Showing posts with label forensics. Show all posts
Showing posts with label forensics. Show all posts

Monday, 5 February 2018

UHCW publication: Micro-CT for quantitative toolmark analysis of sharp force trauma to bone

The cutting edge - Micro-CT for quantitative toolmark analysis of sharp force trauma to bone.
Norman, D G; Watson, D G; Burnett, B; Fenne, P M; Williams, M A; et al.
Forensic science international 2018 February Vol. 283: 156-172.


Abstract
Toolmark analysis involves examining marks created on an object to identify the likely tool responsible for creating those marks (e.g., a knife). Although a potentially powerful forensic tool, knife mark analysis is still in its infancy and the validation of imaging techniques as well as quantitative approaches is ongoing. This study builds on previous work by simulating real-world stabbings experimentally and statistically exploring quantitative toolmark properties, such as cut mark angle captured by micro-CT imaging, to predict the knife responsible. In Experiment 1 a mechanical stab rig and two knives were used to create 14 knife cut marks on dry pig ribs. The toolmarks were laser and micro-CT scanned to allow for quantitative measurements of numerous toolmark properties. The findings from Experiment 1 demonstrated that both knives produced statistically different cut mark widths, wall angle and shapes. Experiment 2 examined knife marks created on fleshed pig torsos with conditions designed to better simulate real-world stabbings. Eight knives were used to generate 64 incision cut marks that were also micro-CT scanned. Statistical exploration of these cut marks suggested that knife type, serrated or plain, can be predicted from cut mark width and wall angle. Preliminary results suggest that knives type can be predicted from cut mark width, and that knife edge thickness correlates with cut mark width. An additional 16 cut marks walls were imaged for striation marks using scanning electron microscopy with results suggesting that this approach might not be useful for knife mark analysis. Results also indicated that observer judgements of cut mark shape were more consistent when rated from micro-CT images than light microscopy images. The potential to combine micro-CT data, medical grade CT data and photographs to develop highly realistic virtual models for visualisation and 3D printing is also demonstrated. This is the first study to statistically explore simulated real-world knife marks imaged by micro-CT to demonstrate the potential of quantitative approaches in knife mark analysis. Findings and methods presented in this study are relevant to both forensic toolmark researchers as well as practitioners. Limitations of the experimental methodologies and imaging techniques are discussed, and further work is recommended.


Full text available at
https://auth.elsevier.com/ShibAuth/institutionLogin?entityID=https%3A%2F%2Fidp.eduserv.org.uk%2Fopenathens&appReturnURL=https%3A%2F%2Fwww.clinicalkey.com%2F%23!%2Fcontent%2Fjournal%2F1-s2.0-S0379073817305558 (UHCW Athens login required)

Monday, 8 January 2018

The cutting edge — Micro-CT for quantitative toolmark analysis of sharp force trauma to bone

Forensic Science International, Volume 283, Issue null, Pages 156-172

Toolmark analysis involves examining marks created on an object to identify the likely tool responsible for creating those marks (e.g., a knife). Although a potentially powerful forensic tool, knife mark analysis is still in its infancy and the validation of imaging techniques as well as quantitative approaches is ongoing. This study builds on previous work by simulating real-world stabbings experimentally and statistically exploring quantitative toolmark properties, such as cut mark angle captured by micro-CT imaging, to predict the knife responsible.

UHCW Research: B. Burnett

Wednesday, 27 December 2017

Novel application of three-dimensional technologies in a case of dismemberment

Forensic Sci Int. 2016 Dec 2;270:139-145. doi: 10.1016/j.forsciint.2016.11.040. [Epub ahead of print]

This case study reports the novel application of three-dimensional technologies such as micro-CT and 3D printing to the forensic investigation of a complex case of dismemberment. Micro-CT was successfully employed to virtually align severed skeletal elements found in different locations, analyse tool marks created during the dismemberment process, and virtually dissect a charred piece of evidence. High resolution 3D prints of the burnt human bone contained within were created for physical visualisation to assist the investigation team. Micro-CT as a forensic radiological method provided vital information and the basis for visualisation both during the investigation and in the subsequent trial making it one of the first examples of such technology in a UK court.

UHCW Research: Brian A. Burnett

See also Corrigendum to "Novel application of three-dimensional technologies in a case of dismemberment" [Forensic Sci. Int. 270C (2017) 139-145].

Thursday, 17 November 2016

The Forensic Mental Health Social Work: Capabilities Framework

This DH framework sets out progression and developments for forensic mental health social workers. It builds on the capabilities set out in the framework for social workers and it outlines pathways for post-qualifying progression and development for social workers practising within forensic mental health settings.