Likelihood ratio slide rule (October 24, 2002) Category:
Diagnostic testing
I am updating this page to reflect recent changes and new activities centering around the Likelihood Ratio Slide Rule. Stay tuned!
The use of likelihood ratios requires a bit of tedious calculations. I have
developed a simple slide rule that will do likelihood ratio calculations
for you.
Note: I am developing a special handout (PDF
format) that explains the mathematics behind diagnostic testing and which
illustrates many of the important points using the likelihood ratio slide
rule. I distributed this handout in a talk for the American College of
Allergy, Asthma & Immunology on Sunday, November 11, but ran out very quickly.
Assembly instructions
Please print out this this PDF file. Cut out the bottom piece (the sleeve) and the top piece (the insert).
Also cut out the two rectangles in the middle of the sleeve. Fold the left
and right portions of the sleeve behind and tape them together. Double
sided tape works very well for this. Slip the insert into the sleeve. You may
need to trim a tiny amount off the left and right sides of the insert to get
it to fit well. You want the insert to fit not too snugly and not too
loosely inside the sleeve.
For a more durable slide rule
If you print this to a regular sheet of paper, the slide rule will be okay
but a bit flimsy and easy to bend. For a more durable slide rule, print
out the image on a thick piece of paper or tape/glue the image to a
thin piece of cardboard. You can also print the image on a full sheet
adhesive label (like Avery 5165) and then attach the label to a thick
piece of paper or a thin piece of cardboard.
How to use the slide rule
Slide the insert up or down until the pre-test probability in the left
window lines up with the likelihood ratio. Read the post-test
probability in the right window.
Examples
In Watkins et al 2001, a single question diagnostic test (the Yale-Brown
obsessive-compulsive scale) was compared to a "gold standard" measure of
depression, the Montgomery Asberg depression rating scale (MADRS).
On the MADRS 43 (54%) were classified as clinically depressed; 37
answered "yes" to the Yale single question and six answered "no." Of the 36
classified as not depressed, eight answered "yes" and 28 "no." The values
(95% confidence intervals) for the Yale test were sensitivity 86% (75% to
97%), specificity 78% (65% to 91%), positive predictive value 82% (71% to
93%), negative predictive value 82% (69% to 95%); 82% (73% to 91%) of cases
were classified correctly.
The prevalence of depression in this population was unusually high, so the
authors presented additional positive predictive values (PPV) and negative
predictive values (NPV) for prevalence values ranging from 10% to 90%. An
abridged version of their table appears below.
| Prevalence |
PPV |
NPV |
| 90% |
97% |
38% |
| 80% |
94% |
58% |
| 70% |
90% |
70% |
| 60% |
85% |
79% |
| 50% |
80% |
85% |
| 40% |
72% |
89% |
| 30% |
63% |
93% |
| 20% |
49% |
96% |
| 10% |
30% |
98% |
Since the PPV is simply the post-test probability after a positive test, we
can use the likelihood ratio slide rule to re-create their calculations.
First, we need to compute the likelihood ratio for a positive test (LR+). The
formula is
LR+ = Sn / (1-Sp) = 0.86 / (1-0.78) = 3.9
where Sn and Sp are sensitivity and specificity, respectively. We will
round this value to 4.
To compute the positive predictive value when the prevalence of the disease
is 10%, line up the 10% pre-test probability with
the likelihood ratio of 4 (the unlabelled tick mark between 3 and
5). In the right side window, the post-test
probability should be slightly more than 30%, which matches the
value computed by Watkins.
Slide the insert up so the 20% pre-test
probability lines up with the likelihood ratio of 4. The
post-test probability should be around 50%
which also matches the value in Watkins.
Now slide the insert up so the 30% pre-test
probability lines up with the likelihood ratio of 4. The
post-test probability should be slightly more than
60%.
Repeat this for 40%, through 90% and
see if you can estimate the remaining PPV values.
To compute NPV, we need to calculate the likelihood ratio for a negative
test (LR-). The formula is
LR- = (1-Sp) / Sn = (1-0.86) / 0.78 = 0.18.
There is no tick mark for 0.18, so we will use a point about halfway
between the 0.15 and 0.2 tick marks. Line up the
prevalence of 10% with the likelihood ratio of 0.18 and read off
the post-test probability of 2% in the
right side window. Since there is only a 2% chance of having the disease,
there is a 98% of being healthy, which
matches the NPV computed by Watkins.
Line up a prevalence of 20% with the likelihood
ratio of 0.18 to get a post-test probability of 4% and an NPV of 96%.
Now line up a prevalence of 30% with the
likelihood ratio of 0.18 to get a post-test probability of 7% and an NPV of
93%.
Repeat this for 40% through 90% and
estimate the remaining NPV values.
Second example
A letter to the editor in BMJ commented on how the use of likelihood ratios
could have simplified the interpretation of results of a rapid whole blood
test for diagnosing Helicobacter pylori infection.
In that study the likelihood ratio for a positive test result was 9.8.
The advantage of knowing this is that it can be applied to similar patients
in other populations to estimate the predictive value of the test, provided
that the pre-test probability of disease can be estimated. For example, H
pylori is found in 48% of dyspeptic patients in the community (the pre-test
probability), so therefore a positive rapid blood test with a likelihood
ratio of 9.8 applied to this population would give a post-test probability
(or predictive value) of 90% (this can be estimated using a simple
calculation or a nomogram). --BMJ 1997; 314: 1688.
We have to round a bit here. Line up a pre-test
probability of 50% with a likelihood ratio of 10. Read the post-test
probability of slightly more than 90% in the upper window.
Third example
Buschbaum et al examined the sensitivity, specificity, and likelihood ratio
for the CAGE score, a series of yes/no answers to four questions (Ann Intern
Med 1991; 115(10): 774-777). The four item scale was very good at detecting
alcohol abuse or dependence.
| Score |
Abuse or
Dependence |
No abuse or
dependence |
Likelihood
ratio |
| 0 |
33 |
428 |
0.14 |
| 1 |
45 |
54 |
1.5 |
| 2 |
86 |
34 |
4.5 |
| 3 |
74 |
10 |
13 |
| 4 |
56 |
1 |
100 |
In this paper, the authors noted a prevalence of alcohol abuse and
dependence of 36%. Find this value in the pre-test probability and line it up
successively with each of the likelihood ratios listed above. You should get
a post-test probability of 7%, 45%, 70%, 90% and 98%
for the scores of 0 through 4, which matches up nicely with the
values given in the paper. The likelihood ratio slide rule computations are
shown below for the first three of these cases.
Grant et al tabulated the prevalence of alcohol abuse or dependence for
demographic groups. This rate varies by age (higher among younger people), by
gender (higher among males) and race (higher among non-blacks). Among
non-black males, for example, the prevalence is
23%, 11%, 6%, and 1% for 18-29, 30-44, 45-64, and 65+ years of age,
respectively (Alcohol Health & Research World 1994; 18(3):243-248, as quoted
in
alcoholism.about.com/library/nabdep4.htm).
The prevalence would be roughly twice as high
among ambulatory patients than the general population and
four times as high for hospitalized patients
than the general population (Postgraduate Medicine Online 1996; 100(1),
www.postgradmed.com/issues/1996/07_96/blondell.htm).
Suppose you apply the CAGE score to a 70 year old
hospitalized white male. This person
scores 3 on CAGE. Line up a pre-test
probability of 4% with a likelihood ratio of 13. The
post test probability is slightly more than 30%.
Suppose you give the same test to a 35 year old
white male who visits your clinic and he
scores 0 on CAGE. Line up a pre-test
probability of 22% with a likelihood ratio of 0.14. The
post-test probability is 4%.
How does it work?
The likelihood ratio slide rule works on the same principle as a regular
slide rule. The logarithms on a slide rule allow you to multiply simply
by adding. It uses the simple formula
log (a*b) = log (a) + log (b).
There's an old joke well known among mathematicians about logarithms. After
the flood waters receded, Noah commanded the animals to go forth and
multiply. The snakes went up to Noah and told him they couldn't
multiply because they were adders. So Noah built them a piece of wooden
furniture with a flat top and four legs. The adders could now multiply
because they had a log table.
The formula for computing post-test odds is
post-test odds = likelihood ratio * pre-test odds.
By taking logarithms of both sides of the equation, we get
log (post-test odds) = log (likelihood ratio) + log (pre-test odds)
Sliding the insert up or down will add a pre-test log odds value to a
log likelihood ratio to get a post-test log odds value. The tick marks
are labeled using probability rather than odds to simplify things further.
The likelihood ratio slide rule that I developed was inspired by the
Fagan nomogram which also uses
logarithms. In the Fagan nomogram, you draw a line connecting the pre-test
probability with the likelihood ratio. Extend the line further to the right
to compute the post-test probability.
Summary
The likelihood ratio slide rule allows you to compute the post-test
probability of a disease given the pre-test probability and the likelihood
ratio of a diagnostic test. Simply line up the pre-test probability in
the left side window with the likelihood ratio. Then read the post-test
probability in the right side window.
This work is licensed under a Creative Commons Attribution 3.0 United States License. It was written by Steve Simon.