1. An individual-based stochastic simulation model was used to investigate
the control of bovine tuberculosis (TB) in the European badger Meles meles.
Nearly all population and epidemiological parameters were derived from one
study site, and the transmission of TB from badgers to cattle was included
. The latter is an essential step if reactive badger control strategies are
to be modelled.
2. The model appeared to underestimate slightly the rate of population reco
very following widespread culling. This may have been due to simulating an
isolated population with no immigration and no compensatory increase in fec
undity. This should not affect the relative efficacy of each control strate
gy, but does require further investigation.
3. Of the historical methods of badger control, gassing and the 'clean ring
' strategies were the most effective at reducing disease prevalence in the
badger and cattle herd breakdown rates. These results agree with those of e
arlier models.
4. The proactive badger removal operation as part of the current field tria
l should cause a dramatic decrease in the number of cattle herd breakdowns,
but also has the greatest effect on the badger population size.
5. The proactive use of a live test to detect TB, followed by vaccination,
appears to reduce substantially cattle herd breakdowns and disease prevalen
ce in the badger.
6. Three combined control strategies gave the best initial reduction in cat
tle herd breakdown rate and disease prevalence in the badger: (i) a proacti
ve cull followed by reactive test and cull; (ii) a continued vaccination an
d proactive test and cull; and (iii) a continuous proactive test and cull.
7. The results of simulation models suggest that badger vaccination is a ve
ry good method of TB control. This is at odds with simple models and requir
es further investigation.