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This vignette will show the internal functions for generating data that can be used in simulation studies.
First we define how to generate baseline data for our study. In its simplest form we only need to define how many patients are in the arms: treated internal, control internal, control external.
This object defines how the data will be created. To actually
generate a sample, use generate()
to produce a list
containing data.frame
s for each arm. We can convert this to
a single data.frame
if needed.
baseline_data <- generate(simple_baseline)
baseline_data
#> Baseline Data List
#>
#> Internal Treated
#> patid ext trt
#> 1 0 1
#> 2 0 1
#> 3 0 1
#> 4 0 1
#> 5 0 1
#> 6 0 1
#> Internal Control
#> patid ext trt
#> 101 0 0
#> 102 0 0
#> 103 0 0
#> 104 0 0
#> 105 0 0
#> 106 0 0
#> External Control
#> patid ext trt
#> 151 1 0
#> 152 1 0
#> 153 1 0
#> 154 1 0
#> 155 1 0
#> 156 1 0
as.data.frame(baseline_data)
#> patid ext trt
#> 1 1 0 1
#> 2 2 0 1
#> 3 3 0 1
#> 4 4 0 1
#> 5 5 0 1
#> 6 6 0 1
#> [ reached 'max' / getOption("max.print") -- omitted 244 rows ]
Often we are interested in some additional covariates. Internally the package uses multivariate normal distributions, so we need to specify the means and (co-)variances. We have the option to specify different distribution parameters for the internal and external arms. The internal arms are assumed to be randomized and therefore come from the same distribution. If no external parameters are specified, the internal ones are used for both.
with_age <- create_baseline_object(
n_trt_int = 100,
n_ctrl_int = 50,
n_ctrl_ext = 100,
covariates = baseline_covariates(
names = "age",
means_int = 55,
covariance_int = covariance_matrix(5)
)
)
set.seed(123)
generate(with_age)
#> Baseline Data List
#>
#> Internal Treated
#> patid ext trt age
#> 1 0 1 53.74674
#> 2 0 1 54.48531
#> 3 0 1 58.48538
#> 4 0 1 55.15766
#> 5 0 1 55.28910
#> [ reached 'max' / getOption("max.print") -- omitted 1 rows ]
#> Internal Control
#> patid ext trt age
#> 101 0 0 53.41148
#> 102 0 0 55.57441
#> 103 0 0 54.44838
#> 104 0 0 54.22287
#> 105 0 0 52.87212
#> [ reached 'max' / getOption("max.print") -- omitted 1 rows ]
#> External Control
#> patid ext trt age
#> 151 1 0 56.76144
#> 152 1 0 56.71963
#> 153 1 0 55.74283
#> 154 1 0 52.74520
#> 155 1 0 54.73290
#> [ reached 'max' / getOption("max.print") -- omitted 1 rows ]
In a more complex setting, we can generate correlated baseline covariates by specifying a variance-covariance matrix as the main diagonal (variance components) and the upper triangle (covariance components).
covariance_matrix(diag = c(5, 1.2), upper_tri = c(0.1))
#> [,1] [,2]
#> [1,] 5.0 0.1
#> [2,] 0.1 1.2
with_age_score <- create_baseline_object(
n_trt_int = 100,
n_ctrl_int = 50,
n_ctrl_ext = 100,
covariates = baseline_covariates(
names = c("age", "score"),
means_int = c(55, 5),
means_ext = c(60, 5),
covariance_int = covariance_matrix(diag = c(5, 1)),
covariance_ext = covariance_matrix(diag = c(5, 1.2), upper_tri = c(0.1))
)
)
data_age_score <- generate(with_age_score)
df_age_score <- as.data.frame(data_age_score)
plot(
x = df_age_score$age,
y = df_age_score$score,
col = df_age_score$trt + 1,
pch = df_age_score$ext * 16,
xlab = "Age",
ylab = "Score"
)
legend(
"topright",
legend = c("internal treated", "internal control", "external control"),
col = c(2, 1, 1),
pch = c(0, 0, 16)
)
Finally, we have the option to transform non-normal covariates, such as with binary cut-offs. These can be added to existing objects and can use built-in functions or used defined.
with_age_score <- with_age_score %>%
set_transformations(
score_high = binary_cutoff("score", int_cutoff = 0.7, ext_cutoff = 0.7),
score_rounded = function(data) round(data$score)
)
set.seed(123)
generate(with_age_score)
#> Baseline Data List
#>
#> Internal Treated
#> patid ext trt age score score_high score_rounded
#> 1 0 1 53.74674 4.769823 0 5
#> 2 0 1 58.48538 5.070508 0 5
#> [ reached 'max' / getOption("max.print") -- omitted 4 rows ]
#> Internal Control
#> patid ext trt age score score_high score_rounded
#> 101 0 0 59.91669 6.312413 1 6
#> 102 0 0 54.40712 5.543194 1 6
#> [ reached 'max' / getOption("max.print") -- omitted 4 rows ]
#> External Control
#> patid ext trt age score score_high score_rounded
#> 151 1 0 58.40067 4.247311 0 4
#> 152 1 0 57.90136 3.947487 0 4
#> [ reached 'max' / getOption("max.print") -- omitted 4 rows ]
Using the baseline object we have specified, we can generate survival outcome data including various parameters like dropout rate, enrollment rate and clinical cut-off.
First we need to specify the outcome distribution. The underlying
data generation is handled by the simsurv
package. The
create_event_dist()
function take the parameters needed to
define the distribution. In the simplest case we can use an exponential
distribution by specifying a single lambda
parameter. We
could also use Weibull or Gompertz distributions, mixtures of
distributions, or even specify an arbitrary (log/cumulative) hazard
function.
The minimum required parameters to create a data simulation object are a baseline object and an event distribution.
create_data_simulation(
baseline = create_baseline_object(n_trt_int = 100, n_ctrl_int = 50, n_ctrl_ext = 100),
event_dist = exponential_dist
) %>% generate()
#> SimDataList object with 1 different scenarios
#> sim_id treatment_hr drift_hr n_datasets_per_param
#> 1 1 1 1 1
We can expand by including a baseline object with covariates and so
we need coefficients for including them in the hazard calculation.
Further we can include coefficient for the treatment parameter
(treatment_hr
) and for the difference between internal and
external arms (drift_hr
).
data_sim <- create_data_simulation(
baseline = with_age_score,
coefficients = c(age = 0.001, score_high = 1.5),
event_dist = exponential_dist,
treatment_hr = 0.5,
drift_hr = 0.9
)
data_list <- generate(data_sim)
data_list
#> SimDataList object with 1 different scenarios
#> sim_id treatment_hr drift_hr n_datasets_per_param
#> 1 1 0.5 0.9 1
We can peek at the data with get_data()
:
get_data(data_list, index = 1, dataset = 1) %>% head()
#> patid age score_high trt ext eventtime status enrollment cens
#> 1 1 53.25887 0 1 0 163.587989 1 1 0
#> 2 2 55.64217 0 1 0 6.884799 1 1 0
#> [ reached getOption("max.print") -- omitted 4 rows ]
We can control how datasets are generated with the n
,
treatment_hr
and drift_hr
parameters of
generate()
. These will override the defaults specified in
create_data_simulation()
.
generate(data_sim, n = 10, treatment_hr = c(1, 1.3, 2), drift_hr = c(1, 1.2))
#> SimDataList object with 6 different scenarios
#> sim_id treatment_hr drift_hr n_datasets_per_param
#> 1 1 1.0 1.0 10
#> 2 2 1.3 1.0 10
#> 3 3 2.0 1.0 10
#> 4 4 1.0 1.2 10
#> 5 5 1.3 1.2 10
#> [ reached 'max' / getOption("max.print") -- omitted 1 rows ]
To add other features to the simulation there are
set_enrollment()
, set_cut_off()
and
set_dropout()
functions which modify a
DataSimObject
.
Currently only one enrollment option is defined,
enrollment_constant
where a fixed number of patients are
enrolled in each period for a given time duration, so
enrollment_constant(rate = c(5, 2), for_time = c(4, 5))
enrolls 5 patients in periods 1, 2, 3, 4, and then 2 patients each in 5,
6, 7, 8, 9.
New methods can be specified by defining a function that takes a
parameter n
, the number of patients to generate enrollment
times for.
poisson_enrollment <- custom_enrollment(
fun = function(n) rpois(n, lambda = 5),
label = "Poisson enrollment distribution"
)
set_enrollment(data_sim, internal = poisson_enrollment)
#> DataSimObject
#> -------------
#> Baseline object:
#> Baseline Data Simulation Object
#> N internal treated: 100
#> N internal control: 50
#> N external control: 100
#>
#> Covariates:
#> [[1]]
#> covariate means_internal means_external
#> age 55 60
#> score 5 5
#>
#> Covariance Matrices
#> Internal External
#> age score age score
#> age 5 0 age 5.0 0.1
#> score 0 1 score 0.1 1.2
#>
#> Transformations:
#> score_high, score_rounded
#>
#> Event distribution:
#> exponential distribution with lambda = 0.0416666666666667
#>
#> Treatment HR: 0.5
#> Drift HR: 0.9
#>
#> Coefficients:
#> age score_high
#> 0.001 1.500
#>
#> Enrollment:
#> Internal: Poisson enrollment distribution
#> External: Poisson enrollment distribution
#>
#> Dropout:
#> Internal treated: No distribution specified
#> Internal control: No distribution specified
#> External control: No distribution specified
#>
#> Clinical cut off:
#> Internal: No cut off
#> External: No cut off
Drop out is defined using the same create_event_dist()
function as for the survival time. No covariates can be specified for
these distributions, but we can set different distributions for the
three arms.
set_dropout(
data_sim,
internal_treated = create_event_dist(dist = "exponential", lambdas = 1 / 50),
internal_control = create_event_dist(dist = "exponential", lambdas = 1 / 55),
external_control = create_event_dist(dist = "weibull", lambdas = 1 / 40, gammas = 1.1)
)
#> DataSimObject
#> -------------
#> Baseline object:
#> Baseline Data Simulation Object
#> N internal treated: 100
#> N internal control: 50
#> N external control: 100
#>
#> Covariates:
#> [[1]]
#> covariate means_internal means_external
#> age 55 60
#> score 5 5
#>
#> Covariance Matrices
#> Internal External
#> age score age score
#> age 5 0 age 5.0 0.1
#> score 0 1 score 0.1 1.2
#>
#> Transformations:
#> score_high, score_rounded
#>
#> Event distribution:
#> exponential distribution with lambda = 0.0416666666666667
#>
#> Treatment HR: 0.5
#> Drift HR: 0.9
#>
#> Coefficients:
#> age score_high
#> 0.001 1.500
#>
#> Enrollment:
#> Internal: Enrolling 1 patient per time
#> External: Enrolling 1 patient per time
#>
#> Dropout:
#> Internal treated: exponential distribution with lambda = 0.02
#> Internal control: exponential distribution with lambda = 0.0181818181818182
#> External control: weibull distribution with lambda = 0.025 and gamma = 1.1
#>
#> Clinical cut off:
#> Internal: No cut off
#> External: No cut off
In some cases we want to mimic a clinical trial cut off rule, where
all patient data after a certain time are censored. Different rules are
available such as: - fixed time after first patient is enrolled
cut_off_after_first(time = 36)
- fixed time after last
patient is enrolled cut_off_after_first(time = 60)
- fixed
number of events observed cut_off_after_events(n = 45)
If a patient has survival time longer than these rules their status
will be set to 0
and eventtime
set to the cut
off time.
set_cut_off(
data_sim,
internal = cut_off_after_first(time = 36),
external = cut_off_after_events(n = 45)
)
#> DataSimObject
#> -------------
#> Baseline object:
#> Baseline Data Simulation Object
#> N internal treated: 100
#> N internal control: 50
#> N external control: 100
#>
#> Covariates:
#> [[1]]
#> covariate means_internal means_external
#> age 55 60
#> score 5 5
#>
#> Covariance Matrices
#> Internal External
#> age score age score
#> age 5 0 age 5.0 0.1
#> score 0 1 score 0.1 1.2
#>
#> Transformations:
#> score_high, score_rounded
#>
#> Event distribution:
#> exponential distribution with lambda = 0.0416666666666667
#>
#> Treatment HR: 0.5
#> Drift HR: 0.9
#>
#> Coefficients:
#> age score_high
#> 0.001 1.500
#>
#> Enrollment:
#> Internal: Enrolling 1 patient per time
#> External: Enrolling 1 patient per time
#>
#> Dropout:
#> Internal treated: No distribution specified
#> Internal control: No distribution specified
#> External control: No distribution specified
#>
#> Clinical cut off:
#> Internal: Cut off after first enrolled patient reaches time = 36
#> External: Cut off after 45 events
Putting all that together:
my_baseline <- create_baseline_object(
n_trt_int = 100,
n_ctrl_int = 50,
n_ctrl_ext = 100,
covariates = baseline_covariates(
names = c("age", "score"),
means_int = c(55, 5),
means_ext = c(60, 5),
covariance_int = covariance_matrix(diag = c(5, 1)),
covariance_ext = covariance_matrix(diag = c(5, 1.2), upper_tri = c(0.1))
),
transformations = list(score_high = binary_cutoff("score", int_cutoff = 0.7, ext_cutoff = 0.7))
)
my_data_sim_setup <- create_data_simulation(
baseline = my_baseline,
coefficients = c(age = 0.001, score_high = 1.1),
event_dist = create_event_dist(dist = "exponential", lambdas = 1 / 50)
) %>%
set_enrollment(
internal = enrollment_constant(rate = c(25, 10), for_time = c(4, 30)),
external = enrollment_constant(rate = c(30, 10), for_time = c(4, 30))
) %>%
set_dropout(
internal_treated = create_event_dist(dist = "exponential", lambdas = 1 / 50),
internal_control = create_event_dist(dist = "exponential", lambdas = 1 / 55),
external_control = create_event_dist(dist = "exponential", lambdas = 1 / 40)
) %>%
set_cut_off(
internal = cut_off_after_first(time = 60),
external = cut_off_after_events(n = 100)
)
my_data_list <- generate(my_data_sim_setup, n = 3, treatment_hr = c(1, 1.3), drift_hr = c(1, 1.2))
Now we can define the simulation setup for the models:
borrowing <- sim_borrowing_list(list(full = borrowing_full("ext")))
outcome <- sim_outcome_list(
list(standard_outcome = outcome_surv_exponential(
time_var = "eventtime",
cens_var = "cens",
baseline_prior = prior_normal(0, 1000)
))
)
covariate <- sim_covariate_list(list(
cov1 = add_covariates(c("age", "score_high"), prior_normal(0, 1000)),
no_covs = NULL
))
treatment <- sim_treatment_list(
list(standard_tx = treatment_details(trt_flag_col = "trt", trt_prior = prior_normal(0, 1000)))
)
sim_obj <- create_simulation_obj(
data_matrix_list = my_data_list,
outcome = outcome,
borrowing = borrowing,
treatment = treatment,
covariate = covariate
)
And finally sample from these models. See the vignette “4. Conduct a simulation study” for more details.
We can also include a known data set as the external data, if we wish
to simulate the operating characteristics of using previously collected
data. This is done by setting the external_data
argument in
create_data_simulation
to a data frame. This data is
included after enrollment, cut-off and dropout functions are applied, so
these have no effect on the fixed data.
It is possible to include a fixed external dataset and additionally
simulate external patients by setting n_ctrl_ext
to a
non-zero value. This will simulate external patients in addition to the
fixed data.
historical_trial_data <- data.frame(
age = rnorm(40, 60, 5),
score_high = rbinom(40, 1, 0.7),
trt = 0,
eventtime = rexp(40, 1 / 50),
status = 1,
enrollment = 1 # enrollment is specified here but not used in clinical cut off
)
my_internal_baseline <- create_baseline_object(
n_trt_int = 100,
n_ctrl_int = 50,
n_ctrl_ext = 0,
covariates = baseline_covariates(
names = c("age", "score"),
means_int = c(55, 5),
means_ext = c(60, 5),
covariance_int = covariance_matrix(diag = c(5, 1)),
covariance_ext = covariance_matrix(diag = c(5, 1.2), upper_tri = c(0.1))
),
transformations = list(score_high = binary_cutoff("score", int_cutoff = 0.7, ext_cutoff = 0.7))
)
my_data_sim_setup_with_fixed <- create_data_simulation(
baseline = my_internal_baseline,
coefficients = c(age = 0.001, score_high = 1.1),
event_dist = create_event_dist(dist = "exponential", lambdas = 1 / 50),
fixed_external_data = historical_trial_data
) %>%
set_enrollment(
internal = enrollment_constant(rate = c(25, 10), for_time = c(4, 30)),
external = enrollment_constant(rate = c(30, 10), for_time = c(4, 30))
) %>%
set_dropout(
internal_treated = create_event_dist(dist = "exponential", lambdas = 1 / 50),
internal_control = create_event_dist(dist = "exponential", lambdas = 1 / 55),
external_control = create_event_dist(dist = "exponential", lambdas = 1 / 40)
) %>%
set_cut_off(
internal = cut_off_after_first(time = 60),
external = cut_off_after_events(n = 100)
)
my_data_sim_setup_with_fixed
#> DataSimObject
#> -------------
#> Baseline object:
#> Baseline Data Simulation Object
#> N internal treated: 100
#> N internal control: 50
#> N external control: 0
#>
#> Covariates:
#> [[1]]
#> covariate means_internal means_external
#> age 55 60
#> score 5 5
#>
#> Covariance Matrices
#> Internal External
#> age score age score
#> age 5 0 age 5.0 0.1
#> score 0 1 score 0.1 1.2
#>
#> Transformations:
#> score_high
#>
#> Event distribution:
#> exponential distribution with lambda = 0.02
#>
#> Treatment HR: 1
#> Drift HR: 1
#>
#> Coefficients:
#> age score_high
#> 0.001 1.100
#>
#> Enrollment:
#> Internal: Enrolling patients per time at rates: 25, 25, 25, 25, 10, 10, 10, 10, 10, 10, 10, 10....
#> External: Enrolling patients per time at rates: 30, 30, 30, 30, 10, 10, 10, 10, 10, 10, 10, 10....
#>
#> Dropout:
#> Internal treated: exponential distribution with lambda = 0.02
#> Internal control: exponential distribution with lambda = 0.0181818181818182
#> External control: exponential distribution with lambda = 0.025
#>
#> Clinical cut off:
#> Internal: Cut off after first enrolled patient reaches time = 60
#> External: Cut off after 100 events
#>
#> Fixed external data:
#> Columns: age, score_high, trt, eventtime, status, enrollment, ext
#> N: 40
# Drift is not be used for the fixed external data!
generate(my_data_sim_setup_with_fixed, n = 1, treatment_hr = c(1, 1.3), drift_hr = c(1, 1.2))
#> Warning: Drift parameter is not applied to fixed external data
#> SimDataList object with 4 different scenarios
#> sim_id treatment_hr drift_hr n_datasets_per_param
#> 1 1 1.0 1.0 1
#> 2 2 1.3 1.0 1
#> 3 3 1.0 1.2 1
#> 4 4 1.3 1.2 1
external_data_list <- generate(my_data_sim_setup_with_fixed, n = 3, treatment_hr = c(1, 1.3), drift_hr = c(1))
Simulation data objects can be combined so that a simulation can be run once.
combined_data_list <- c(my_data_list, external_data_list)
combined_data_list
#> SimDataList object with 6 different scenarios
#> sim_id treatment_hr drift_hr n_datasets_per_param
#> 1 1 1.0 1.0 3
#> 2 2 1.3 1.0 3
#> 3 3 1.0 1.2 3
#> 4 4 1.3 1.2 3
#> 5 5 1.0 1.0 3
#> [ reached 'max' / getOption("max.print") -- omitted 1 rows ]
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They may not be fully stable and should be used with caution. We make no claims about them.
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