Prospective directions for the development of means and methods for detection and fixation of handprints
Abstract
Identification by fingerprints remains one of the most common ways of proving the involvement of persons in the commission of a criminal offense in law enforcement practice around the world. Over the past hundred years, the methodology of detecting and collecting fingerprints at the scene has evolved from the first attempts to use carbon black and metal powders (at the end of the 19th century) to the use of modern fluorescent powders and molecularly selective chemical compounds.
The type of surface and its condition affect the choice of one or another means of finding and developing a papillary pattern. According to empirical data, difficulties arise when working with heterogeneous surfaces, leather products, granular and porous materials. Until recently, the search for prints at the scene has been negated by contamination of surfaces, as well as the presence of moisture or organic liquids. It was practically impossible to develop outdated traces, as well as to determine the approximate time of leaving the trace. The analysis of the latest foreign publications has shown significant achievements that help to effectively solve the above problems, significantly expanding the arsenal of forensic tools and methods of working with traces at the scene.
Physical methods of detecting traces have received significant development. Among them, it can be singled out the use of luminescent dactyloscopic powders, which better visualize papillary patterns under UV and IR special lighting. Silicon nanoparticles with the addition of dyes, depending on the color of the surface, have shown a better result compared to the cyanoacrylate method.
The scientists have managed to improve the results regarding the detection of outdated traces by combining homogeneous chemical compounds. The main ones among them are ninhydrin, which works well with dirty and wet surfaces, as well as silver nitrate and DFO solution, which reacts with organic secretions of human skin well. A vacuum deposition method (VMD) has proven to be effective, making visible prints on the surfaces of four-year-old organic plastic. The direction of immunological research of the sebaceous trace of a finger for taking samples for a DNA profile remains relevant. The presented review of foreign and domestic experience has indicated the continuation of active searches for improving methods and means of working with traces.
Downloads
References
Bécue, A., Eldridge, H., & Champod, C. (2020). Interpol review of fingermarks and other body impressions (2016–2019). Forensic Science International: Synergy, 2, 442-480. https://doi.org/10.1016/j.fsisyn.2020.01.013.
Girod-Frais, A., & Bécue, A. (2021). Past, Present, and Future of the ForensicUse of Fingermarks. In J. De Alcaraz-Fossoul (Ed.), Technologies for Fingermark Age Estimations. Springer Nature. https://doi.org/10.1007/978-3-030-69337-4_1.
Herschel, W. J. (1916). The Origin of Finger-Printing. Oxford University Press.
Ishchenko, A. V., & Kotsiulym, Kh. M. (2012, May 18). The history of the use of dactyloscopic knowledge: from the origins to the first attempts at generalization [Conference presentation abstract]. International Round Table “Problems of the theory and practice of forensic examination”, Luhansk, Uktaine.
Jürgen, T. (1966). Das Jahrhundert der Detektive. Weg und Abenteuer der Kriminalistik. Droemer.
Kozhakar, I. Yu. (2017). Historiography of the problem of dactyloscopy of an unidentified corpse. Forensic Bulletin, 2(28), 78-84.
Lennard, C. (2020). Fingermark detection and identification: current research efforts. Australian Journal of Forensic Sciences, 52(2), 125-145. https://doi.org/10.1080/00450618.2018.1474948.
Logvinenko, A. O. (2017). Problems of use of fingerprint information in the investigation of crimes. Law Herald, 1(42), 174-178.
Lysak, H. S., & Khobot, V. V. (2017). Immunological study of fingerprints on dactyloscopic films. Forensic Bulletin, 1(27), 78-90.
Lytovskyi, O., & Shevchenko, S. (2021). Detection, extraction and packaging of fingerprints at the crime place. Young Scientist, 5(93), 322-324. https://doi.org/10.32839/2304-5809/2021-5-93-61.
Lytovskyi, O., & Shevchenko, S. (2022, November 25). Current issues of detecting handprints from vehicles [Conference presentation abstract]. International scientific and practical conference “Modern trends in the development of criminology and the criminal process under martial law”, Kharkiv, Ukraine. http://doi.org/10.5281/zenodo.7319910.
Malpighi, M. (1687). De externo tactus organo. Exercitatio epistolica ad Iacobum Ruffum. Operum.
Margot, P., & Lennard, C. (2012). Detection of Latent Fingerprints on Newly Developed Substances Using the Vacuum Metal Deposition Method. Journal of Forensic Identification, 52(5), 573-578. https://doi.org/10.1016/s0379-0738(01)00507-2.
Moore, J., Bleay, S., Deans, J., & NicDaeid, N. (2010). Recovery of Fingerprints from Arson Scenes. Journal of Forensic Identification, 58(1), 83-108.
Perlin, S. I., Shevtsov, S. O., Kosmina, N. M., & Ivanova, V. V. (2012). Inspection of the scene: identification and removal of objects of biological origin. FOP Chaltsev O. V.
Rohatiuk, I. V. (2014). Directions for improving the use of dactyloscopic information in the activities of pre-trial investigation bodies and the prosecutor's office. Law Review of Kyiv University of Law, 1, 292-296.
Sava, V. (2014). Dactiloscopia оn serviciul Justiuiei. ScriGroup. https://www.scrigroup.com/educatie/sociologie/IDENTIFICAREA-PERSOANELOR-DUPA52574.php.
Scotcher, K., & Bradshaw, R. (2018). The analysis of latent fingermarks on polymer banknotes using MALDI-MS. Scientific Reports, 8. https://doi.org/10.1038/s41598-018-27004-0.
Shvedova, O. V. (2015). Dactyloscopic studies. KNT.
Sonderegger, B., & Peter, M. (2013) The Fingerprint: 100 years in the service of the Swiss Confederation. Bern.
Wilson, L. E., Gahanb, M. E., & Lennard, C. (2021). Case study – crown prosecution of a British citizen for the extraterritorial murder of Sergeant First Class Randy Johnson, United States 2nd Cavalry Regiment. Australian Journal of Forensic Sciences, 53, 84-95. https://doi.org/10.1080/00450618.2019.1637939.
Wood, M., Maynard, P., Spindler, X., Roux, C., & Lennard, C. (2013). Selective targeting of fingermarks using immunogenic techniques. Australian Journal of Forensic Sciences, 45(2), 211-226. https://doi.org/10.1080/00450618.2012.744847.
Yamashita, B., & French, M. (2010). Fingerprint Sourcebook – Chapter 7: Latent Print Development. Rockville.
Yusupov, V. V. (2015). Fingerprints: history of detection, collection, and forensic study. Forensic Herald, 2, 34-41.
Zholtanska, I. I., Kuznetsov, V. A., & Shchavelev, A. V. et al. (2014). Methodology for dactyloscopy examination. Expert specialty 4.6 “Dactyloscopic research”. Kyiv.
Copyright (c) 2022 V. V. Korniienko
This work is licensed under a Creative Commons Attribution 4.0 International License.
