BOVINE TUBERCULOSIS TESTING IN MICHIGAN

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Title: BOVINE TUBERCULOSIS TESTING IN MICHIGAN

1
BOVINE TUBERCULOSIS TESTING IN MICHIGAN
David Blum Ioannis Giannakakis Abra Jeffers Ahren
Lacy

2
Background

Tuberculosis is a widespread, potentially fatal
disease. The bovine form of Tb, M. bovis, has a
wide range of hosts including humans.
A series of tests is performed by the state on a
percentage of all Michigan herds per year,
including
Caudal Fold Test (CFT),
Comparative Cervical Test (CCT), and
Gamma interferon.

3
Model formulation

A decision tree is constructed which includes
all the successive tests,
the probabilities of being infected given the
results of the tests,
the decisions taken about whether or not to
continue testing, and
the total cost in each of the different cases.
We treated each herd as existing in one of two
following states
high frequency of Tb infection,
low frequency of Tb infection
Tb transmission within herds with high frequency
of Tb infection is sufficiently high that it is
less costly to cull the herd than to eradicate Tb
though ongoing testing and slaughtering of
individual cattle

4
Model formulation

Before administering a test, one has a prior
belief as to whether the herd has a low infection
rate or a high infection rate
We flip the tree, to determine ones posterior
belief that the herd is highly infected given
that there are k positive readings from the
current test.
Assumption Each cow tests independently of each
other cow in the herd.
The probability of seeing k positives (given that
the herd is highly or low infected) can be
modeled as a binomial distribution.

5
Test Decision Space
6
Assessing Posterior Belief of Infection

7
Assessing Posterior Belief of Infection

The probability a cow tests positive on a test
(given it has tested positive previously)
where

8
Baseline Parameters

9
Baseline Parameters

10
Analysis

Plot P(HK) versus k at every model.
The curve is S-shaped.
As the number of positive observations within a
herd increases, the herd infection belief
increases more steeply
A sharp S curve implies a good test,
Strong distinction in posterior beliefs

11
Findings

Increasing the accuracy of any given test
sharpens the corresponding S-curve and shifts
left,
Thus fewer positive observations are required to
convince an observer that the herd is highly
infected.
Improving the accuracy of the first test (CF) is
the most efficient way to improve the information
available to an observer.
The information conveyed through subsequent tests
is less sensitive to a change in test accuracy
than each preceding test.

12
Findings

P(IH) is an important factor affecting the shape
of the P(Hk) curve.
P(IL) has little to no effect on the shape of
the posterior P(Hk) curve consistent with
assumptions
The prior belief P(H) does not affect the shape
of the P(Hk) curve, though it does shift the
curve horizontally
Thus test results greatly outweigh the prior
within a range of likely priors (0.001 to 5)

13
Figures
14
Figures
15
Figures
16
Figures
17
Figures
18
References

Jeffers, K. J. (2008). Personal Communication.
October 15, 2008.
OReilly, L. M. and C.M. Daborn. (1995). The
Epidemiology of Mycobacterium bovis Infections in
Animals and Man A Review. Tubercule and Lung
Disease. 76(S.1) 1 46.
VanderKlok, M. S. (2008). Bovine Tuberculosis in
Michigan Where We Are Today. Bovine TB
Scientific Meeting, East Lansing, MI online.
Available http//www.michigan.gov/documents/emerg
ingdiseases/MDA_Update_Part_2_249465_7.pdf
Accessed October 20, 2008.
Judge, L. J (2005). Epidemiologic update for the
Michigan bovine TB program, online. Available
http//www.michigan.gov/documents/MDA_2005_BTB_Rep
ort2_148142_7.pdf
Radintz, T, and DiConstanzo, A (2008). Impancts
of Bovine Tb Testing and Associated Costs on
Cow-Calf Producer Profitability in 2008-2009.
University of Minnesota Extension.