The origin of unknown source DNA from touched objects

The presence of DNA in a criminal investigation often requires scrutiny in relation to how it came to be where it was found. There is a paucity of data with respect to the extent to which one can assume that the last person handling an object, which has previously been touched by others, will contribute to the DNA profile generated from it. There are limited data in detailing the extent to which any foreign DNA is picked-up from a previously touched object and transferred to subsequently touched objects. This study focuses on DNA transfer and persistence on a knife handle after multiple handlings with the knife by different individuals soon after each other, as well as handprints left on flat DNA-free surfaces immediately after touching a knife handle with a known history of prior handling. The profiles of later handlers of a knife are more prominent than earlier handlers; however, the last handler is not always the major contributor to the profile. Proportional contributions to the profiles retrieved from knife handles vary depending on the individuals touching the knife handle. They can also vary when knife handles have been handled in the same manner by the same individuals in the same sequence on different occasions. Hands readily pickup DNA left on objects by others and transfer it to subsequently touched objects. The quantity of foreign DNA picked up by a hand and deposited on subsequently touched objects diminishes as more DNA-free objects are handled soon after each other. Caution is advised when considering how DNA from different individuals may have been transferred to the object from which it was collected.

Thinning of a vertical free draining aqueous film incorporating colloidal particles

The drainage under gravity of a vertical foam film formed on a wire frame has been investigated. Dual-wavelength optical interferometry was used so that unambiguous fringe order assignments could be made, enabling absolute film thicknesses to be calculated with confidence. Films were stabilized by nonionic polypropylene glycol surfactant. Halfmicrometer silica particles with varying degrees of hydrophobicity were added to the film-forming liquid to investigate their effect on film drainage rate and stability. Hydrophilic particles had little or no effect, while hydrophobic particles slowed the drainage of the film and caused a minor increase in film lifetime, from ∼10 to ∼30 s. In both the hydrophilic and hydrophobic cases the films ruptured when they reached a thickness of ∼2 particle diameters. Particles of intermediate hydrophobicity had the most significant effect, increasing film lifetime by an order of magnitude over that for hydrophilic particles. The intermediate particles allowed films to thin down to a thickness less than the particle diameter, indicating that particles bridge across the entire film. This did not occur with more hydrophobic particles even though they were embedded in each of the two film surfaces. These results correlate well with previous literature on particle-laden foams. The film thickness and drainage measurements allow drainage mechanisms for the different particles to be identified, thus providing a mechanistic explanation for the observation by several previous authors that foams formed in the presence of particles, for example during mineral processing, have the greatest stability when the particles are of intermediate hydrophobicity.