Perspectives of vets on plastics in veterinary medicine

The use of disposable plastics and their subsequent environmental impacts are topics of increasing concern in modern society. Medical, including veterinary, sectors are major contributors to plastic waste production. While there is an existing body of literature on the use and reduction of disposable plastics in the human medical sector, few studies, if any, have specifically investigated the use of plastics within the veterinary field. The overall aim of this pilot study was to investigate Australian veterinarians regarding their attitudes toward the ways in which they use disposable plastic in their work and personal lives

Lead exposure of mainland Australia\u27s top avian predator

Lead (Pb) toxicity, through ingestion of lead ammunition in carcasses, is a threat to scavenging birds worldwide, but has received little attention in Australia. We analyzed lead exposure in the wedge-tailed eagle (Aquila audax), the largest raptor species found in mainland Australia and a facultative scavenger. Eagle carcasses were collected opportunistically throughout south-eastern mainland Australia between 1996 and 2022. Lead concentrations were measured in bone samples from 62 animals via portable X-ray fluorescence (XRF). Lead was detected (concentration \u3e 1 ppm) in 84% (n = 52) of the bone samples. The mean lead concentration of birds in which lead was detected was 9.10 ppm (±SE 1.66). Bone lead concentrations were elevated (10–20 ppm) in 12.9% of samples, and severe ( \u3e 20 ppm) in 4.8% of samples. These proportions are moderately higher than equivalent data for the same species from the island of Tasmania, and are comparable to data from threatened eagle species from other continents. Lead exposure at these levels is likely to have negative impacts on wedge-tailed eagles at the level of the individual and perhaps at a population level. Our results suggest that studies of lead exposure in other Australian avian scavenger species are warranted

Etude de l\u27appareil nucl\ue9aire du cili\ue9 h\ue9t\ue9rotriche Climacostomum virens

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Undergraduate veterinary training in wildlife health and conservation medicine in Australasia

Traditionally veterinary schools in Australasia have concentrated undergraduate training on the health and medicine of domesticated animals with an increasing emphasis on small animal medicine. However, veterinary practices are now called upon to treat and examine exotic pets including reptiles, amphibians, caged birds, native mammals, and rabbits and other small exotic pets. Historically, there has been little undergraduate training in these areas and veterinarians have had to learn from the literature, attend conferences and develop their interest and confidence to tackle these types of cases. Veterinary practices also increasingly see many injured or sick wildlife cases brought in by members of the public or by carers. Each practice in Australia treated on average 3.48 wildlife cases each week- at a time when there were 1792 practices in Australia. In 2003, across Australia each week practices were treating 6236 animals. Ten years later it is likely that this has increased considerably. Concurrently, there has been a marked increase in interest in emerging infectious diseases linked in many instances to wildlife such as SARS, Hendra virus, Nipah virus and this has led to new terms that have arisen such as ecohealth, ecosystem health and one health. In addition there have been diseases that have affected wildlife biodiversity eg chytriodiomycosis and beak and feather disease, and some of which often spillover in to domestic animals such as tuberculosis - these areas have led to the new term – Conservation medicine. Much has changed over the last 20 years but has undergraduate veterinary education adapted to these changes? Some veterinary schools in Australasia are starting to provide more training to support these emerging needs, ranging from individual sick and injured wildlife cases, to pet reptiles and birds, to diseases of wildlife populations which can affect biodiversity and the balance of ecosystems. What are the drivers of these changes? Should we be teaching veterinary students about the drivers of the changes in the health of ecosystems and biodiversity? This presentation provides a snapshot of the undergraduate training that is being provided in wildlife health in veterinary schools within Australasia by the analysis of data collected from a questionnaire sent to all schools. lt discusses how we can adapt the training in the future to ensure veterinary students are conversant with the challenges that lie ahead and can seek employment in these areas

Comparison of the modified agglutination test and real-time PCR for detection of Toxoplasma gondii exposure in feral cats from Phillip Island, Australia, and risk factors associated with infection

Toxoplasma gondii is considered a disease risk for many native Australian species. Feral cats are the key definitive host of T. gondii in Australia and therefore, investigating the epidemiology of T. gondii in cat populations is essential to understanding the risk posed to wildlife. Test sensitivity and specificity are poorly defined for diagnostic tests targeting T. gondii in cats and there is a need for validated techniques. This study focused on the feral cat population on Phillip Island, Victoria, Australia. We compared a novel real-time PCR (qPCR) protocol to the modified agglutination test (MAT) and used a Bayesian latent class modelling approach to assess the diagnostic parameters of each assay and estimate the true prevalence of T. gondii in feral cats. In addition, we performed multivariable logistic regression to determine risk factors associated with T. gondii infection in cats. Overall T. gondii prevalence by qPCR and MAT was 79.5% (95% confidence interval 72.6-85.0) and 91.8% (84.6-95.8), respectively. Bayesian modelling estimated the sensitivity and specificity of the MAT as 96.2% (95% credible interval 91.8-98.8) and 82.1% (64.9-93.6), and qPCR as 90.1% (83.6-95.5) and 96.0% (82.1-99.8), respectively. True prevalence of T. gondii infection in feral cats on Phillip Island was estimated as 90.3% (83.2-95.1). Multivariable logistic regression analysis indicated that T. gondii infection was positively associated with weight and this effect was modified by season. Cats trapped in winter had a high probability of infection, regardless of weight. The present study suggests qPCR applied to tissue is a highly sensitive, specific and logistically feasible tool for T. gondii testing in feral cat populations. Additionally, T. gondii infection is highly prevalent in feral cats on Phillip Island, which may have significant impacts on endemic and introduced marsupial populations

Developmental and Post-Eruptive Defects in Molar Enamel of Free-Ranging Eastern Grey Kangaroos (Macropus giganteus) Exposed to High Environmental Levels of Fluoride

Dental fluorosis has recently been diagnosed in wild marsupials inhabiting a high-fluoride area in Victoria, Australia. Information on the histopathology of fluorotic marsupial enamel has thus far not been available. This study analyzed the developmental and post-eruptive defects in fluorotic molar enamel of eastern grey kangaroos (Macropus giganteus) from the same high-fluoride area using light microscopy and backscattered electron imaging in the scanning electron microscope. The fluorotic enamel exhibited a brownish to blackish discolouration due to post-eruptive infiltration of stains from the oral cavity and was less resistant to wear than normally mineralized enamel of kangaroos from low-fluoride areas. Developmental defects of enamel included enamel hypoplasia and a pronounced hypomineralization of the outer (sub-surface) enamel underneath a thin rim of well-mineralized surface enamel. While the hypoplastic defects denote a disturbance of ameloblast function during the secretory stage of amelogenesis, the hypomineralization is attributed to an impairment of enamel maturation. In addition to hypoplastic defects, the fluorotic molars also exhibited numerous post-eruptive enamel defects due to the flaking-off of portions of the outer, hypomineralized enamel layer during mastication. The macroscopic and histopathological lesions in fluorotic enamel of M. giganteus match those previously described for placental mammals. It is therefore concluded that there exist no principal differences in the pathogenic mechanisms of dental fluorosis between marsupial and placental mammals. The regular occurrence of hypomineralized, opaque outer enamel in the teeth of M. giganteus and other macropodids must be considered in the differential diagnosis of dental fluorosis in these species