Background: Adverse respiratory effects of particulate air pollution have been identified by epidemiological studies. We aimed to examine the health effects of ambient particulate air pollution from wood burning on school-age students in Christchurch, New Zealand, and to explore the utility of urine and exhaled breath condensate biomarkers of exposure in this population.
Rabbit haemorrhagic disease virus 2 (RHDV2 or GI.2, referring to any virus with lagovirus GI.2 structural genes) is a recently emerged calicivirus that causes generalised hepatic necrosis and disseminated intravascular coagulation leading to death in susceptible lagomorphs (rabbits and hares). Previous studies investigating the virulence of RHDV2 have reported conflicting results, with case fatality rates ranging from 0% to 100% even within a single study. Lagoviruses are of particular importance in Australia and New Zealand where they are used as biocontrol agents to manage wild rabbit populations, which threaten over 300 native species and result in economic impacts in excess of $200 million AUD annually to Australian agricultural industries. It is critically important that any pest control method is both highly effective (i.e., virulent, in the context of viral biocontrols) and has minimal animal welfare impacts. To determine whether RHDV2 might be a suitable candidate biocontrol agent, we investigated the virulence and disease progression of a naturally occurring Australian recombinant RHDV2 in both 5-week-old and 11-week-old New Zealand White laboratory rabbits after either high or low dose oral infection. Objective measures of disease progression were recorded through continuous body temperature monitoring collars, continuous activity monitors, and twice daily observations. We observed a 100% case fatality rate in both infected kittens and adult rabbits after either high dose or low dose infection. Clinical signs of disease, such as pyrexia, weight loss, and reduced activity, were evident in the late stages of infection. Clinical disease, i.e., welfare impacts, were limited to the period after the onset of pyrexia, lasting on average 12 h and increasing in severity as disease progressed. These findings confirm the high virulence of this RHDV2 variant in naïve rabbits. While age and infectious dose significantly affected disease progression, the case fatality rate was consistently 100% under all conditions tested.
Fine atmospheric particles depositing in the lung present a large adsorbent surface for the adsorption of bronchoalveolar lining fluid (BALF) components, including lung surfactant and its associated proteins. Such adsorption at invading particle surfaces is known to be important in biological particle clearance, and the immunological and toxicological fate of these particles. In the experiments conducted here, it was hypothesized that this is also true for particles of nonbiological origin, and that fine particles with large surface areas would selectively adsorb the opsonizing components of BALF. This work quantifies the adsorption rates (adsorption of compound per unit surface area) of isolated BALF components. Elemental carbon (EC) is a ubiquitous component of fine urban particulate matter (PM2.5), and particular forms of EC are extremely surface active (e.g., activated carbon). EC originates largely from fossil fuel combustion, and vehicles in particular contribute a significant proportion of PM(2.5) EC mass in urban areas. Since the size distribution of EC is submicrometer, industrially produced carbon blacks in the 25-100 nm size range can be used as a surrogate for urban EC, in terms of surface area and chemistry. Three types of carbon black (CB) particles were used. Two were identical in size (25 nm) but different in surface treatment; R330, a CB with a nonoxidized surface, and R400, a CB produced with an oxidized surface. The third particle type, M120, was 75 nm, different in size from R330 and R400, but similar to R330 in surface chemistry, that is, nonoxidized. Particles were first washed and resuspended in phosphate-buffered-saline (PBS, pH 7.0) three times to remove surfactant coatings added during their manufacture. Colloidal suspensions of M120, R330, and R400 particles with decreasing surface areas were then generated and separated into reaction vials. BALF proteins were added spanning physiological concentrations while the dominant phospholipid in surfactant was added at a fixed concentration lower than physiological lung lavage concentrations to ensure the lipid remained in suspension during experimentation ex situ. For dipalmitoylphosphatidylcholine (DPPC) combinations with particles, visible particle agglomeration occurred within 1 h. Marked changes in the size distribution of the immersed particles were observed, compared to a phosphate buffer control. Differences in particle agglomeration and particle settling were observed between M120, R330, and R400. Reduction of DPPC occurred in a surface- and size-dependent manner. This indicates that surface adsorption was responsible for the observed agglomeration and the gross reductions in phospholipid concentrations. Combination of particles with fibrinogen and albumin revealed little agglomeration/precipitation at the protein concentrations chosen. However, surfactant protein (SP-D) was completely eliminated from suspension upon combination with all three-particle types. This reaction between SP-D particles was therefore concluded to be independen...
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