Despite advances in DNA, fingermarks remain one the best forms of evidence available. While fingermarks are routinely analyzed in terms of their patterns, it may be possible to obtain additional information in terms of their chemical composition. If successful, a chemical analysis of the constituents of a fingermark may give scientists additional information that may help in the identification of a person. The results presented herein describe the initial investigation into the analytical determination of some of these compounds, specifically the fatty acids. This study was specifically aimed at identifying possible fatty acids, which could aid in profiling or perhaps uniquely identifying an individual. Preliminary data obtained in this study suggests that this may in fact be possible, though additional research is certainly necessary. Utilizing gas chromatography-mass spectrometry, significant differences in the ratios of several fatty acid methyl esters were found when comparing individuals of varying race and gender. In addition, large intervariability and intravariability was discovered for some compounds, suggesting the possibility of being able to individualize based on chemical profile. Follow-up investigations will continue to determine whether this continues to be the case as greater numbers of individuals are sampled and more extensive control and information on the subjects is obtained.
The attack on the World Trade Center on 9/11/2001 challenged current approaches to forensic DNA typing methods. The large number of victims and the extreme thermal and physical conditions of the site necessitated special approaches to the DNA-based identification. Because of these and many additional challenges, new procedures were created or modified from routine forensic protocols. This effort facilitated the identification of 1594 of the 2749 victims. In this Policy Forum, the authors, who were were members of the World Trade Center Kinship and Data Analysis Panel, review the lessons of the attack response from the perspective of DNA forensic identification and suggest policies and procedures for future mass disasters or large-scale terrorist attacks.
A form of physical vapor deposition, called the conformal-evaporated-film-by-rotation (CEFR) method, was optimized for the conformal deposition of columnar thin films (CTFs) on sebaceous fingermarks. Relying on the surface topology of the fingermark, the CTF development technique is different from traditional development techniques. After the optimization of the development conditions, the CTF development technique was found to be superior to traditional development methods on several nonporous substrates: the smooth side of Scotch(®) Multitask, Gorilla(®) , and Scotch(®) Duct tapes; clear and black soft plastics; stained and sealed walnut and cherry woods; partial bloody fingermarks on stainless steel; and discharged cartridge casings. It was equally as good as other development techniques on other substrates, but worse on a few. The optimization study is expected to assist in designing a mobile CEFR apparatus capable of on-scene development of fingermarks.
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