Your search keyword '"Bart, J."' showing total 6 results

1. Melioidosis in Papua New Guinea and Oceania

Author

Warner, Jeffrey M. and Currie, Bart J.

Published

2018

2. Melioidosis - an uncommon but also under-recognized cause of pneumonia in Papua New Guinea

Author

Warner, Jeffrey M, Pelowa, Daniel B, and Currie, Bart J

Published

2010

3. Death Adder Envenoming Causes Neurotoxicity Not Reversed by Antivenom - Australian Snakebite Project (ASP-16).

Author

Johnston, Christopher I., O'Leary, Margaret A., Brown, Simon G. A., Currie, Bart J., Halkidis, Lambros, Whitaker, Richard, Close, Benjamin, and Isbister, Geoffrey K.

Subjects

SNAKEBITES, ANTIVENINS, NEUROTOXICOLOGY, DISSEMINATED intravascular coagulation, POISONOUS snakes, ENZYME-linked immunosorbent assay

Abstract

Background: Death adders (Acanthophis spp) are found in Australia, Papua New Guinea and parts of eastern Indonesia. This study aimed to investigate the clinical syndrome of death adder envenoming and response to antivenom treatment. Methodology/Principal Findings: Definite death adder bites were recruited from the Australian Snakebite Project (ASP) as defined by expert identification or detection of death adder venom in blood. Clinical effects and laboratory results were collected prospectively, including the time course of neurotoxicity and response to treatment. Enzyme immunoassay was used to measure venom concentrations. Twenty nine patients had definite death adder bites; median age 45 yr (5–74 yr); 25 were male. Envenoming occurred in 14 patients. Two further patients had allergic reactions without envenoming, both snake handlers with previous death adder bites. Of 14 envenomed patients, 12 developed neurotoxicity characterised by ptosis (12), diplopia (9), bulbar weakness (7), intercostal muscle weakness (2) and limb weakness (2). Intubation and mechanical ventilation were required for two patients for 17 and 83 hours. The median time to onset of neurotoxicity was 4 hours (0.5–15.5 hr). One patient bitten by a northern death adder developed myotoxicity and one patient only developed systemic symptoms without neurotoxicity. No patient developed venom induced consumption coagulopathy. Antivenom was administered to 13 patients, all receiving one vial initially. The median time for resolution of neurotoxicity post-antivenom was 21 hours (5–168). The median peak venom concentration in 13 envenomed patients with blood samples was 22 ng/mL (4.4–245 ng/mL). In eight patients where post-antivenom bloods were available, no venom was detected after one vial of antivenom. Conclusions/Significance: Death adder envenoming is characterised by neurotoxicity, which is mild in most cases. One vial of death adder antivenom was sufficient to bind all circulating venom. The persistent neurological effects despite antivenom, suggests that neurotoxicity is not reversed by antivenom. Author Summary: Death adders are a genus of venomous snakes found in Australia, Papua New Guinea and Indonesia. Death adder envenoming is a rare but important health problem in Australasia. Definite death adder bites were recruited as part of the Australian Snakebite Project (ASP). Clinical effects, laboratory results and response to antivenom treatment were recorded for each case. Death adder envenoming was confirmed by enzyme immunoassay in blood collected from patients. The most important clinical effect was neurotoxicity, which was mild in most cases. One vial of antivenom was shown to be effective at binding circulating death adder venom. However, antivenom had little effect on the neurotoxicity that developed in envenomed patients and neurotoxicity took on average one day to resolve. This study supports the idea of presynaptic neurotoxicity in death adder envenoming which was previously thought to be due to post-synaptic neurotoxicity. The study calls into question the benefit of antivenom, with poor response shown in patients with both mild and severe envenoming. [ABSTRACT FROM AUTHOR]

Published

2012

4. Epidemiological tracking and population assignment of the non-clonal bacterium, Burkholderia pseudomallei.

Author

Dale J, Price EP, Hornstra H, Busch JD, Mayo M, Godoy D, Wuthiekanun V, Baker A, Foster JT, Wagner DM, Tuanyok A, Warner J, Spratt BG, Peacock SJ, Currie BJ, Keim P, and Pearson T

Subjects

Algorithms, Asia, Southeastern epidemiology, Australia epidemiology, Bayes Theorem, Burkholderia pseudomallei classification, Burkholderia pseudomallei genetics, Computational Biology, Databases, Factual, Gene Frequency, Genetics, Population, Humans, Multilocus Sequence Typing, Papua New Guinea epidemiology, Software, Burkholderia pseudomallei isolation & purification, Melioidosis epidemiology, Melioidosis microbiology

Abstract

Rapid assignment of bacterial pathogens into predefined populations is an important first step for epidemiological tracking. For clonal species, a single allele can theoretically define a population. For non-clonal species such as Burkholderia pseudomallei, however, shared allelic states between distantly related isolates make it more difficult to identify population defining characteristics. Two distinct B. pseudomallei populations have been previously identified using multilocus sequence typing (MLST). These populations correlate with the major foci of endemicity (Australia and Southeast Asia). Here, we use multiple Bayesian approaches to evaluate the compositional robustness of these populations, and provide assignment results for MLST sequence types (STs). Our goal was to provide a reference for assigning STs to an established population without the need for further computational analyses. We also provide allele frequency results for each population to enable estimation of population assignment even when novel STs are discovered. The ability for humans and potentially contaminated goods to move rapidly across the globe complicates the task of identifying the source of an infection or outbreak. Population genetic dynamics of B. pseudomallei are particularly complicated relative to other bacterial pathogens, but the work here provides the ability for broad scale population assignment. As there is currently no independent empirical measure of successful population assignment, we provide comprehensive analytical details of our comparisons to enable the reader to evaluate the robustness of population designations and assignments as they pertain to individual research questions. Finer scale subdivision and verification of current population compositions will likely be possible with genotyping data that more comprehensively samples the genome. The approach used here may be valuable for other non-clonal pathogens that lack simple group-defining genetic characteristics and provides a rapid reference for epidemiologists wishing to track the origin of infection without the need to compile population data and learn population assignment algorithms.

Published

2011

5. Melioidosis--an uncommon but also under-recognized cause of pneumonia in Papua New Guinea.

Author

Warner JM, Pelowa DB, and Currie BJ

Subjects

Animals, Burkholderia pseudomallei classification, Burkholderia pseudomallei isolation & purification, Burkholderia pseudomallei pathogenicity, Humans, Papua New Guinea epidemiology, Melioidosis complications, Melioidosis epidemiology, Pneumonia epidemiology, Pneumonia microbiology

Abstract

Melioidosis is being increasingly recognized as an important cause of severe, acute community-acquired pneumonia in various tropical regions. The chronic form of melioidosis can also mimic tuberculosis. Studies have established that, while uncommon in the Port Moresby region, melioidosis is an important cause of pneumonia and sepsis in the Balimo region of Western Province. Phylogenetic analyses of strains of Burkholderia pseudomallei from Papua New Guinea have shown them to be more closely related to strains of B. pseudomallei from Australia than to strains from Southeast Asia. This is consistent with the proposed origins of B. pseudomallei in Australia, with subsequent spread out of Australia to Southeast Asia during the last ice age. Further surveillance across Papua New Guinea is likely to unmask other locations where B. pseudomallei occurs in the environment and where melioidosis is currently not being diagnosed.

Published

2010

6. Clonality and recombination in genetically differentiated subgroups of Cryptococcus gattii.

Author

Campbell LT, Currie BJ, Krockenberger M, Malik R, Meyer W, Heitman J, and Carter D

Subjects

Animals, Australia epidemiology, Cryptococcosis epidemiology, Cryptococcosis microbiology, Cryptococcus classification, Eucalyptus microbiology, Genes, Fungal, Genetic Variation, Genotype, Humans, Papua New Guinea epidemiology, Phylogeny, Polymorphism, Genetic, Cryptococcus genetics, Recombination, Genetic genetics

Abstract

Cryptococcus gattii is a pathogenic yeast that together with Cryptococcus neoformans causes cryptococcosis in humans and animals. High numbers of viable C. gattii propagules can be obtained from certain species of Australian Eucalyptus camaldulensis trees, and an epidemiological link between Eucalyptus colonization and human exposure has been proposed. However, the highest prevalence of C. gattii cryptococcosis occurs in Papua New Guinea and in regions of Australia where the eucalypt species implicated to date are not endemic. This study investigated the population structure of three geographically distinct clinical and veterinary populations of C. gattii from Australia and Papua New Guinea. All populations that consisted of a genotype found frequently in Australia (VGI) were strongly clonal and were highly differentiated from one another. Two populations of the less common VGII genotype from Sydney and the Northern Territory had population structures inferring recombination. In addition, there was some evidence of reduced genetic differentiation between these geographically remote regions. In a companion study presented in this issue, VGII isolates were overwhelmingly more fertile than those of the VGI genotype, giving biological support to the indirect assessment of sexual exchange. It appears that the VGI genotype propagates clonally on eucalypts in Australia and on an unknown substrate in Papua New Guinea, with infection initiated by an unidentified infectious propagule. VGII isolates are completing their life cycles and may be dispersed via sexually produced basidiospores, which are also likely to initiate respiratory infection.

Published

2005