Forensic science experts at Flinders University are refining an innovative counter-terrorism technique that checks for environmental DNA in the dust on clothing, baggage, shoes, or even a passport.
The Flinders-led research, led by postdoctoral research associate Dr. Jennifer Young, will developed a system to trace the source of dust on suspect articles to match a soil profile of a specific area or overseas country.
“This could help provide evidence of where a person of interest might have traveled based on the environmental DNA signature from dust on their belongings,” says Dr. Young, from the College of Science and Engineering at Flinders University.
“This microscopic environmental trace evidence, based on soil geochemical, bacterial and fungal analysis would complement and enhance current forensic intelligence tools,” she says in new research in Forensic Science International: Genetics.
The project has received a State Government Defence Innovation Partnership (DIP) grant of almost $150,000 to develop the intelligence and forensic potential of dust traces for counter-terrorism and national security, working with the Australian Federal Police and university partners (University of Adelaide and University of Canberra) to match the DNA extraction and amplification technique to Australian soil profiles from Geosciences Australia.
Professor Linacre, chair in Forensic DNA Technology at Flinders, says environmental samples serve as ideal forms of contact trace evidence as detection at a scene can establish a link between a suspect, location, and victim. “Environment samples extracted via the ‘massively parallel sequencing’ technology provide biological signatures from complex DNA mixtures and trace amounts of low biomass samples,” he says.
The project is among more than $1 million in funding announced in the fourth round of the Defence Innovation Partnership’s Collaborative Research Fund.
InFoDust: The intelligence and forensic potential of dust traces for counter-terrorism and national security, led by Dr. Young, will put the new technique on trial with soil reference data from across Australia provided by partner Geoscience Australia.
This project will utilize a series of soils with contrasting properties to understand the relationship between soil biogeochemical signals and the derived dust signal under controlled conditions, before introducing environmental variables through an ‘in-situ’ experiment.
Reference: “Massively parallel sequencing is unlocking the potential of environmental trace evidence” by J.M. Young and A. Linacre, 16 September 2020, Forensic Science International: Genetics.
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