创伤性脑损伤
法医学
心理学
工程类
医学
精神科
兽医学
作者
Yuyang Wei,Jeremy Oldroyd,Phoebe Haste,Jayaratnam Jayamohan,Michael Jones,Nicholas Casey,José-María Peña,Sonya Baylis,Stan Gilmour,Antoine Jérusalem
标识
DOI:10.1038/s44172-025-00352-2
摘要
Police forensic investigations are not immune to our society’s ubiquitous search for better predictive ability. In the particular and very topical case of Traumatic Brain Injury (TBI), police forensic investigations aim at evaluating whether a given impact or assault scenario led to the clinically observed TBI. This question is traditionally answered by means of forensic biomechanics and neurosurgical expertise which cannot provide a fully objective probabilistic measure. To this end, we propose here a numerical framework-based solution coupling biomechanical simulations of a variety of injurious impacts to machine learning training of police reports provided by the UK’s Thames Valley Police and the National Crime Agency’s National Injury Database. In this approach, the biomechanical predictions of mechanical metrics such as strain and stress distributions are interpreted by the machine learning model by additionally considering assault specific metadata to predict brain injury outcomes. The framework, only taking as input information typically available in police reports, reaches prediction accuracies exceeding 94% for skull fracture, 79% for loss of consciousness and intracranial haemorrhage, and is able to identify the best predictive features for each targeted injury. Overall, the proposed framework offers new avenues for the prediction, directly from police reports, of any TBI related symptom as required by forensic law enforcement investigations. Yuyang Wei, Stan Gilmour, Antoine Jerusalem and colleagues report a computational framework that uses a coupled biomechanical - machine learning framework to predict outcomes of head injury assaults. This novel framework aims at supporting police and forensic investigations by providing an objective tool to help estimate whether a reported assault could lead to traumatic brain injury.
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