In pierucci/heemod: Markov Models for Health Economic Evaluations
library(heemod)
This document is a presentation of the basic steps to define and run a model in heemod. Note that decision trees are actually a subset even of Markov model, and thus can be specified easily with this package.
When building a Markov model the following steps must be performed:
- Specify transition probabilities between states.
- Specify values attached to states (costs, utilities, etc.).
- Combine this information and run the model.
Transition probabilities
The probability to transition from one state to another during a time period is called a transition probability. Said time period is called a cycle.
Transition probabilities between states can be described through a 2-way table where the lines correspond to the states at the beginning of a cycle and the columns to the states at the end of a cycle. Consider a model with 2 states A and B:
| | A | B |
|-------|---|---|
| A | 1 | 2 |
| B | 3 | 4 |
When starting a cycle in state A (row A), the probability to still be in state A at the end of the cycle is found in colunm A (cell 1) and the probability to change to state B is found in column B (cell 2).
Similarly, when starting a cycle from state B (row B), the probability to be in state A or B at the end of the cycle are found in cells 3 or 4 respectively.
In the context of Markov models, this 2-way table is called a transition matrix. A transition matrix can be defined easily in heemod with the define_transition() function. If we consider the previous example, where cell values have been replaced by actual probabilities:
| | A | B |
|-------|-----|-----|
| A | 0.9 | 0.1 |
| B | 0.2 | 0.8 |
That transition matrix can be defined with the following command:
mat_trans <- define_transition(
.9, .1,
.2, .8
)
mat_trans
Attach values to states
Values are attached to states. Cost and utility are classical examples of such values. To continue with the previous example, the following values can be attachd to state A and B:
- State A has a cost of 1234 per cycle and an utility of 0.85.
- State B has a cost of 4321 per cycle and an utility of 0.50.
A state and its values can be defined with define_state():
state_A <- define_state(
cost = 1234,
utility = 0.85
)
state_A
state_B <- define_state(
cost = 4321,
utility = 0.50
)
state_B
Combine information in a model
Now that the transition matrix and the state values are defined for a given strategy, we can combine them with define_strategy():
strat <- define_strategy(
transition = mat_trans,
state_A,
state_B
)
strat
Run the model
A model is a made of one or more strategy, run with run_model() for a given number of cycles. Here we run only one strategy, so no comparison of the cost-effectiveness of the different strategies will be made. The variables corresponding to valuation of cost and effect must be given at that point.
res_mod <- run_model(
strat,
cycles = 10,
cost = cost,
effect = utility
)
res_mod
By default the model is run for 1000 persons starting in the first state (here state A).
Analyse results
We can plot the state membership counts over time. Other plot types are available.
plot(res_mod)
Plots can be modified using ggplot2 syntax.
library(ggplot2)
plot(res_mod) +
xlab("Time") +
ylab("N") +
theme_minimal() +
scale_color_brewer(
name = "State",
palette = "Set1"
)
And black & white plots for publication are available with the bw plot option
library(ggplot2)
plot(res_mod, bw = TRUE)
The state membership counts and the values can be accessed with get_counts() and get_values() respectively.
head(get_counts(res_mod))
head(get_values(res_mod))
Convenience functions
Convenience functions are available to easily compute transition probabilities from indidence rates, OR, RR, or probabilities estimated on a different timeframe.
Example : convert an incidence rate of 162 cases per 1,000 person-years to a 5-year probability.
rate_to_prob(r = 162, per = 1000, to = 5)
See ?probability to see a list of the convenience functions available.
External data
Mortality rates by age and sex (often used as transition probabilities) can be downloaded from the WHO online database with the function get_who_mr().
External data contained in user-defined data frames can be referenced in a model with the function look_up().
Compare strategies
In order to compare different strategies it is possible to run a model with multiple strategies in parallel, examples are provided in vignette("c-homogeneous", "heemod") or vignette("d-non-homogeneous", "heemod").
Time-variability
Time varying transition probabilities and state values are available through the markov_cycle and state_cycle variables. Time-varying probabilities and values are explained in vignette("b-time-dependency", "heemod").
Transition costs
Transition costs between states can be defined by adding an additional state called a transition state. This is a special case of a tunnel state. A situation where the transtion from A to B (noted A->B) costs \$100 and reduces utility by 0.1 points compared to the usual values of B can be modelled by adding a state B_trans.
The cost and utility of B_trans are the same as those of B +\$100 and -0.1 QALY respectively.
A->B_trans is equal to the former value of A->B. A->B is set to 0 (all transitions from A to B must pass through B_trans from now on).
The probability to stay in B_trans is 0, B_trans->B is equal to B->B and similarly all B_trans->* are equal to B->*.
Parallel computing
Some operation such as PSA can be significantly sped up using parallel computing. This can be done in the following way:
- Define a cluster with the
use_cluster() functions (i.e. use_cluster(4) to use 4 cores).
- Run the analysis as usual.
- To stop using parallel computing use the
close_cluster() function.
Results may vary depending on the machine, but we found speed gains to be quite limited beyond 4 cores.
Going further
Probabilistic uncertainty analysis vignette("e-probabilistic", "heemod") and deterministic sensitivity analysis vignette("f-sensitivity", "heemod") can be performed. Population-level estimates and heterogeneity can be computed : vignette("g-heterogeneity", "heemod").
pierucci/heemod documentation built on July 17, 2022, 9:27 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
library(heemod)
This document is a presentation of the basic steps to define and run a model in heemod. Note that decision trees are actually a subset even of Markov model, and thus can be specified easily with this package.
When building a Markov model the following steps must be performed:
- Specify transition probabilities between states.
- Specify values attached to states (costs, utilities, etc.).
- Combine this information and run the model.
Transition probabilities
The probability to transition from one state to another during a time period is called a transition probability. Said time period is called a cycle.
Transition probabilities between states can be described through a 2-way table where the lines correspond to the states at the beginning of a cycle and the columns to the states at the end of a cycle. Consider a model with 2 states A and B:
| | A | B | |-------|---|---| | A | 1 | 2 | | B | 3 | 4 |
When starting a cycle in state A (row A), the probability to still be in state A at the end of the cycle is found in colunm A (cell 1) and the probability to change to state B is found in column B (cell 2).
Similarly, when starting a cycle from state B (row B), the probability to be in state A or B at the end of the cycle are found in cells 3 or 4 respectively.
In the context of Markov models, this 2-way table is called a transition matrix. A transition matrix can be defined easily in heemod with the define_transition() function. If we consider the previous example, where cell values have been replaced by actual probabilities:
| | A | B | |-------|-----|-----| | A | 0.9 | 0.1 | | B | 0.2 | 0.8 |
That transition matrix can be defined with the following command:
mat_trans <- define_transition( .9, .1, .2, .8 ) mat_trans
Attach values to states
Values are attached to states. Cost and utility are classical examples of such values. To continue with the previous example, the following values can be attachd to state A and B:
- State A has a cost of 1234 per cycle and an utility of 0.85.
- State B has a cost of 4321 per cycle and an utility of 0.50.
A state and its values can be defined with define_state():
state_A <- define_state( cost = 1234, utility = 0.85 ) state_A state_B <- define_state( cost = 4321, utility = 0.50 ) state_B
Combine information in a model
Now that the transition matrix and the state values are defined for a given strategy, we can combine them with define_strategy():
strat <- define_strategy( transition = mat_trans, state_A, state_B ) strat
Run the model
A model is a made of one or more strategy, run with run_model() for a given number of cycles. Here we run only one strategy, so no comparison of the cost-effectiveness of the different strategies will be made. The variables corresponding to valuation of cost and effect must be given at that point.
res_mod <- run_model( strat, cycles = 10, cost = cost, effect = utility ) res_mod
By default the model is run for 1000 persons starting in the first state (here state A).
Analyse results
We can plot the state membership counts over time. Other plot types are available.
plot(res_mod)
Plots can be modified using ggplot2 syntax.
library(ggplot2) plot(res_mod) + xlab("Time") + ylab("N") + theme_minimal() + scale_color_brewer( name = "State", palette = "Set1" )
And black & white plots for publication are available with the bw plot option
library(ggplot2) plot(res_mod, bw = TRUE)
The state membership counts and the values can be accessed with get_counts() and get_values() respectively.
head(get_counts(res_mod)) head(get_values(res_mod))
Convenience functions
Convenience functions are available to easily compute transition probabilities from indidence rates, OR, RR, or probabilities estimated on a different timeframe.
Example : convert an incidence rate of 162 cases per 1,000 person-years to a 5-year probability.
rate_to_prob(r = 162, per = 1000, to = 5)
See ?probability to see a list of the convenience functions available.
External data
Mortality rates by age and sex (often used as transition probabilities) can be downloaded from the WHO online database with the function get_who_mr().
External data contained in user-defined data frames can be referenced in a model with the function look_up().
Compare strategies
In order to compare different strategies it is possible to run a model with multiple strategies in parallel, examples are provided in vignette("c-homogeneous", "heemod") or vignette("d-non-homogeneous", "heemod").
Time-variability
Time varying transition probabilities and state values are available through the markov_cycle and state_cycle variables. Time-varying probabilities and values are explained in vignette("b-time-dependency", "heemod").
Transition costs
Transition costs between states can be defined by adding an additional state called a transition state. This is a special case of a tunnel state. A situation where the transtion from A to B (noted A->B) costs \$100 and reduces utility by 0.1 points compared to the usual values of B can be modelled by adding a state B_trans.
The cost and utility of B_trans are the same as those of B +\$100 and -0.1 QALY respectively.
A->B_trans is equal to the former value of A->B. A->B is set to 0 (all transitions from A to B must pass through B_trans from now on).
The probability to stay in B_trans is 0, B_trans->B is equal to B->B and similarly all B_trans->* are equal to B->*.
Parallel computing
Some operation such as PSA can be significantly sped up using parallel computing. This can be done in the following way:
- Define a cluster with the
use_cluster()functions (i.e.use_cluster(4)to use 4 cores). - Run the analysis as usual.
- To stop using parallel computing use the
close_cluster()function.
Results may vary depending on the machine, but we found speed gains to be quite limited beyond 4 cores.
Going further
Probabilistic uncertainty analysis vignette("e-probabilistic", "heemod") and deterministic sensitivity analysis vignette("f-sensitivity", "heemod") can be performed. Population-level estimates and heterogeneity can be computed : vignette("g-heterogeneity", "heemod").
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.