Path of Science: International Electronic Scientific Journal

Automated fingerprint systems are very accurate with clear prints, but they do not work well with damaged or unclear evidence. This review assessed how well computational biology models perform in fingerprint analysis compared to manual methods. We searched five databases from 2018 to 2024, following PRISMA guidelines. We included 33 studies using machine learning for fingerprints, with data from 169 forensic examiners and 744 fingerprint pairs from real cases. We measured accuracy, false-negative rates, and group differences using meta-analysis in R. Computational models achieved 99.6% accuracy on clear prints, while manual checks achieved 92%. Both methods had a 7.5% false negative rate. 85% of examiners made at least one mistake, and algorithms worked 15–25% worse for less-represented groups. Deep learning achieved better fingerprint recognition but struggled with poor-quality prints. Computational biology models are best with clear evidence, but real forensic work still needs both algorithms and human experts.

computational biology; dermatoglyphics; forensic identification; machine learning; automated fingerprint identification; pattern recognition

1. Ulery, B. T., Hicklin, R. A., Buscaglia, J., & Roberts, M. A. (2011). Accuracy and reliability of forensic latent fingerprint decisions. Proceedings of the National Academy of Sciences, 108(19), 7733–7738. doi: 10.1073/pnas.1018707108

2. Yoon, N. S., Feng, N. J., & Jain, A. K. (2011). Altered Fingerprints: analysis and detection. IEEE Transactions on Pattern Analysis and Machine Intelligence, 34(3), 451–464. doi: 10.1109/tpami.2011.161

3. Cao, W., Fang, Z., Hou, G., Han, M., Xu, X., Dong, J., & Zheng, J. (2020). The psychological impact of the COVID-19 epidemic on college students in China. Psychiatry Research, 287, 112934. doi: 10.1016/j.psychres.2020.112934

4. Deshpande, U. U., Malemath, V. S., Patil, S. M., & Chaugule, S. V. (2020). End-to-End Automated Latent fingerprint identification with improved DCNN-FFT enhancement. Frontiers in Robotics and AI, 7, 594412. doi: 10.3389/frobt.2020.594412

5. FBI. (n. d.). Next Generation Identification (NGI). Retrieved from https://le.fbi.gov/science-and-lab/biometrics-and-fingerprints/biometrics/next-generation-identification-ngi

6. Anibor, E., Igbigbi, P. S., Avwioro, O. G., & Okpor, A. (2011). Palmar and digital dermatoglyphic patterns in the Ndokwas of Delta State, Nigeria. African Journal of Medical Sciences, 40(3), 181-185

7. Grand View Research. (2024). Automated Fingerprint Identification System (AFIS) Market (2024 - 2030). Retrieved from https://www.grandviewresearch.com/industry-analysis/automated-fingerprint-identification-system-market

8. Precedence Research. (2025). Automated Fingerprint Identification System Market Size, Share and Trends 2025 to 2034. Retrieved from https://www.precedenceresearch.com/automated-fingerprint-identification-system-market

9. Orsini, F., Cioffi, A., Cipolloni, L., Bibbò, R., Montana, A., De Simone, S., & Cecannecchia, C. (2025). The application of artificial intelligence in forensic pathology: a systematic literature review. Frontiers in Medicine, 12, 1583743. doi: 10.3389/fmed.2025.1583743

10. Chiroma, H. (2021). Deep Learning Algorithms-based Fingerprint Authentication: Systematic Literature Review. Journal of Artificial Intelligence and Systems, 3(1), 157–197. doi: 10.33969/ais.2021.31010

11. Gibb, C., & Riemen, J. (2023). Toward better AFIS practice and process in the forensic fingerprint environment. Forensic Science International Synergy, 7, 100336. doi: 10.1016/j.fsisyn.2023.100336