Model combustion-generated particulate matter containing persistent free radicals redox cycle to produce reactive oxygen species.

Particulate matter (PM) is emitted during thermal decomposition of waste. During this process, aromatic compounds chemisorb to the surface of metal-oxide-containing PM, forming a surface-stabilized environmentally persistent free radical (EPFR). We hypothesized that EPFR-containing PM redox cycle to produce ROS and that this redox cycle is maintained in biological environments. To test our hypothesis, we incubated model EPFRs with the fluorescent probe dihydrorhodamine (DHR). Marked increases in DHR fluorescence were observed. Using a more specific assay, hydroxyl radicals ((•)OH) were also detected, and their level was further increased by cotreatment with thiols or ascorbic acid (AA), known components of epithelial lining fluid. Next, we incubated our model EPFR in bronchoalveolar lavage fluid (BALF) or serum. Detection of EPFRs and (•)OH verified that PM generate ROS in biological fluids. Moreover, incubation of pulmonary epithelial cells with EPFR-containing PM increased (•)OH levels compared to those in PM lacking EPFRs. Finally, measurements of oxidant injury in neonatal rats exposed to EPFRs by inhalation suggested that EPFRs induce an oxidant injury within the lung lining fluid and that the lung responds by increasing antioxidant levels. In summary, our EPFR-containing PM redox cycle to produce ROS, and these ROS are maintained in biological fluids and environments. Moreover, these ROS may modulate toxic responses of PM in biological tissues such as the lung.

In vitro evaluation of the insertion force for different dilator tip configurations.

The purpose of this study was to evaluate the tissue penetration insertion force of different dilator tip geometries in simulated tissue. Four different dilator tip designs-conical (control), triangular, diamond, and biconvex-were appraised. The penetration force for each dilator was measured by using an ad hoc device. Each modified dilator required significantly less force necessary for "tissue" insertion compared with the conical control (P < .05 for all designs). These data suggest that angled dilator tips may facilitate insertion and may contribute to new dilator and catheter tip design.