This thesis is about making inference on the host status of feral ferrets in New
Zealand for Mycobacterium bovis, the aetiological agent of bovine tuberculosis. The
central question addressed is whether the rate of intra-specific transmission of M. bovis
among ferrets is sufficient for the disease to persist in ferret populations in the absence
of external, non-ferret sources of infection (inter-specific transmission). The question is
tackled in three parts�firstly using model selection to identify suitable models for
estimating the force of M. bovis infection in ferret populations; secondly applying
statistical hypothesis testing to the results of planned manipulative field experiments to
test the relationship between M. bovis infection in brushtail possums and that in ferrets;
and thirdly using modelling to estimate intra-specific disease transmission rates and the
basic reproductive rate (Ro) of M. bovis infection in ferrets.
The model selection approach clearly identified the hypothesis of oral infection
related to diet was, as modelled by a constant force of infection from the age of
weaning, the best approximation of how M. bovis infection was transmitted to ferrets.
No other form of transmission (e.g., during fighting, mating, or routine social
interaction) was supported in comparison. The force of infection (λ) ranged from 0.14
yr-1 to 5.77 yr-1, and was significantly higher (2.2 times) in male than female ferrets.
Statistical hypothesis testing revealed transmission of M. bovis to ferrets
occurred from both brushtail possums and ferrets. The force of M. bovis infection in
ferrets was reduced by 88% (λ=0.3 yr-1 vs. λ=2.5 yr-1) at sites with reductions in the
population density of sympatric brushtail possum populations. A smaller decline in the
force of infection resulting from the lethal cross-sectional sampling of the ferret
populations was also demonstrated.
The modelling approach estimated the basic reproductive rate (Ro) of M. bovis
infection in ferrets in New Zealand to vary from 0.17 at the lowest population density
(0.5 km-2) recorded to 1.6 at the highest population density (3.4 km-2) recorded. The
estimates of Ro were moderately imprecise, with a coefficient of variation of 76%.
Despite this imprecision, the Ro for M. bovis infection in ferrets was significantly less
than unity for all North Island sites surveyed. Hence it is inferred ferrets are spillover
hosts (0<Ro<1) for M. bovis infection in these environments. That is, M. bovis infection
will progressively disappear from these ferret populations if the source of inter-specific
transmission is eliminated. The estimates of Ro for M. bovis infection in South Island
ferret populations were above one (the level required for disease establishment) for a
number (5/10) of populations, though the imprecision made it impossible to ascertain
whether Ro was significantly greater than one. The estimated threshold population
density (Kt) for disease establishment was 2.9 ferrets km-2. It is inferred that, given
sufficient population density (>Kt), the rate of intra-specific transmission of M. bovis
among ferrets is sufficient for the disease to establish in ferrets in the absence of interspecific
transmission. In these areas, ferrets would be considered maintenance hosts for
the disease. Active management (e.g., density reduction or vaccination) of ferrets
would be required to eradicate M. bovis from ferret populations in these areas, in
addition to the elimination of sources of inter-specific transmission, particularly brushtail possums.
Identifer | oai:union.ndltd.org:ADTP/218621 |
Date | January 2001 |
Creators | Caley, Peter, n/a |
Publisher | University of Canberra. Resource, Environment & Heritage Studies |
Source Sets | Australiasian Digital Theses Program |
Language | English |
Detected Language | English |
Rights | ), Copyright Peter Caley |
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