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These functions determine which items in a vector can be considered (the start of) a new episode. This can be used to determine clinical episodes for any epidemiological analysis. The get_episode() function returns the index number of the episode per group, while the is_new_episode() function returns TRUE for every new get_episode() index. Both absolute and relative episode determination are supported.

Usage

get_episode(x, episode_days = NULL, case_free_days = NULL, ...)

is_new_episode(x, episode_days = NULL, case_free_days = NULL, ...)

Arguments

x

vector of dates (class Date or POSIXt), will be sorted internally to determine episodes

episode_days

episode length in days to specify the time period after which a new episode begins, can also be less than a day or Inf, see Details

case_free_days

(inter-epidemic) interval length in days after which a new episode will start, can also be less than a day or Inf, see Details

...

ignored, only in place to allow future extensions

Value

Details

Episodes can be determined in two ways: absolute and relative.

  1. Absolute

    This method uses episode_days to define an episode length in days, after which a new episode will start. A common use case in AMR data analysis is microbial epidemiology: episodes of S. aureus bacteraemia in ICU patients for example. The episode length could then be 30 days, so that new S. aureus isolates after an ICU episode of 30 days will be considered a different (or new) episode.

    Thus, this method counts since the start of the previous episode.

  2. Relative

    This method uses case_free_days to quantify the duration of case-free days (the inter-epidemic interval), after which a new episode will start. A common use case is infectious disease epidemiology: episodes of norovirus outbreaks in a hospital for example. The case-free period could then be 14 days, so that new norovirus cases after that time will be considered a different (or new) episode.

    Thus, this methods counts since the last case in the previous episode.

In a table:

DateUsing episode_days = 7Using case_free_days = 7
2023-01-0111
2023-01-0211
2023-01-0511
2023-01-082**1
2023-02-2132***
2023-02-2232
2023-02-2332
2023-02-2432
2023-03-0142

** This marks the start of a new episode, because 8 January 2023 is more than 7 days since the start of the previous episode (1 January 2023).
*** This marks the start of a new episode, because 21 January 2023 is more than 7 days since the last case in the previous episode (8 January 2023).

Either episode_days or case_free_days must be provided in the function.

Difference between get_episode() and is_new_episode()

The get_episode() function returns the index number of the episode, so all cases/patients/isolates in the first episode will have the number 1, all cases/patients/isolates in the second episode will have the number 2, etc.

The is_new_episode() function returns TRUE for every new get_episode() index, and is thus equal to !duplicated(get_episode(...)).

To specify, when setting episode_days = 365 (using method 1 as explained above), this is how the two functions differ:

patientdateget_episode()is_new_episode()
A2019-01-011TRUE
A2019-03-011FALSE
A2021-01-012TRUE
B2008-01-011TRUE
B2008-01-011FALSE
C2020-01-011TRUE

Other

The first_isolate() function is a wrapper around the is_new_episode() function, but is more efficient for data sets containing microorganism codes or names and allows for different isolate selection methods.

The dplyr package is not required for these functions to work, but these episode functions do support variable grouping and work conveniently inside dplyr verbs such as filter(), mutate() and summarise().

See also

Examples

# difference between absolute and relative determination of episodes:
x <- data.frame(dates = as.Date(c(
  "2021-01-01",
  "2021-01-02",
  "2021-01-05",
  "2021-01-08",
  "2021-02-21",
  "2021-02-22",
  "2021-02-23",
  "2021-02-24",
  "2021-03-01",
  "2021-03-01"
)))
x$absolute <- get_episode(x$dates, episode_days = 7)
x$relative <- get_episode(x$dates, case_free_days = 7)
x
#>         dates absolute relative
#> 1  2021-01-01        1        1
#> 2  2021-01-02        1        1
#> 3  2021-01-05        1        1
#> 4  2021-01-08        2        1
#> 5  2021-02-21        3        2
#> 6  2021-02-22        3        2
#> 7  2021-02-23        3        2
#> 8  2021-02-24        3        2
#> 9  2021-03-01        4        2
#> 10 2021-03-01        4        2


# `example_isolates` is a data set available in the AMR package.
# See ?example_isolates
df <- example_isolates[sample(seq_len(2000), size = 100), ]

get_episode(df$date, episode_days = 60) # indices
#>   [1] 13 31 23 24 16 19 43 25 28 28 46 31  8 41 30 34 11 18 39 14  4 22 27 10 49
#>  [26] 22 28 19 34 15  5 36 40  3 21 38  8 43 36 40 37 23  6 20 47  1 25 11 29 45
#>  [51]  5 45  6  1 32 40  7 45  2 46 35 34  6 41 41  2 12 26 48 17 15 20 24 12 31
#>  [76] 18 29 28 26 48 41  5 46 43 34  9  6 14  6 20 15 26  5 33 42 46 45  6 44 23
is_new_episode(df$date, episode_days = 60) # TRUE/FALSE
#>   [1]  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE FALSE  TRUE FALSE
#>  [13]  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE
#>  [25]  TRUE FALSE FALSE FALSE FALSE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE  TRUE
#>  [37] FALSE FALSE FALSE FALSE  TRUE FALSE  TRUE  TRUE  TRUE  TRUE FALSE FALSE
#>  [49]  TRUE  TRUE FALSE FALSE FALSE FALSE  TRUE FALSE  TRUE FALSE  TRUE FALSE
#>  [61]  TRUE FALSE FALSE FALSE FALSE FALSE  TRUE  TRUE  TRUE  TRUE FALSE FALSE
#>  [73] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
#>  [85] FALSE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE  TRUE FALSE
#>  [97] FALSE FALSE  TRUE FALSE

# filter on results from the third 60-day episode only, using base R
df[which(get_episode(df$date, 60) == 3), ]
#> # A tibble: 1 × 46
#>   date       patient   age gender ward  mo           PEN   OXA   FLC   AMX  
#>   <date>     <chr>   <dbl> <chr>  <chr> <mo>         <sir> <sir> <sir> <sir>
#> 1 2002-07-30 218912     76 F      ICU   B_ESCHR_COLI R     NA    NA    NA   
#> # … with 36 more variables: AMC <sir>, AMP <sir>, TZP <sir>, CZO <sir>,
#> #   FEP <sir>, CXM <sir>, FOX <sir>, CTX <sir>, CAZ <sir>, CRO <sir>,
#> #   GEN <sir>, TOB <sir>, AMK <sir>, KAN <sir>, TMP <sir>, SXT <sir>,
#> #   NIT <sir>, FOS <sir>, LNZ <sir>, CIP <sir>, MFX <sir>, VAN <sir>,
#> #   TEC <sir>, TCY <sir>, TGC <sir>, DOX <sir>, ERY <sir>, CLI <sir>,
#> #   AZM <sir>, IPM <sir>, MEM <sir>, MTR <sir>, CHL <sir>, COL <sir>,
#> #   MUP <sir>, RIF <sir>

# the functions also work for less than a day, e.g. to include one per hour:
get_episode(
  c(
    Sys.time(),
    Sys.time() + 60 * 60
  ),
  episode_days = 1 / 24
)
#> [1] 1 2

# \donttest{
if (require("dplyr")) {
  # is_new_episode() can also be used in dplyr verbs to determine patient
  # episodes based on any (combination of) grouping variables:
  df %>%
    mutate(condition = sample(
      x = c("A", "B", "C"),
      size = 100,
      replace = TRUE
    )) %>%
    group_by(patient, condition) %>%
    mutate(new_episode = is_new_episode(date, 365)) %>%
    select(patient, date, condition, new_episode) %>%
    arrange(patient, condition, date)
}
#> # A tibble: 100 × 4
#> # Groups:   patient, condition [98]
#>    patient date       condition new_episode
#>    <chr>   <date>     <chr>     <lgl>      
#>  1 001213  2009-08-03 A         TRUE       
#>  2 001213  2009-08-03 B         TRUE       
#>  3 005088  2017-09-28 A         TRUE       
#>  4 010257  2004-04-03 A         TRUE       
#>  5 035268  2011-05-31 C         TRUE       
#>  6 065187  2003-05-26 B         TRUE       
#>  7 080086  2010-08-08 A         TRUE       
#>  8 083080  2012-04-16 A         TRUE       
#>  9 092034  2006-06-12 B         TRUE       
#> 10 0E2483  2007-08-10 C         TRUE       
#> # … with 90 more rows

if (require("dplyr")) {
  df %>%
    group_by(ward, patient) %>%
    transmute(date,
      patient,
      new_index = get_episode(date, 60),
      new_logical = is_new_episode(date, 60)
    ) %>%
    arrange(patient, ward, date)
}
#> # A tibble: 100 × 5
#> # Groups:   ward, patient [97]
#>    ward     date       patient new_index new_logical
#>    <chr>    <date>     <chr>       <int> <lgl>      
#>  1 Clinical 2009-08-03 001213          1 TRUE       
#>  2 Clinical 2009-08-03 001213          1 FALSE      
#>  3 Clinical 2017-09-28 005088          1 TRUE       
#>  4 Clinical 2004-04-03 010257          1 TRUE       
#>  5 ICU      2011-05-31 035268          1 TRUE       
#>  6 ICU      2003-05-26 065187          1 TRUE       
#>  7 Clinical 2010-08-08 080086          1 TRUE       
#>  8 Clinical 2012-04-16 083080          1 TRUE       
#>  9 ICU      2006-06-12 092034          1 TRUE       
#> 10 ICU      2007-08-10 0E2483          1 TRUE       
#> # … with 90 more rows

if (require("dplyr")) {
  df %>%
    group_by(ward) %>%
    summarise(
      n_patients = n_distinct(patient),
      n_episodes_365 = sum(is_new_episode(date, episode_days = 365)),
      n_episodes_60 = sum(is_new_episode(date, episode_days = 60)),
      n_episodes_30 = sum(is_new_episode(date, episode_days = 30))
    )
}
#> # A tibble: 3 × 5
#>   ward       n_patients n_episodes_365 n_episodes_60 n_episodes_30
#>   <chr>           <int>          <int>         <int>         <int>
#> 1 Clinical           65             13            38            48
#> 2 ICU                30             10            22            25
#> 3 Outpatient          2              2             2             2

# grouping on patients and microorganisms leads to the same
# results as first_isolate() when using 'episode-based':
if (require("dplyr")) {
  x <- df %>%
    filter_first_isolate(
      include_unknown = TRUE,
      method = "episode-based"
    )

  y <- df %>%
    group_by(patient, mo) %>%
    filter(is_new_episode(date, 365)) %>%
    ungroup()

  identical(x, y)
}
#> [1] TRUE

# but is_new_episode() has a lot more flexibility than first_isolate(),
# since you can now group on anything that seems relevant:
if (require("dplyr")) {
  df %>%
    group_by(patient, mo, ward) %>%
    mutate(flag_episode = is_new_episode(date, 365)) %>%
    select(group_vars(.), flag_episode)
}
#> # A tibble: 100 × 4
#> # Groups:   patient, mo, ward [98]
#>    patient mo            ward       flag_episode
#>    <chr>   <mo>          <chr>      <lgl>       
#>  1 F32657  B_CRYNB       ICU        TRUE        
#>  2 A66134  B_STPHY_AURS  Clinical   TRUE        
#>  3 001213  B_PSDMN_AERG  Clinical   TRUE        
#>  4 126334  B_STPHY_CONS  Outpatient TRUE        
#>  5 34B622  B_KLBSL_OXYT  Clinical   TRUE        
#>  6 945BD5  B_ENTRBC_CLOC Clinical   TRUE        
#>  7 5C1947  B_ESCHR_COLI  Clinical   TRUE        
#>  8 284FFF  B_STPHY_EPDR  Clinical   TRUE        
#>  9 662978  B_ESCHR_COLI  Clinical   TRUE        
#> 10 874171  B_ESCHR_COLI  Clinical   TRUE        
#> # … with 90 more rows
# }