How changes to the substrate’s physical characteristics can influence the deposition of touch and salivary deposits

“…After a drying time of 1 week, the dislodgments increased with data suggesting that the substrate is either too smooth for blood to maintain a strong adhesion potential or too rough to effectively create sufficient intermolecular bonds to maintain a strong adhesion potential; instead, it appears that the deposit remains on the upper surface layer of the substrate. This lack of adhesion potential was also documented by Hughes et al [20,22,23], where blood had shown to have the lowest persistence on aluminum compared to touch, semen, and/or salivary deposits. Again, difference in persistence as well as the high dislodgment tendency may be driven by the formations of radial cracks (Figure 3) in the drying blood drop, due to stresses created by the diffusion of solvent molecules during the solvent evaporation phase [34].…”

“…Whole blood was collected second to limit the total waiting time before deposition, in accordance with the method applied by Hughes et al. [23], where blood was collected into a 9 mL EDTA‐free tube (Vacutest® Kima s.r.l., Arzergrande, Italy), which was then kept warm with a self‐activating heat pad (Kobayashi, HotHands Toe Warmers, Dalton, USA) and maintaining a gentle side‐to‐side motion to prevent the premature clotting of the blood.…”

“…After deposition and the completion of individual experiments (the three different drying duration tests), the substrates were cleaned according to Hughes et al. [20, 22, 23], by submerging and cleaning the samples in an anionic soap (Earth Choice, Australia) bath followed with a rinse in deionized water, before repeating this washing process a second time and then drying the samples with sterile KimWipe™. Subsequent DNA decontamination as outlined above was then again performed 1 day prior to deposition.…”

“…TA B L E 1 Surface roughness categories R1-R6, representing average surface roughness (Sa) measurements in μm. After deposition and the completion of individual experiments (the three different drying duration tests), the substrates were cleaned according to Hughes et al [20,22,23], by submerging and cleaning the samples in an anionic soap (Earth Choice, Australia)…”

“…Whole blood was deposited first by immediately pipetting 10 μL of blood onto the center of the substrate disc, before lightly spreading the blood with the pipette tip as per procedure used by Hughes et al [20,23]. The collection tube was recapped and agitated between sets to limit the exposure of the blood to oxygen in the air and to prevent blood serum separation.…”

The effect of the anti‐coagulant EDTA on the deposition and adhesion of whole blood deposits on non‐porous substrates

“…After a drying time of 1 week, the dislodgments increased with data suggesting that the substrate is either too smooth for blood to maintain a strong adhesion potential or too rough to effectively create sufficient intermolecular bonds to maintain a strong adhesion potential; instead, it appears that the deposit remains on the upper surface layer of the substrate. This lack of adhesion potential was also documented by Hughes et al [20,22,23], where blood had shown to have the lowest persistence on aluminum compared to touch, semen, and/or salivary deposits. Again, difference in persistence as well as the high dislodgment tendency may be driven by the formations of radial cracks (Figure 3) in the drying blood drop, due to stresses created by the diffusion of solvent molecules during the solvent evaporation phase [34].…”

“…Whole blood was collected second to limit the total waiting time before deposition, in accordance with the method applied by Hughes et al. [23], where blood was collected into a 9 mL EDTA‐free tube (Vacutest® Kima s.r.l., Arzergrande, Italy), which was then kept warm with a self‐activating heat pad (Kobayashi, HotHands Toe Warmers, Dalton, USA) and maintaining a gentle side‐to‐side motion to prevent the premature clotting of the blood.…”

“…After deposition and the completion of individual experiments (the three different drying duration tests), the substrates were cleaned according to Hughes et al. [20, 22, 23], by submerging and cleaning the samples in an anionic soap (Earth Choice, Australia) bath followed with a rinse in deionized water, before repeating this washing process a second time and then drying the samples with sterile KimWipe™. Subsequent DNA decontamination as outlined above was then again performed 1 day prior to deposition.…”

“…TA B L E 1 Surface roughness categories R1-R6, representing average surface roughness (Sa) measurements in μm. After deposition and the completion of individual experiments (the three different drying duration tests), the substrates were cleaned according to Hughes et al [20,22,23], by submerging and cleaning the samples in an anionic soap (Earth Choice, Australia)…”

“…Whole blood was deposited first by immediately pipetting 10 μL of blood onto the center of the substrate disc, before lightly spreading the blood with the pipette tip as per procedure used by Hughes et al [20,23]. The collection tube was recapped and agitated between sets to limit the exposure of the blood to oxygen in the air and to prevent blood serum separation.…”

The effect of the anti‐coagulant EDTA on the deposition and adhesion of whole blood deposits on non‐porous substrates

Emerging use of air eDNA and its application to forensic investigations – A review

How the physicochemical substrate properties can influence the deposition of blood and seminal deposits