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505 lines
19 KiB
R
505 lines
19 KiB
R
# ==================================================================== #
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# TITLE #
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# Antimicrobial Resistance (AMR) Analysis #
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# #
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# AUTHORS #
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# Berends MS (m.s.berends@umcg.nl), Luz CF (c.f.luz@umcg.nl) #
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# #
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# LICENCE #
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# This program is free software; you can redistribute it and/or modify #
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# it under the terms of the GNU General Public License version 2.0, #
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# as published by the Free Software Foundation. #
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# #
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# This program is distributed in the hope that it will be useful, #
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# but WITHOUT ANY WARRANTY; without even the implied warranty of #
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the #
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# GNU General Public License for more details. #
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# ==================================================================== #
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#' Determine first (weighted) isolates
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#'
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#' Determine first (weighted) isolates of all microorganisms of every patient per episode and (if needed) per specimen type.
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#' @param tbl a \code{data.frame} containing isolates.
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#' @param col_date column name of the result date (or date that is was received on the lab)
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#' @param col_patient_id column name of the unique IDs of the patients
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#' @param col_genus column name of the genus of the microorganisms
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#' @param col_species column name of the species of the microorganisms
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#' @param col_testcode column name of the test codes. Use \code{col_testcode = NA} to \strong{not} exclude certain test codes (like test codes for screening). In that case \code{testcodes_exclude} will be ignored.
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#' @param col_specimen column name of the specimen type or group
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#' @param col_icu column name of the logicals (\code{TRUE}/\code{FALSE}) whether a ward or department is an Intensive Care Unit (ICU)
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#' @param col_keyantibiotics column name of the key antibiotics to determine first \emph{weighted} isolates, see \code{\link{key_antibiotics}}.
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#' @param episode_days episode in days after which a genus/species combination will be determined as 'first isolate' again
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#' @param testcodes_exclude character vector with test codes that should be excluded (caseINsensitive)
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#' @param icu_exclude logical whether ICU isolates should be excluded
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#' @param filter_specimen specimen group or type that should be excluded
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#' @param output_logical return output as \code{logical} (will else the values \code{0} or \code{1})
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#' @param points_threshold points until the comparison of key antibiotics will lead to inclusion of an isolate, see Details
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#' @param info print progress
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#' @details \strong{Why this is so important} \cr
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#' To conduct an analysis of antimicrobial resistance, you should only include the first isolate of every patient per episode \href{https://www.ncbi.nlm.nih.gov/pubmed/17304462}{[1]}. If you would not do this, you could easily get an overestimate or underestimate of the resistance of an antibiotic. Imagine that a patient was admitted with an MRSA and that it was found in 5 different blood cultures the following week. The resistance percentage of oxacillin of all \emph{S. aureus} isolates would be overestimated, because you included this MRSA more than once. It would be \href{https://en.wikipedia.org/wiki/Selection_bias}{selection bias}.
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#'
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#' \strong{Using parameter \code{points_threshold}} \cr
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#' To compare key antibiotics, the difference between antimicrobial interpretations will be measured. A difference from I to S|R (or vice versa) means 0.5 points. A difference from S to R (or vice versa) means 1 point. When the sum of points exceeds \code{points_threshold}, an isolate will be (re)selected as a first weighted isolate.
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#' @keywords isolate isolates first
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#' @export
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#' @importFrom dplyr arrange_at lag between row_number filter mutate arrange
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#' @return A vector to add to table, see Examples.
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#' @examples
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#' \dontrun{
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#'
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#' # set key antibiotics to a new variable
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#' tbl$keyab <- key_antibiotics(tbl)
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#'
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#' tbl$first_isolate <-
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#' first_isolate(tbl)
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#'
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#' tbl$first_isolate_weighed <-
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#' first_isolate(tbl,
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#' col_keyantibiotics = 'keyab')
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#'
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#' tbl$first_blood_isolate <-
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#' first_isolate(tbl,
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#' filter_specimen = 'Blood')
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#'
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#' tbl$first_blood_isolate_weighed <-
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#' first_isolate(tbl,
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#' filter_specimen = 'Blood',
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#' col_keyantibiotics = 'keyab')
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#'
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#' tbl$first_urine_isolate <-
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#' first_isolate(tbl,
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#' filter_specimen = 'Urine')
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#'
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#' tbl$first_urine_isolate_weighed <-
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#' first_isolate(tbl,
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#' filter_specimen = 'Urine',
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#' col_keyantibiotics = 'keyab')
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#'
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#' tbl$first_resp_isolate <-
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#' first_isolate(tbl,
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#' filter_specimen = 'Respiratory')
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#'
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#' tbl$first_resp_isolate_weighed <-
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#' first_isolate(tbl,
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#' filter_specimen = 'Respiratory',
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#' col_keyantibiotics = 'keyab')
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#' }
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first_isolate <- function(tbl,
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col_date,
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col_patient_id,
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col_genus,
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col_species,
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col_testcode = NA,
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col_specimen,
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col_icu,
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col_keyantibiotics = NA,
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episode_days = 365,
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testcodes_exclude = '',
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icu_exclude = FALSE,
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filter_specimen = NA,
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output_logical = TRUE,
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points_threshold = 2,
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info = TRUE) {
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# controleren of kolommen wel bestaan
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check_columns_existance <- function(column, tblname = tbl) {
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if (NROW(tblname) <= 1 | NCOL(tblname) <= 1) {
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stop('Please check tbl for existance.')
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}
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if (!is.na(column)) {
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if (!(column %in% colnames(tblname))) {
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stop('Column ', column, ' not found.')
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}
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}
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}
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check_columns_existance(col_date)
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check_columns_existance(col_patient_id)
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check_columns_existance(col_genus)
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check_columns_existance(col_species)
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check_columns_existance(col_testcode)
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check_columns_existance(col_icu)
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check_columns_existance(col_keyantibiotics)
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if (is.na(col_testcode)) {
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testcodes_exclude <- NA
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}
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# testcodes verwijderen die ingevuld zijn
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if (!is.na(testcodes_exclude[1]) & testcodes_exclude[1] != '' & info == TRUE) {
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cat('Isolates from these test codes will be ignored:\n', toString(testcodes_exclude), '\n')
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}
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if (is.na(col_icu)) {
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icu_exclude <- FALSE
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} else {
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tbl <- tbl %>%
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mutate(col_icu = tbl %>% pull(col_icu) %>% as.logical())
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}
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specgroup.notice <- ''
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weighted.notice <- ''
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# filteren op materiaalgroep en sleutelantibiotica gebruiken wanneer deze ingevuld zijn
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if (!is.na(filter_specimen) & filter_specimen != '') {
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check_columns_existance(col_specimen, tbl)
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if (info == TRUE) {
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cat('Isolates other than of specimen group \'', filter_specimen, '\' will be ignored. ', sep = '')
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}
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} else {
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filter_specimen <- ''
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}
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if (col_keyantibiotics %in% c(NA, '')) {
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col_keyantibiotics <- ''
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} else {
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tbl <- tbl %>% mutate(key_ab = tbl %>% pull(col_keyantibiotics))
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}
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if (is.na(testcodes_exclude[1])) {
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testcodes_exclude <- ''
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}
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# nieuwe dataframe maken met de oorspronkelijke rij-index, 0-bepaling en juiste sortering
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#cat('Sorting table...')
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tbl <- tbl %>%
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mutate(first_isolate_row_index = 1:nrow(tbl),
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eersteisolaatbepaling = 0,
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date_lab = tbl %>% pull(col_date),
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patient_id = tbl %>% pull(col_patient_id),
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species = tbl %>% pull(col_species),
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genus = tbl %>% pull(col_genus)) %>%
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mutate(species = if_else(is.na(species), '', species),
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genus = if_else(is.na(genus), '', genus))
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if (filter_specimen == '') {
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if (icu_exclude == FALSE) {
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if (info == TRUE) {
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cat('Isolates from ICU will *NOT* be ignored.\n')
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}
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tbl <- tbl %>%
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arrange_at(c(col_patient_id,
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col_genus,
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col_species,
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col_date))
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row.start <- 1
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row.end <- nrow(tbl)
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} else {
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if (info == TRUE) {
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cat('Isolates from ICU will be ignored.\n')
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}
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tbl <- tbl %>%
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arrange_at(c(col_icu,
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col_patient_id,
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col_genus,
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col_species,
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col_date))
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suppressWarnings(
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row.start <- which(tbl %>% pull(col_icu) == FALSE) %>% min(na.rm = TRUE)
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)
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suppressWarnings(
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row.end <- which(tbl %>% pull(col_icu) == FALSE) %>% max(na.rm = TRUE)
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)
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}
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} else {
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# sorteren op materiaal en alleen die rijen analyseren om tijd te besparen
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if (icu_exclude == FALSE) {
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if (info == TRUE) {
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cat('Isolates from ICU will *NOT* be ignored.\n')
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}
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tbl <- tbl %>%
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arrange_at(c(col_specimen,
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col_patient_id,
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col_genus,
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col_species,
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col_date))
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suppressWarnings(
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row.start <- which(tbl %>% pull(col_specimen) == filter_specimen) %>% min(na.rm = TRUE)
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)
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suppressWarnings(
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row.end <- which(tbl %>% pull(col_specimen) == filter_specimen) %>% max(na.rm = TRUE)
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)
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} else {
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if (info == TRUE) {
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cat('Isolates from ICU will be ignored.\n')
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}
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tbl <- tbl %>%
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arrange_at(c(col_icu,
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col_specimen,
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col_patient_id,
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col_genus,
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col_species,
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col_date))
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suppressWarnings(
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row.start <- which(tbl %>% pull(col_specimen) == filter_specimen
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& tbl %>% pull(col_icu) == FALSE) %>% min(na.rm = TRUE)
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)
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suppressWarnings(
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row.end <- which(tbl %>% pull(col_specimen) == filter_specimen
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& tbl %>% pull(col_icu) == FALSE) %>% max(na.rm = TRUE)
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)
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}
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}
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if (abs(row.start) == Inf | abs(row.end) == Inf) {
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if (info == TRUE) {
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cat('No isolates found.\n')
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}
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# NA's maken waar genus niet beschikbaar is
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tbl <- tbl %>%
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mutate(real_first_isolate = if_else(genus == '', NA, FALSE))
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if (output_logical == FALSE) {
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tbl$real_first_isolate <- tbl %>% pull(real_first_isolate) %>% as.integer()
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}
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return(tbl %>% pull(real_first_isolate))
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}
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scope.size <- tbl %>%
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filter(row_number() %>%
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between(row.start,
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row.end),
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genus != '') %>%
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nrow()
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# Analyse van eerste isolaat ----
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all_first <- tbl %>%
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mutate(other_pat_or_mo = if_else(patient_id == lag(patient_id)
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& genus == lag(genus)
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& species == lag(species),
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FALSE,
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TRUE),
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days_diff = 0) %>%
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mutate(days_diff = if_else(other_pat_or_mo == FALSE,
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(date_lab - lag(date_lab)) + lag(days_diff),
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0))
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if (col_keyantibiotics != '') {
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if (info == TRUE) {
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cat(paste0('Comparing key antibiotics for first weighted isolates (using points threshold of '
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, points_threshold, ')...\n'))
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}
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all_first <- all_first %>%
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mutate(key_ab_lag = lag(key_ab)) %>%
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mutate(key_ab_other = !key_antibiotics_equal(x = key_ab,
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y = key_ab_lag,
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points_threshold = points_threshold,
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info = info)) %>%
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mutate(
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real_first_isolate =
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if_else(
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between(row_number(), row.start, row.end)
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& genus != ''
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& (other_pat_or_mo
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| days_diff >= episode_days
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| key_ab_other),
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TRUE,
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FALSE))
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if (info == TRUE) {
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cat('\n')
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}
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} else {
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all_first <- all_first %>%
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mutate(
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real_first_isolate =
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if_else(
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between(row_number(), row.start, row.end)
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& genus != ''
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& (other_pat_or_mo
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| days_diff >= episode_days),
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TRUE,
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FALSE))
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}
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# allereerst isolaat als TRUE
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all_first[row.start, 'real_first_isolate'] <- TRUE
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# geen testen die uitgesloten moeten worden, of ICU
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if (!is.na(col_testcode)) {
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all_first[which(all_first[, col_testcode] %in% tolower(testcodes_exclude)), 'real_first_isolate'] <- FALSE
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}
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if (icu_exclude == TRUE) {
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all_first[which(all_first[, col_icu] == TRUE), 'real_first_isolate'] <- FALSE
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}
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# NA's maken waar genus niet beschikbaar is
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all_first <- all_first %>%
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mutate(real_first_isolate = if_else(genus == '', NA, real_first_isolate))
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all_first <- all_first %>%
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arrange(first_isolate_row_index) %>%
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pull(real_first_isolate)
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if (info == TRUE) {
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cat(paste0('\nFound ',
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all_first %>% sum(na.rm = TRUE),
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' first ', weighted.notice, 'isolates (',
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(all_first %>% sum(na.rm = TRUE) / scope.size) %>% percent(),
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' of isolates in scope [where genus was not empty] and ',
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(all_first %>% sum(na.rm = TRUE) / tbl %>% nrow()) %>% percent(),
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' of total)\n'))
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}
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if (output_logical == FALSE) {
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all_first <- all_first %>% as.integer()
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}
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all_first
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}
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#' Key antibiotics based on bacteria ID
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#'
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#' @param tbl table with antibiotics coloms, like \code{amox} and \code{amcl}.
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#' @param col_bactcode column of bacteria IDs in \code{tbl}; these should occur in \code{bactlist$bactid}, see \code{\link{bactlist}}
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#' @param info print warnings
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#' @param amcl,amox,cfot,cfta,cftr,cfur,cipr,clar,clin,clox,doxy,gent,line,mero,peni,pita,rifa,teic,trsu,vanc column names of antibiotics.
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#' @export
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#' @importFrom dplyr %>% mutate if_else
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#' @return Character of length 1.
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#' @seealso \code{\link{mo_property}} \code{\link{ablist}}
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#' @examples
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#' \donttest{
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#' #' # set key antibiotics to a new variable
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#' tbl$keyab <- key_antibiotics(tbl)
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#' }
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key_antibiotics <- function(tbl,
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col_bactcode = 'bactid',
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info = TRUE,
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amcl = 'amcl',
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amox = 'amox',
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cfot = 'cfot',
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cfta = 'cfta',
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cftr = 'cftr',
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cfur = 'cfur',
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cipr = 'cipr',
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clar = 'clar',
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clin = 'clin',
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clox = 'clox',
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doxy = 'doxy',
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gent = 'gent',
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line = 'line',
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mero = 'mero',
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peni = 'peni',
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pita = 'pita',
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rifa = 'rifa',
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teic = 'teic',
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trsu = 'trsu',
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vanc = 'vanc') {
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keylist <- character(length = nrow(tbl))
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# check columns
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col.list <- c(amox, cfot, cfta, cftr, cfur, cipr, clar,
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clin, clox, doxy, gent, line, mero, peni,
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pita, rifa, teic, trsu, vanc)
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col.list <- col.list[!is.na(col.list)]
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if (!all(col.list %in% colnames(tbl))) {
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if (info == TRUE) {
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warning('These columns do not exist and will be ignored:\n',
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col.list[!(col.list %in% colnames(tbl))] %>% toString(),
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immediate. = TRUE,
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call. = FALSE)
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}
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}
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# bactlist aan vastknopen
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tbl <- tbl %>% left_join_bactlist(col_bactcode)
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tbl$key_ab <- NA_character_
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# Staphylococcus
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list_ab <- c(clox, trsu, teic, vanc, doxy, line, clar, rifa)
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list_ab <- list_ab[list_ab %in% colnames(tbl)]
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tbl <- tbl %>% mutate(key_ab =
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if_else(genus == 'Staphylococcus',
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apply(X = tbl[, list_ab],
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MARGIN = 1,
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FUN = function(x) paste(x, collapse = "")),
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key_ab))
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# Rest of Gram +
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list_ab <- c(peni, amox, teic, vanc, clin, line, clar, trsu)
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list_ab <- list_ab[list_ab %in% colnames(tbl)]
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tbl <- tbl %>% mutate(key_ab =
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if_else(gramstain %like% '^Positi[e]?ve',
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apply(X = tbl[, list_ab],
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MARGIN = 1,
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FUN = function(x) paste(x, collapse = "")),
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key_ab))
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# Gram -
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list_ab <- c(amox, amcl, pita, cfur, cfot, cfta, cftr, mero, cipr, trsu, gent)
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list_ab <- list_ab[list_ab %in% colnames(tbl)]
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tbl <- tbl %>% mutate(key_ab =
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if_else(gramstain %like% '^Negati[e]?ve',
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apply(X = tbl[, list_ab],
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MARGIN = 1,
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FUN = function(x) paste(x, collapse = "")),
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key_ab))
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# format
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tbl <- tbl %>%
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mutate(key_ab = gsub('(NA|NULL)', '-', key_ab) %>% toupper())
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tbl$key_ab
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}
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#' @importFrom dplyr progress_estimated %>%
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#' @noRd
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key_antibiotics_equal <- function(x, y, points_threshold = 2, info = FALSE) {
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# x is active row, y is lag
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if (length(x) != length(y)) {
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stop('Length of `x` and `y` must be equal.')
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}
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result <- logical(length(x))
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if (info == TRUE) {
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p <- dplyr::progress_estimated(length(x))
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}
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for (i in 1:length(x)) {
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if (info == TRUE) {
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p$tick()$print()
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}
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if (is.na(x[i])) {
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x[i] <- ''
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|
}
|
|
if (is.na(y[i])) {
|
|
y[i] <- ''
|
|
}
|
|
|
|
if (nchar(x[i]) != nchar(y[i])) {
|
|
|
|
result[i] <- FALSE
|
|
|
|
} else if (x[i] == '' & y[i] == '') {
|
|
|
|
result[i] <- TRUE
|
|
|
|
} else {
|
|
|
|
# count points for every single character:
|
|
# - no change is 0 points
|
|
# - I <-> S|R is 0.5 point
|
|
# - S|R <-> R|S is 1 point
|
|
# use the levels of as.rsi (S = 1, I = 2, R = 3)
|
|
|
|
x2 <- strsplit(x[i], "")[[1]] %>% as.rsi() %>% as.double()
|
|
y2 <- strsplit(y[i], "")[[1]] %>% as.rsi() %>% as.double()
|
|
|
|
points <- (x2 - y2) %>% abs() %>% sum(na.rm = TRUE)
|
|
result[i] <- ((points / 2) >= points_threshold)
|
|
}
|
|
}
|
|
if (info == TRUE) {
|
|
cat('\n')
|
|
}
|
|
result
|
|
}
|