---
title: "Generic Derivations"
output:
rmarkdown::html_vignette
vignette: >
%\VignetteIndexEntry{Generic Derivations}
%\VignetteEngine{knitr::rmarkdown}
%\VignetteEncoding{UTF-8}
---
```{r setup, include = FALSE}
knitr::opts_chunk$set(
collapse = TRUE,
comment = "#>"
)
library(admiraldev)
```
# Introduction
This vignette provides an overview of the most important admiral functions, the
generic derivations. They do not derive a specific variable or parameter in a
specific dataset but can be used for many different derivations in many
different datasets. The most important concepts and some examples are presented
here. For full details and more examples see the documentation of the functions.
## Required Packages
The examples in this vignette require the following packages.
```{r, warning=FALSE, message=FALSE}
library(admiral)
library(tibble)
```
# Characterization of Derivations
The generic functions can be characterized by the following three properties:
- What should be added? There are two options:
- _Variables_
- _Records/Parameters_
- What is the source data? There are two options:
- A _single_ source dataset
- _Multiple_ source datasets
- Which method should be used? There are three options:
- _Selection_: The new values are derived by selecting records, e.g., the
baseline records, the last exposure record, ...
- _Summary_: The new values are derived by summarizing values, e.g., sum,
average, concatenation, ...
- _Computation_: The new values are derived by a computation with more than
one value as input, e.g., deriving BMI or BSA from height and weight
## Overview of Derivations
Using the three properties makes it easy to find the appropriate function for a
particular derivation. The following interactive table lists all generic
functions and their properties.
```{r, echo=FALSE}
library(reactable)
generic_derivations <- tibble::tribble(
~Derivation, ~Method, ~What, ~Source,
"derive_var_extreme_flag()", "selection", "variables", "single",
"derive_var_joined_exist_flag()", "selection", "variables", "single",
"derive_var_merged_ef_msrc()", "selection", "variables", "multiple",
"derive_var_merged_exist_flag()", "selection", "variables", "single",
"derive_vars_merged_summary()", "summary", "variables", "single",
"derive_vars_joined()", "selection", "variables", "single",
"derive_vars_merged()", "selection", "variables", "single",
"derive_vars_extreme_event()", "selection", "variables", "multiple",
"derive_vars_computed()", "computation", "variables", "single",
"derive_extreme_event()", "selection", "records", "multiple",
"derive_extreme_records()", "selection", "records", "single",
"derive_param_computed()", "computation", "records", "single",
"derive_param_exist_flag()", "selection", "records", "single",
"derive_summary_records()", "summary", "records", "single"
) %>% dplyr::select(Derivation, What, Source, Method)
reactable(
generic_derivations,
columns = list(
Derivation = colDef(
minWidth = 200,
cell = function(value, index) {
# Render as a link
url <- paste0(
"../reference/",
substr(value, 1, nchar(value) - 2),
".html"
)
htmltools::tags$a(href = url, as.character(value))
}
)
),
defaultSorted = list("What" = "desc", "Source" = "desc", "Method" = "asc"),
filterable = TRUE,
resizable = TRUE,
defaultPageSize = 20
)
```
# Source Data
Most derivation functions expect a single source dataset. For some multiple
source datasets can be specified. In both cases the way how to specify the
source datasets is the same across all generic functions.
## Single Source Dataset
For functions expecting a single source dataset the data is provided by the
`dataset_add` argument. This is a mandatory argument. The data provided by the
`dataset` argument is not used[^1].
[^1]: `derive_param_computed()` is an exception. It uses the data from both
arguments.
If the `dataset_add` argument is not provided, the data from `dataset` is used
(`derive_var_extreme_flag()`).
## Multiple Source Datasets
For functions expecting multiple source datasets the data is provided by the
`source_datasets` argument. The datasets are referred to by the `dataset_name`
element of the source objects.
For example, consider the derivation of a response parameter. The three possible
responses are defined by `event()` objects. These objects define the events but
do not include any data. Instead the `dataset_name` field is set to a
(character) id. This id is used in the `source_datasets` argument of the
derivation function to link the data to the events. I.e., for the first two
events (`complete_response` and `partial_response`) the dataset `adrs_ovr` is
used while for the last event the dataset `myadsl` is used.
```
complete_response <- event(
description = "Define complete response",
dataset_name = "ovr",
condition = AVALC == "CR",
set_values_to = exprs(AVALC = "COMPLETE RESPONSE")
)
partial_response <- event(
description = "Define partial response",
dataset_name = "ovr",
condition = AVALC == "PR",
set_values_to = exprs(AVALC = "PARTIAL RESPONSE")
)
no_response <- event(
description = "Define no response for all patients in adsl",
dataset_name = "adsl",
condition = TRUE,
set_values_to = exprs(AVALC = "NO RESPONSE")
)
derive_extreme_event(
...
events = list(complete_response, partial_response, no_response),
source_datasets = list(ovr = adrs_ovr, adsl = myadsl),
...
)
```
This allows to define the source objects independent of the data. I.e., the same
source object can be used for different source datasets. For example, the
parameter above could be derived for data from a second reporter by just
changing `source_dataset`:
```
derive_extreme_event(
...
events = list(complete_response, partial_response, no_response),
source_datasets = list(ovr = adrs_ovr_reporter2, adsl = myadsl),
...
)
```
For some source objects the `dataset_name` element is optional, e.g., `event()`.
If it is not specified, the input dataset (`dataset`) is used.
# Methods
The generic derivations use three different methods for deriving the values of
the new variables or records. Usually the derivation applies the method several
times, once for each group in the input or source data. The groups are defined
by the `by_vars` argument, e.g., `by_vars = exprs(USUBJID)` for "each subject"
or `by_vars = exprs(USUBJID, PARAMCD)` for "each subject and parameter".
## Selection
The most common method is the selection method. It selects a record from the
source dataset(s) and adds information from the selected record to the input
dataset. This information could be just a flag indicating that a record exists,
one or more variables from the selected records, or new variables created from
the selected record.
### Options for Selection
In the simplest case the record is selected by a condition. The condition is
specified by the `filter_add` or `filter` argument. In the following example
baseline weight is added to `ADSL`.
```{r}
adsl <- tribble(
~USUBJID,
"1",
"2",
"3"
)
advs <- tribble(
~USUBJID, ~PARAMCD, ~AVISIT, ~ABLFL, ~AVAL, ~AVALU,
"1", "WEIGHT", "BASELINE", "Y", 58.7, "kg",
"1", "HEIGHT", "BASELINE", "Y", 169.2, "cm",
"1", "WEIGHT", "WEEK 3", NA, 59.3, "kg",
"2", "WEIGHT", "BASELINE", "Y", 72.5, "kg",
"2", "WEIGHT", "WEKK 3", NA, 71.9, "kg",
)
derive_vars_merged(
adsl,
dataset_add = advs,
by_vars = exprs(USUBJID),
filter_add = PARAMCD == "WEIGHT" & ABLFL == "Y",
new_vars = exprs(WGTBL = AVAL)
)
```
Sometimes it is not possible to select the record of interest by a condition,
e.g., if the first, last, best, worst, lowest, highest, ... value should be
derived. In this case the `mode` and `order` argument can be specified to select
the first or last record with respect to the variables specified for `order`.
Below the day of the last valid dose is added to `ADSL`.
```{r}
adsl <- tribble(
~USUBJID,
"1",
"2",
"3"
)
ex <- tribble(
~USUBJID, ~EXSTDY, ~EXDOSE,
"1", 1, 50,
"1", 7, 70,
"1", 14, 0,
"2", 1, 75,
"2", 9, 70
)
derive_vars_merged(
adsl,
dataset_add = ex,
by_vars = exprs(USUBJID),
filter_add = EXDOSE > 0,
order = exprs(EXSTDY),
mode = "last",
new_vars = exprs(TRTEDY = EXSTDY)
)
```
It is also possible to select the record based on records of the input _and_ the
source dataset. For this type of selection `{admiral}` provides the functions
`derive_vars_joined()`, `derive_var_joined_exist_flag()`, and
`derive_extreme_event()`. They provide the `filter_join` argument which accepts
conditions with variables from both the input dataset (`dataset`) and the
additional dataset (`dataset_add`). As an example consider deriving the day and
dose of the last study treatment before an adverse event:
```{r}
adae <- tribble(
~USUBJID, ~ASTDY, ~AESEQ,
"1", 3, 1,
"1", 3, 2,
"1", 15, 3
)
ex <- tribble(
~USUBJID, ~EXSTDY, ~EXDOSE,
"1", 1, 50,
"1", 7, 70,
"1", 14, 0,
"2", 1, 75,
"2", 9, 70
)
derive_vars_joined(
adae,
dataset_add = ex,
by_vars = exprs(USUBJID),
filter_add = EXDOSE > 0,
filter_join = EXSTDY <= ASTDY,
join_type = "all",
order = exprs(EXSTDY),
mode = "last",
new_vars = exprs(LSTDOSDY = EXSTDY, LASTDOS = EXDOSE)
)
```
The `filter_join` condition is applied on a temporary dataset created by left joining the input dataset and the additional dataset (restricted by `filter_add`):
```{r, echo=FALSE}
admiral:::get_joined_data(
adae,
dataset_add = ex,
by_vars = exprs(USUBJID),
filter_add = EXDOSE > 0,
join_vars = exprs(EXDOSE),
join_type = "all",
order = exprs(EXSTDY)
)
```
The "joined" function can also be used when the condition for selecting depends
on previous or subsequent records in the dataset. In this case the same dataset
is specified for `dataset` and `dataest_add`. Consider the following example
where `"HIGH"` results should be flagged which are confirmed by a second
`"HIGH"` result at least ten days later.
```{r}
adlb <- tribble(
~USUBJID, ~PARAMCD, ~ADY, ~ANRIND,
"1", "AST", 1, "HIGH",
"1", "AST", 7, "HIGH",
"1", "AST", 14, "NORMAL",
"1", "ALT", 1, "HIGH",
"1", "ALT", 7, "NORMAL",
"1", "ALT", 14, "HIGH",
"2", "AST", 1, "HIGH",
"2", "AST", 15, "HIGH",
"2", "AST", 22, "NORMAL",
"2", "ALT", 1, "HIGH"
)
derive_var_joined_exist_flag(
adlb,
dataset_add = adlb,
by_vars = exprs(USUBJID, PARAMCD),
order = exprs(ADY),
join_vars = exprs(ADY, ANRIND),
join_type = "after",
filter_join = ANRIND == "HIGH" & ANRIND.join == "HIGH" & ADY.join > ADY + 10,
new_var = HICONFFL
)
```
The `join_type` argument is set to `"after"` to restrict the joined records to
subsequent results.
As the same variables are included in `dataset` and `dataset_add`, those from
`dataset_add` are renamed by adding the suffix ".join". The variables from
`dataset_add` which are used in `filter_join` must be specified for `join_vars`.
So the temporary dataset for applying `filter_join` is:
```{r, echo=FALSE}
admiral:::get_joined_data(
adlb,
dataset_add = adlb,
by_vars = exprs(USUBJID, PARAMCD),
order = exprs(ADY),
join_vars = exprs(ADY, ANRIND),
join_type = "after"
)
```
It is possible to use summary functions like `all()` or `any()` in
`filter_join`. Assume that in the previous example records should be flagged
only if all results between the flagged record and the confirmation record were
`"HIGH"`. This can be achieved by specifying the `first_cond_upper` argument and
set it to the condition for confirmation.
```{r}
derive_var_joined_exist_flag(
adlb,
dataset_add = adlb,
by_vars = exprs(USUBJID, PARAMCD),
order = exprs(ADY),
join_vars = exprs(ADY, ANRIND),
join_type = "after",
first_cond_upper = ANRIND.join == "HIGH" & ADY.join > ADY + 10,
filter_join = ANRIND == "HIGH" & all(ANRIND.join == "HIGH"),
new_var = HICONFFL
)
```
If the `first_cond_upper` argument is specified the records in the joined
dataset are restricted up to the first records where the condition is fulfilled:
```{r, echo=FALSE}
admiral:::get_joined_data(
adlb,
dataset_add = adlb,
by_vars = exprs(USUBJID, PARAMCD),
order = exprs(ADY),
join_vars = exprs(ADY, ANRIND),
join_type = "after",
first_cond_upper = ANRIND.join == "HIGH" & ADY.join > ADY + 10
)
```
Thereafter `filter_join` is applied to the restricted joined dataset. I.e., the
`all()` function considers only the results up to the confirmation records and
ignores subsequent results.
**Note:** In principle, we actually could achieve every result from
`derive_vars_merged()` and `derive_var_merged_exist_flag()` by using
`derive_vars_joined()` or `derive_var_joined_exist_flag()` respectively.
However, the "joined" functions require much more resources (time and memory),
hence it is recommended to use them only if it is really required, i.e., the
condition for selecting records depends on variables from _both_ datasets.
### Sort Order {#sort_order}
The `{admiral}` functions use `dplyr::arrange()` for sorting, i.e., `NA`s are
always sorted to the end (regardless whether `desc()` is used or not).
Consider for example the following derivation of a last visit flag. The record
with `AVISITN == NA` is flagged because `NA` is sorted to the end.
```{r}
advs <- tribble(
~USUBJID, ~PARAMCD, ~AVISITN, ~AVAL,
"1", "WEIGHT", NA, 62.1,
"1", "WEIGHT", 1, 62.3,
"1", "WEIGHT", 2, 62.5,
"1", "WEIGHT", 3, 62.4
)
derive_var_extreme_flag(
advs,
by_vars = exprs(USUBJID, PARAMCD),
order = exprs(AVISITN),
mode = "last",
new_var = LSTVISFL
)
```
The `order` argument accepts expressions. This allows to specify how `NA`s
should be handled. For example, the following sorts the `NA` to the start. Thus
the `AVISITN == 3` record is flagged.
```{r}
derive_var_extreme_flag(
advs,
by_vars = exprs(USUBJID, PARAMCD),
order = exprs(if_else(is.na(AVISITN), -Inf, AVISITN)),
mode = "last",
new_var = LSTVISFL
)
```
The same can achieved with the following, which also works for character
variables.
```{r}
derive_var_extreme_flag(
advs,
by_vars = exprs(USUBJID, PARAMCD),
order = exprs(!is.na(AVISITN), AVISITN),
mode = "last",
new_var = LSTVISFL
)
```
### New Values
How the (new) variables are set depends on whether variables, a flag, or records
are added by the derivation.
- If only a flag needs to be added, the flag functions
(`derive_var_merged_exist_flag()`, `derive_var_joined_exist_flag()`) can be
used. The name of the new variable is specified by the `new_var` argument and
the values of the flag by `true_value` and `false_value`.
- If new variables from the selected record needs to be added, the name of the
new variables and their values are specified by the `new_vars` argument. If in
addition a flag should be added, the `exist_flag` argument and the `true_value`
and `false_value` argument can be used.
- If new records are added, the variables and their values are defined by the
`set_values_to` argument.
## Summary
If the new values should be derived by summarizing values, e.g., sum, average,
concatenation, ..., the functions `derive_summary_records()` or
`derive_var_merged_summary()` can be used. For example, adding an average dose
parameter to `ADEX` can be done by the following:
```{r}
adex <- tribble(
~USUBJID, ~ASTDY, ~AVAL, ~PARAMCD,
"1", 1, 50, "DOSE",
"1", 7, 70, "DOSE",
"1", 14, 0, "DOSE",
"2", 1, 75, "DOSE",
"2", 9, 70, "DOSE"
)
derive_summary_records(
adex,
dataset_add = adex,
filter_add = AVAL > 0,
by_vars = exprs(USUBJID),
set_values_to = exprs(
AVAL = mean(AVAL),
PARAMCD = "AVERAGE DOSE"
)
)
```
The summary function, the source variable, and the new variable can be specified
by the `set_values_to` argument. Variables which are not specified by
`set_values_to` or `by_vars` are set to `NA` for the new records.
If the average dose should be added as a variable to `ADSL`, consider the
following:
```{r}
adsl <- tribble(
~USUBJID,
"1",
"2",
"3"
)
derive_var_merged_summary(
adsl,
dataset_add = adex,
filter_add = AVAL > 0,
by_vars = exprs(USUBJID),
new_vars = exprs(
AVERDOSE = mean(AVAL)
),
missing_values = exprs(AVERDOSE = 0)
)
```
Here the summary function, the source variable, and the new variable are
specified by the `new_vars` argument. For subjects without exposure observations
the value of the new variable can be defined by the `missing_values` argument.
## Computed
If the new values should be computed from different parameters of the source dataset, `derive_param_computed()` can be used. The computed value can be specified by the `set_values_to` argument. The values of the source variable for a parameter can be referred to by temporary variables of the form `<variable name>.<parameter name>`.
```{r}
advs <- tribble(
~USUBJID, ~AVISIT, ~PARAMCD, ~AVAL, ~AVALU,
"1", "BASELINE", "WEIGHT", 32.6, "kg",
"1", "BASELINE", "HEIGHT", 155.4, "cm",
"1", "MONTH 6", "WEIGHT", 33.2, "kg",
"1", "MONTH 6", "HEIGHT", 155.8, "cm",
"2", "BASELINE", "WEIGHT", 44.2, "kg",
"2", "BASELINE", "HEIGHT", 145.3, "cm",
"2", "MONTH 6", "WEIGHT", 42.0, "kg",
"2", "MONTH 6", "HEIGHT", 146.4, "cm"
)
derive_param_computed(
advs,
by_vars = exprs(USUBJID, AVISIT),
parameters = c("WEIGHT", "HEIGHT"),
set_values_to = exprs(
AVAL = AVAL.WEIGHT / (AVAL.HEIGHT / 100)^2,
PARAMCD = "BMI",
AVALU = "kg/m^2"
)
)
```
For common computations like BMI `{admiral}` offers [computation
functions](../reference/#computation-functions-for-vectors). In the previous
example `compute_bmi()` could be used instead of the formula for BMI:
```{r}
derive_param_computed(
advs,
by_vars = exprs(USUBJID, AVISIT),
parameters = c("WEIGHT", "HEIGHT"),
set_values_to = exprs(
AVAL = compute_bmi(weight = AVAL.WEIGHT, height = AVAL.HEIGHT),
PARAMCD = "BMI",
AVALU = "kg/m^2"
)
)
```