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111 lines
6.0 KiB
R
Executable File
111 lines
6.0 KiB
R
Executable File
% Generated by roxygen2: do not edit by hand
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% Please edit documentation in R/mic.R
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\docType{data}
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\name{as.mic}
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\alias{as.mic}
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\alias{mic}
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\alias{NA_mic_}
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\alias{is.mic}
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\title{Transform Input to Minimum Inhibitory Concentrations (MIC)}
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\format{
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An object of class \code{mic} (inherits from \code{ordered}, \code{factor}) of length 1.
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}
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\usage{
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as.mic(x, na.rm = FALSE)
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NA_mic_
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is.mic(x)
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}
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\arguments{
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\item{x}{a \link{character} or \link{numeric} vector}
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\item{na.rm}{a \link{logical} indicating whether missing values should be removed}
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}
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\value{
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Ordered \link{factor} with additional class \code{\link{mic}}, that in mathematical operations acts as decimal numbers. Bare in mind that the outcome of any mathematical operation on MICs will return a \link{numeric} value.
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}
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\description{
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This transforms vectors to a new class \code{\link{mic}}, which treats the input as decimal numbers, while maintaining operators (such as ">=") and only allowing valid MIC values known to the field of (medical) microbiology.
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}
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\details{
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To interpret MIC values as RSI values, use \code{\link[=as.rsi]{as.rsi()}} on MIC values. It supports guidelines from EUCAST and CLSI.
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This class for MIC values is a quite a special data type: formally it is an ordered \link{factor} with valid MIC values as \link{factor} levels (to make sure only valid MIC values are retained), but for any mathematical operation it acts as decimal numbers:\preformatted{x <- random_mic(10)
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x
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#> Class <mic>
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#> [1] 16 1 8 8 64 >=128 0.0625 32 32 16
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is.factor(x)
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#> [1] TRUE
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x[1] * 2
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#> [1] 32
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median(x)
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#> [1] 26
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}
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This makes it possible to maintain operators that often come with MIC values, such ">=" and "<=", even when filtering using \link{numeric} values in data analysis, e.g.:\preformatted{x[x > 4]
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#> Class <mic>
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#> [1] 16 8 8 64 >=128 32 32 16
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df <- data.frame(x, hospital = "A")
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subset(df, x > 4) # or with dplyr: df \%>\% filter(x > 4)
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#> x hospital
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#> 1 16 A
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#> 5 64 A
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#> 6 >=128 A
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#> 8 32 A
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#> 9 32 A
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#> 10 16 A
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}
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The following \link[=groupGeneric]{generic functions} are implemented for the MIC class: \code{!}, \code{!=}, \code{\%\%}, \code{\%/\%}, \code{&}, \code{*}, \code{+}, \code{-}, \code{/}, \code{<}, \code{<=}, \code{==}, \code{>}, \code{>=}, \code{^}, \code{|}, \code{\link[=abs]{abs()}}, \code{\link[=acos]{acos()}}, \code{\link[=acosh]{acosh()}}, \code{\link[=all]{all()}}, \code{\link[=any]{any()}}, \code{\link[=asin]{asin()}}, \code{\link[=asinh]{asinh()}}, \code{\link[=atan]{atan()}}, \code{\link[=atanh]{atanh()}}, \code{\link[=ceiling]{ceiling()}}, \code{\link[=cos]{cos()}}, \code{\link[=cosh]{cosh()}}, \code{\link[=cospi]{cospi()}}, \code{\link[=cummax]{cummax()}}, \code{\link[=cummin]{cummin()}}, \code{\link[=cumprod]{cumprod()}}, \code{\link[=cumsum]{cumsum()}}, \code{\link[=digamma]{digamma()}}, \code{\link[=exp]{exp()}}, \code{\link[=expm1]{expm1()}}, \code{\link[=floor]{floor()}}, \code{\link[=gamma]{gamma()}}, \code{\link[=lgamma]{lgamma()}}, \code{\link[=log]{log()}}, \code{\link[=log1p]{log1p()}}, \code{\link[=log2]{log2()}}, \code{\link[=log10]{log10()}}, \code{\link[=max]{max()}}, \code{\link[=mean]{mean()}}, \code{\link[=min]{min()}}, \code{\link[=prod]{prod()}}, \code{\link[=range]{range()}}, \code{\link[=round]{round()}}, \code{\link[=sign]{sign()}}, \code{\link[=signif]{signif()}}, \code{\link[=sin]{sin()}}, \code{\link[=sinh]{sinh()}}, \code{\link[=sinpi]{sinpi()}}, \code{\link[=sqrt]{sqrt()}}, \code{\link[=sum]{sum()}}, \code{\link[=tan]{tan()}}, \code{\link[=tanh]{tanh()}}, \code{\link[=tanpi]{tanpi()}}, \code{\link[=trigamma]{trigamma()}} and \code{\link[=trunc]{trunc()}}. Some functions of the \code{stats} package are also implemented: \code{\link[=median]{median()}}, \code{\link[=quantile]{quantile()}}, \code{\link[=mad]{mad()}}, \code{\link[=IQR]{IQR()}}, \code{\link[=fivenum]{fivenum()}}. Also, \code{\link[=boxplot.stats]{boxplot.stats()}} is supported. Since \code{\link[=sd]{sd()}} and \code{\link[=var]{var()}} are non-generic functions, these could not be extended. Use \code{\link[=mad]{mad()}} as an alternative, or use e.g. \code{sd(as.numeric(x))} where \code{x} is your vector of MIC values.
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\code{NA_mic_} is a missing value of the new \verb{<mic>} class.
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}
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\section{Stable Lifecycle}{
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\if{html}{\figure{lifecycle_stable.svg}{options: style=margin-bottom:"5"} \cr}
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The \link[=lifecycle]{lifecycle} of this function is \strong{stable}. In a stable function, major changes are unlikely. This means that the unlying code will generally evolve by adding new arguments; removing arguments or changing the meaning of existing arguments will be avoided.
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If the unlying code needs breaking changes, they will occur gradually. For example, an argument will be deprecated and first continue to work, but will emit a message informing you of the change. Next, typically after at least one newly released version on CRAN, the message will be transformed to an error.
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}
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\section{Read more on Our Website!}{
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On our website \url{https://msberends.github.io/AMR/} you can find \href{https://msberends.github.io/AMR/articles/AMR.html}{a comprehensive tutorial} about how to conduct AMR data analysis, the \href{https://msberends.github.io/AMR/reference/}{complete documentation of all functions} and \href{https://msberends.github.io/AMR/articles/WHONET.html}{an example analysis using WHONET data}.
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}
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\examples{
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mic_data <- as.mic(c(">=32", "1.0", "1", "1.00", 8, "<=0.128", "8", "16", "16"))
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is.mic(mic_data)
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# this can also coerce combined MIC/RSI values:
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as.mic("<=0.002; S") # will return <=0.002
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# mathematical processing treats MICs as [numeric] values
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fivenum(mic_data)
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quantile(mic_data)
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all(mic_data < 512)
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# interpret MIC values
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as.rsi(x = as.mic(2),
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mo = as.mo("S. pneumoniae"),
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ab = "AMX",
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guideline = "EUCAST")
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as.rsi(x = as.mic(4),
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mo = as.mo("S. pneumoniae"),
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ab = "AMX",
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guideline = "EUCAST")
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# plot MIC values, see ?plot
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plot(mic_data)
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plot(mic_data, mo = "E. coli", ab = "cipro")
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}
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\seealso{
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\code{\link[=as.rsi]{as.rsi()}}
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}
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\keyword{datasets}
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