To address these limitations, Signature Science has developed DNA-Touch. This proprietary method uses synthetic fingermarks to accurately and consistently represent the biochemical composition and biological signatures of human fingerprints. DNA-Touch samples include the primary components of a typical latent fingerprint, specifically sebaceous fluid, eccrine perspiration, extracellular DNA, and proteinaceous epidermal skin material (i.e., shed skin cells). An emulsion of synthetic sebaceous and eccrine material provides a chemically-relevant carrier solution into which a precise amount of extracted human genomic DNA is added. This accurately mimics the extracellular DNA content of a typical latent print. Further, these samples also contain a representative quantity of protein originating from epidermal skin cells. This allows DNA-Touch to be used in combination with protein-based forensic identification techniques.
DNA-Touch samples can support the quantitative evaluation of laboratory performance (e.g. DNA or protein recovery, quantitation, and typing success). Published data shows that DNA from the DNA-Touch samples (previously termed “artificial fingerprints” or “AFs”) was successfully recovered from glass and metal surfaces in ranges that generally mimicked the DNA yield ranges collected from human fingerprint samples. Evaluation of the degradation index revealed that the DNA was of comparable quality as well. Critically, the variability in extracted DNA yields between DNA-Touch replicates was lower than that of the human deposits. This illustrates the benefit of using touch samples containing a known, repeatable amount of genetic material when evaluating method or analyst performance.
Comparison of DNA yield and quality in human and artificial fingerprints. (Left) Latent, eccrine loaded, and artificial fingerprints (AF) were deposited on metal or glass surfaces, followed by DNA collection and extraction to evaluate the total yield. AF (10) refers to artificial fingerprints with 10 ng input DNA, and AF (5) refers to 5 ng input DNA. (Right) Comparison of DNA degradation index (DI) across fingerprint deposition on multiple surface types, where a DI ratio of greater than 1.0 indicates DNA degradation. Individual replicates are shown (circles) with the mean (bar) ± SD.
"We view DNA-Touch as a game-changing technology for the analysis of touch forensic samples," said Dr. Curt Hewitt, Signature Science's Center for Advanced Genomics' Science and Technology Advisor and study co-author. "While synthetic touch samples will never entirely replace human samples in forensic labs, DNA-Touch will both simplify and add scientific value to method development and validation efforts. The days of collecting dozens of latent fingerprints from multiple donors in the hopes of generating statistically defensible results for new collection methods are at an end."
Envisioned applications for DNA-Touch samples in the forensic laboratory include staff training, measuring the competency and proficiency of both manual and automated extraction processes, and assessing value for emerging R&D and technology advancements. Signature Science’s Center for Advanced Genomics R&D team is partnering with forensic and R&D laboratories to refine and advance the technology. Please contact us if you are interested in evaluating this technology or joining our 'early access' community.