Using 'biological motion' to enhance the nighttime safety of road workers, cyclists, and pedestrians. Pedestrian and cyclist fatalities are a major road safety problem, accounting for a third of road fatalities at an estimated cost of $2.5 billion/year. Late recognition of pedestrians and cyclist by drivers is the main reason for these collisions. We have shown that innovative visibility designs which involve strategic placement of reflective markers on the moveable joints can greatly enhance vi ....Using 'biological motion' to enhance the nighttime safety of road workers, cyclists, and pedestrians. Pedestrian and cyclist fatalities are a major road safety problem, accounting for a third of road fatalities at an estimated cost of $2.5 billion/year. Late recognition of pedestrians and cyclist by drivers is the main reason for these collisions. We have shown that innovative visibility designs which involve strategic placement of reflective markers on the moveable joints can greatly enhance visibility and hence safety of these vulnerable road users. We will extend this research to incorporate evaluation of these visibility solutions in real-world environments and encourage the widespread use of these designs in the real-world through education and policy change.Read moreRead less
A comparative study of the laser-tissue interaction between solid state 213nm vs excimer gas 193nm laser systems. We will carry out a comparative study of the latest technological developments in laser vision correction surgery. We will compare the biological effects of a new solid state laser operating at 213nm and a traditional excimer gas laser operating at 193nm. For each laser type, long-term scarring, cytotoxicity, mutagenicity and free radical production will be studied in relevant in viv ....A comparative study of the laser-tissue interaction between solid state 213nm vs excimer gas 193nm laser systems. We will carry out a comparative study of the latest technological developments in laser vision correction surgery. We will compare the biological effects of a new solid state laser operating at 213nm and a traditional excimer gas laser operating at 193nm. For each laser type, long-term scarring, cytotoxicity, mutagenicity and free radical production will be studied in relevant in vivo and in vitro animal models. Furthermore, optimization of the irradiation protocol for the solid state laser will lead to the development of a wide range of biological applications.Read moreRead less