High-Tech Models for Simulating the Wounding Effects of Projectiles of Small Calibres: Benefits for Security Management

High-Tech Models for Simulating the Wounding Effects of Projectiles of Small Calibres: Benefits for Security Management

The aim of this study is to analyse the effects of projectiles of small calibres on the human femur using an innovative indirect identification method. A heterogeneous physical model was developed that combines ballistic gelatine for soft tissues and porcine femur as an analogue for human bone to si...

Full description

Saved in:
Bibliographic Details
Main Authors: Ludvík Juříček, Katarína Pagáčová, David Mazák, Olga Vojtěchovská
Format: Article
Language:English
Published: Ital Publication 2025-03-01
Series:HighTech and Innovation Journal
Subjects:
physical model
ballistic experiment
complex gunshot injury
indirect identification method
projectiles of small calibres
live tissue substitution
wounding effect of a projectile
wounding potential of a projectile.
Online Access:https://hightechjournal.org/index.php/HIJ/article/view/1016
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The aim of this study is to analyse the effects of projectiles of small calibres on the human femur using an innovative indirect identification method. A heterogeneous physical model was developed that combines ballistic gelatine for soft tissues and porcine femur as an analogue for human bone to simulate gunshot injuries under ethical and economic conditions. The study evaluated three types of ammunition: 9 mm Luger pistol cartridges and two micro-calibre rifle cartridges, 5.56×45 mm (SS 109) and 5.45×39 mm (7H6). Ballistic testing measured impact and exit velocities, assessed bone tissue destruction, soft tissue damage, and the temporary cavity created by projectiles. The findings reveal that micro-calibre rifle projectiles cause up to twice the bone destruction and more extensive soft tissue damage compared to pistol ammunition. The study also highlights the significant role of liquid structures in the medullary cavity in amplifying bone damage. These results improve ballistic testing methodologies, offering valuable insights for crisis management, security operations, and the development of protective equipment. The proposed model serves as a critical tool for understanding the effects on human tissues, aiding in forensic analysis, and advancing experimental ballistics. This research opens new opportunities for applications in the security and health disciplines.   Doi: 10.28991/HIJ-2025-06-01-010 Full Text: PDF
ISSN:2723-9535

Similar Items