced differences (from +0.32 to −0.31 mm). These experiments suggest that MDCT provides less reproducible body models than 3D surface scanning. But further studies must be undertaken in order to corroborate this first impression, and possibly explain the reason for these findings.

[1]  S. Grabherr,et al.  Performance of post-mortem CT compared to autopsy in children , 2016, International Journal of Legal Medicine.

[2]  M. Thali,et al.  Essentials of forensic post-mortem MR imaging in adults. , 2014, The British journal of radiology.

[3]  Kyra E Stull,et al.  Accuracy and reliability of measurements obtained from computed tomography 3D volume rendered images. , 2014, Forensic science international.

[4]  Anders Ynnerman,et al.  Full Body Virtual Autopsies using a State-of-the-art Volume Rendering Pipeline , 2006, IEEE Transactions on Visualization and Computer Graphics.

[5]  Tanya Uldin,et al.  Virtual anthropology: a comparison between the performance of conventional X-ray and MDCT in investigating the trabecular structure of long bones. , 2013, Forensic science international.

[6]  Lorenzo Campana,et al.  The examination and identification of bite marks in foods using 3D scanning and 3D comparison methods , 2011, International Journal of Legal Medicine.

[7]  Michael J Thali,et al.  Application of 3D documentation and geometric reconstruction methods in traffic accident analysis: with high resolution surface scanning, radiological MSCT/MRI scanning and real data based animation. , 2007, Forensic science international.

[8]  Y. Donchin,et al.  Utility of postmortem computed tomography in trauma victims. , 1994, The Journal of trauma.

[9]  J. Fasel,et al.  Evaluating Preoperative Models: A Methodologic Contribution. , 2016, World neurosurgery.

[10]  R. Martin,et al.  Computer‐assisted paleoanthropology , 1998 .

[11]  M. Thali,et al.  Optical 3D surface digitizing in forensic medicine: 3D documentation of skin and bone injuries. , 2003, Forensic science international.

[12]  Hisao Ito,et al.  Evaluation of Computed Tomography as a Screening Test for Death Inquest , 2010, Journal of forensic sciences.

[13]  Daniel Rougé,et al.  Virtual anthropology and forensic identification: report of one case. , 2007, Forensic science international.

[14]  R Knapp,et al.  Skull of a 5,300-year-old mummy: reproduction and investigation with CT-guided stereolithography. , 1994, Radiology.

[15]  Maren Lindstaedt,et al.  COMPARATIVE GEOMETRICAL INVESTIGATIONS OF HAND-HELD SCANNING SYSTEMS , 2016 .

[16]  G. Weber,et al.  Virtual anthropology (VA): A call for Glasnost in paleoanthropology , 2001, The Anatomical record.

[17]  F. Boas,et al.  CT artifacts: Causes and reduction techniques , 2012 .

[18]  C. Boesch,et al.  Virtopsy, a new imaging horizon in forensic pathology: virtual autopsy by postmortem multislice computed tomography (MSCT) and magnetic resonance imaging (MRI)--a feasibility study. , 2003, Journal of forensic sciences.

[19]  P. Mangin,et al.  Virtuelle vs. reale forensische bildgebende Verfahren , 2015, Rechtsmedizin.

[20]  Tomoya Kobayashi,et al.  Background and current status of postmortem imaging in Japan: short history of "Autopsy imaging (Ai)". , 2013, Forensic science international.

[21]  Michael J Thali,et al.  Accident or homicide--virtual crime scene reconstruction using 3D methods. , 2013, Forensic science international.

[22]  Domínguez Alejandro,et al.  Postmortem computed tomography angiography vs. conventional autopsy: advantages and inconveniences of each method , 2013, International Journal of Legal Medicine.

[23]  Michael J Thali,et al.  'Morphological imprint': determination of the injury-causing weapon from the wound morphology using forensic 3D/CAD-supported photogrammetry. , 2003, Forensic science international.

[24]  Lorenzo Campana,et al.  3D documentation and visualization of external injury findings by integration of simple photography in CT/MRI data sets (IprojeCT) , 2015, International Journal of Legal Medicine.

[25]  E. Fishman,et al.  Volume rendering versus maximum intensity projection in CT angiography: what works best, when, and why. , 2006, Radiographics : a review publication of the Radiological Society of North America, Inc.

[26]  Michael J Thali,et al.  VIRTOPSY: minimally invasive, imaging-guided virtual autopsy. , 2006, Radiographics : a review publication of the Radiological Society of North America, Inc.

[27]  G. Weber,et al.  Virtual anthropology. , 2015, American journal of physical anthropology.

[28]  Christian Jackowski,et al.  Advances of dual source, dual-energy imaging in postmortem CT. , 2008, European journal of radiology.

[29]  F. Joffre,et al.  New identification possibilities with postmortem multislice computed tomography , 2007, International Journal of Legal Medicine.

[30]  Michael J. Thali,et al.  Estimation of sex and age of “virtual skeletons”–a feasibility study , 2009, European Radiology.

[31]  P. Mangin,et al.  Application of contrast media in post-mortem imaging (CT and MRI) , 2015, La radiologia medica.

[32]  Michael J Thali,et al.  Digital forensic osteology--possibilities in cooperation with the Virtopsy project. , 2008, Forensic science international.

[34]  S. Prasad,et al.  Price of isotropy in multidetector CT. , 2007, Radiographics : a review publication of the Radiological Society of North America, Inc.

[35]  Olivier Delémont,et al.  An exploratory study toward the contribution of 3D surface scanning for association of an injury with its causing instrument , 2018, International Journal of Legal Medicine.

[36]  F. Dedouit,et al.  Application a la thanatologie de l’imagerie en coupe: revue iconographique , 2006 .