Saliva-derived secondary DNA transfer on fabric: The impact of varying conditions

Abstract

This study explored secondary DNA transfer involving saliva, a body fluid often encountered in forensic investigations. Various factors were examined to investigate their potential impact on the transfer of DNA from saliva stains deposited onto common types of fabric (cotton, nylon, and towel). We examined varying types of saliva moisture (wet, dry, and rehydrated) and different types of contact (controlled pressure and active/friction pressure) to quantitatively evaluate how such variables could impact transfer and possible conclusions surrounding saliva-derived DNA deposits. The transfer of DNA was generally least pronounced with more absorbent primary fabrics (cotton and towel materials) while a less absorbent primary fabric (nylon) exhibited a greater propensity for DNA transfer. There were significantly higher amounts of transferred DNA (p < 0.05) observed in wet saliva samples compared to dry and rehydrated saliva samples. Further, the use of active pressure (friction) appeared to result in more DNA transfer overall as compared to controlled pressure contact. Experiments conducted with wet saliva and active pressure (friction) demonstrated the highest likelihood of transfer, with the primary nylon and secondary towel fabric combination demonstrating the greatest average transfer percentage of 94.74 %. The variables explored in this study presented multiple combinations wherein a sufficient amount of DNA (≥ 240 pg total) was transferred to the secondary fabric, making it potentially suitable for STR-PCR amplification in our laboratory. The findings from this study indicate that the type of primary fabric receiving the saliva deposit, the type of saliva moisture, the type of secondary fabric and its moisture type, and the type of contact all have the potential to affect the quantity of DNA transferred and recovered. This study provides empirical data on the ease, and to what extent, DNA from saliva transfers between fabrics and aids DNA activity level evaluations. The significance of this research lies in its contribution to expanding our current understanding of DNA transfer involving saliva within forensic science and criminal investigations.