Identification of Human Remains Using Rapid DNA Analysis

Overview

Journal Int J Legal Med

Specialty Forensic Sciences

Date 2019 Nov 30

PMID 31781850

Citations 13

Authors

Rosemary S Turingan

Jessi Brown

Ludmila Kaplun

Jake Smith

Jenna Watson

Derek A Boyd

Dawnie Wolfe Steadman

Richard F Selden

Affiliations

Soon will be listed here.

Abstract

Rapid identification of human remains following mass casualty events is essential to bring closure to family members and friends of the victims. Unfortunately, disaster victim identification, missing persons identification, and forensic casework analysis are often complicated by sample degradation due to exposure to harsh environmental conditions. Following a mass disaster, forensic laboratories may be overwhelmed by the number of dissociated portions that require identification and reassociation or compromised by the event itself. The interval between the disaster and receipt of victim samples at a laboratory is critical in that sample quality deteriorates as the postmortem interval increases. When bodies decompose due to delay in collection, transport, and sample processing, DNA becomes progressively fragmented, adversely impacting identification. We have previously developed a fully automated, field-forward Rapid DNA identification system that produces STR profiles (also referred to as DNA IDs or DNA fingerprints) from buccal and crime scene samples. The system performs all sample processing and data interpretation in less than 2 h. Here, we present results on Rapid DNA identification performed on several tissue types (including buccal, muscle, liver, brain, tooth, and bone) from exposed human bodies placed above ground or stored in a morgue/cooler, two scenarios commonly encountered following mass disasters. We demonstrate that for exposed remains, buccal swabs are the sample of choice for up to 11 days exposure and bone and tooth samples generated excellent DNA IDs for the 1-year duration of the study. For refrigerated remains, all sample types generated excellent DNA IDs for the 3-month testing period.

Citing Articles

Disaster victim identification: the co-utilisation of applied biosystems RapidHIT ID system and DJI Matrice 300 drone for onsite DNA analysis.

Mohd Sabri N, Sheikh Abdul Kadir S, Chainchel Singh M, Heo C, Khoo L, Mohd Yusof M Sci Rep. 2025; 15(1):4872.

PMID: 39929911 PMC: 11811220. DOI: 10.1038/s41598-025-88750-6.

Using DNA to Reunify Families Separated by Disasters.

Barnert E, Lee J, Huston S NAM Perspect. 2025; 2024.

PMID: 39830813 PMC: 11741538. DOI: 10.31478/202410a.

Assessing the feasibility of free DNA for disaster victim identification and forensic applications.

Worrapitirungsi W, Sathirapatya T, Sukawutthiya P, Vongpaisarnsin K, Varrathyarom P Sci Rep. 2024; 14(1):5411.

PMID: 38443390 PMC: 10914783. DOI: 10.1038/s41598-024-53040-0.

Alternative workflows for identifying transnational missing persons.

Kaplan M, McDaneld C, Brown J, Selden I, Jiang H, Tan E Forensic Sci Int Synerg. 2023; 7:100445.

PMID: 38025091 PMC: 10630773. DOI: 10.1016/j.fsisyn.2023.100445.

Introducing a Rapid DNA Analysis Procedure for Crime Scene Samples Outside of the Laboratory-A Field Experiment.

de Roo R, Mapes A, van Cooten M, van Hooff B, Kneppers S, Kokshoorn B Sensors (Basel). 2023; 23(8).

PMID: 37112494 PMC: 10145755. DOI: 10.3390/s23084153.

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