Fully automatic CT-histogram-based fat estimation in dead bodies

Post-mortem body cooling is the foundation of temperature-based death time estimations (TDE) in homicide cases. Forensic science generally provides two types of p.m. body cooling models, the phenomenological and the physical models. Since both of them have to implement important individual parameters like the quantity of abdominal fat explicitly or implicitly, a more exact quantification and localization of abdominal fat is a desideratum in TDE. Particularly for the physical models, a better knowledge of the abdominal fat distribution could lead to relevant improvements in TDEs. Modern imaging methods in medicine like computed tomography (CT) are opening up the possibility to register the quantity and spatial distribution of body fat in individual cases with unprecedented precision. Since a CT-scan of an individual’s abdominal region can comprise 1000 slices as an order of magnitude, it is evident that their evaluation for body fat quantification and localization needs fully automated algorithms. The paper at hand describes the development and validation of such an algorithm called “CT-histogram-based fat estimation and quasi-segmentation” (CFES). The approach can be characterized as a weighted least squares method dealing with the gray value histogram of single CT-slices only. It does not require any anatomical a priori information nor does it perform time-consuming feature detection on the CT-images. The processing result consists in numbers quantifying the amount of abdominal body fat and of muscle-, organ-, and connective tissue. As a by-product, CFES generates a quasi-segmentation of the slices processed differentiating fat from muscle-, organ-, and connective tissue. The tool is validated on synthetic data and on CT-data of a special phantom. It was also applied on a CT-scan of a dead body, where it produced anatomically plausible results.

[1]  K. Kvaal,et al.  Calibration models for lamb carcass composition analysis using Computerized Tomography (CT) imaging , 2007 .

[2]  P. Wolf,et al.  Overweight, Obesity, and Survival After Stroke in the Framingham Heart Study , 2017, Journal of the American Heart Association.

[3]  Gita Mall,et al.  Estimation of time since death by heat-flow Finite-Element model. Part I: method, model, calibration and validation. , 2005, Legal medicine.

[4]  Thorsten M. Buzug,et al.  Einführung in die Computertomographie , 2004 .

[5]  N. Otsu A threshold selection method from gray level histograms , 1979 .

[6]  K. Main,et al.  Body fat throughout childhood in 2647 healthy Danish children: agreement of BMI, waist circumference, skinfolds with dual X-ray absorptiometry , 2014, European Journal of Clinical Nutrition.

[7]  William H. Press,et al.  The Art of Scientific Computing Second Edition , 1998 .

[8]  A. Strathe,et al.  Hounsfield Unit dynamics of adipose tissue and non-adipose soft tissues in growing pigs. , 2008, Research in veterinary science.

[9]  John H. Sampson,et al.  A Novel Method for Volumetric MRI Response Assessment of Enhancing Brain Tumors , 2011, PloS one.

[10]  Stefan Zachow,et al.  Automatic CT-based finite element model generation for temperature-based death time estimation: feasibility study and sensitivity analysis , 2017, International Journal of Legal Medicine.

[11]  Robin Strand,et al.  Automated analysis of liver fat, muscle and adipose tissue distribution from CT suitable for large-scale studies , 2017, Scientific Reports.

[12]  Xavier L. Aubert,et al.  Ambulatory estimation of human circadian phase using models of varying complexity based on non-invasive signal modalities , 2014, 2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[13]  C. Henßge Die Präzision von Todeszeitschätzungen durch die mathematische Beschreibung der rektalen Leichenabkühlung , 1979, Zeitschrift für Rechtsmedizin.

[14]  F. McEvoy,et al.  Computer tomographic investigation of subcutaneous adipose tissue as an indicator of body composition , 2009, Acta veterinaria Scandinavica.

[15]  Christos P. Loizou,et al.  Segmentation of atherosclerotic carotid plaque in ultrasound video , 2012, 2012 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[16]  Estimation of Time of Death With a Fourier Series Unsteady‐State Heat Transfer Model , 2010, Journal of forensic sciences.

[17]  Michael Frankfurter,et al.  Numerical Recipes In C The Art Of Scientific Computing , 2016 .

[18]  H. Boeing,et al.  Low-dose spiral computed tomography for measuring abdominal fat volume and distribution in a clinical setting , 1998, European Journal of Clinical Nutrition.

[19]  Wolfgang Branscheid,et al.  Schlachtkörperwertbestimmung beim schwein röntgen- computertomographie als mögliche referenzmethode , 2004 .

[20]  Coert Metz,et al.  Automatic quantification of epicardial fat volume on non-enhanced cardiac CT scans using a multi-atlas segmentation approach. , 2013, Medical physics.

[21]  Gita Mall,et al.  Estimation of time since death by heat-flow Finite-Element model part II: application to non-standard cooling conditions and preliminary results in practical casework. , 2005, Legal medicine.

[22]  Matti Stenroos,et al.  Engineering in Medicine and Biology Society (EMBC), Milan, Italy, August 25-29, 2015 , 2015 .

[23]  Michael W Freckleton,et al.  Informatics in radiology (infoRAD): introduction to the language of three-dimensional imaging with multidetector CT. , 2005, Radiographics : a review publication of the Radiological Society of North America, Inc.

[24]  L. Mccargar,et al.  Accuracy of subcutaneous fat measurement: comparison of skinfold calipers, ultrasound, and computed tomography. , 1994, Journal of the American Dietetic Association.

[25]  Young Jae Kim,et al.  Body Fat Assessment Method Using CT Images with Separation Mask Algorithm , 2013, Journal of Digital Imaging.

[26]  S. Yamashita,et al.  Abdominal fat: standardized technique for measurement at CT. , 1999, Radiology.

[27]  S B Heymsfield,et al.  Cadaver validation of skeletal muscle measurement by magnetic resonance imaging and computerized tomography. , 1998, Journal of applied physiology.

[28]  C. D. Robinson,et al.  Estimators of Tissue Proportions from X‐Ray CT Images , 2002, Biometrics.

[29]  L. Sarli,et al.  Computed Tomography Volumetric Fat Parameters versus Body Mass Index for Predicting Short-term Outcomes of Colon Surgery , 2011, World Journal of Surgery.

[30]  P. Allen,et al.  Development of a computed tomographic calibration method for the determination of lean meat content in pig carcasses. , 2006, Acta veterinaria Hungarica.

[31]  Noriyuki Moriyama,et al.  Development of an automated 3D segmentation program for volume quantification of body fat distribution using CT. , 2008, Nihon Hoshasen Gijutsu Gakkai zasshi.

[32]  G. Borkan,et al.  Assessment of abdominal fat content by computed tomography. , 1982, The American journal of clinical nutrition.

[33]  Knut Kvaal,et al.  Virtual dissection of lamb carcasses using computer tomography (CT) and its correlation to manual dissection , 2008 .

[34]  I. Sinicina,et al.  Temperature based forensic death time estimation: The standard model in experimental test. , 2015, Legal medicine.

[35]  Ioannis A. Kakadiaris,et al.  Automatic Segmentation of Abdominal Fat from CT Data , 2005, 2005 Seventh IEEE Workshops on Applications of Computer Vision (WACV/MOTION'05) - Volume 1.