Used in 175 countries
Since its first public
release in early 2018, this R package has been used in almost all
countries in the world. Click the map to enlarge and to see the country
names.
Update: The latest EUCAST guideline for intrinsic resistance (v3.3, October 2021) is now supported, the CLSI 2021 interpretation guideline is now supported, and our taxonomy tables have been updated as well (LPSN, 5 October 2021).
AMR
(for R)?
AMR
is a free, open-source and independent R package (see Copyright) to simplify the analysis and prediction
of Antimicrobial Resistance (AMR) and to work with microbial and
antimicrobial data and properties, by using evidence-based methods.
Our aim is to provide a standard for clean and
reproducible AMR data analysis, that can therefore empower
epidemiological analyses to continuously enable surveillance and
treatment evaluation in any setting.
After installing this package, R knows ~71,000 distinct microbial species and all ~570 antibiotic, antimycotic and antiviral drugs by name and code (including ATC, WHONET/EARS-Net, PubChem, LOINC and SNOMED CT), and knows all about valid R/SI and MIC values. It supports any data format, including WHONET/EARS-Net data.
The AMR
package is available in
Danish,
Dutch,
English,
French,
German,
Italian,
Portuguese,
Russian,
Spanish and
Swedish. Antimicrobial drug (group) names and colloquial microorganism
names are provided in these languages.
This package is fully independent of any other R package and works on Windows, macOS and Linux with all versions of R since R-3.0 (April 2013). It was designed to work in any setting, including those with very limited resources. It was created for both routine data analysis and academic research at the Faculty of Medical Sciences of the University of Groningen, in collaboration with non-profit organisations Certe Medical Diagnostics and Advice Foundation and University Medical Center Groningen. This R package formed the basis of two PhD theses (DOI 10.33612/diss.177417131 and DOI 10.33612/diss.192486375) but is actively and durably maintained by two public healthcare organisations in the Netherlands.
Used in 175 countries
Since its first public
release in early 2018, this R package has been used in almost all
countries in the world. Click the map to enlarge and to see the country
names.
AMR
(for R), there’s always a knowledgeable
microbiologist by your side!
# AMR works great with dplyr, but it's not required or neccesary
library(AMR)
library(dplyr)
example_isolates %>%
mutate(bacteria = mo_fullname()) %>%
filter(mo_is_gram_negative(),
mo_is_intrinsic_resistant(ab = "cefotax")) %>%
select(bacteria,
aminoglycosides(),
carbapenems())
With only having defined a row filter on Gram-negative bacteria with
intrinsic resistance to cefotaxime (mo_is_gram_negative()
and mo_is_intrinsic_resistant()
) and a column selection on
two antibiotic groups (aminoglycosides()
and
carbapenems()
), the reference data about all microorganisms and all antibiotics in the
AMR
package make sure you get what you meant:
bacteria | GEN | TOB | AMK | KAN | IPM | MEM |
---|---|---|---|---|---|---|
Pseudomonas aeruginosa | I | S | R | S | ||
Pseudomonas aeruginosa | I | S | R | S | ||
Pseudomonas aeruginosa | I | S | R | S | ||
Pseudomonas aeruginosa | S | S | S | R | S | |
Pseudomonas aeruginosa | S | S | S | R | S | S |
Pseudomonas aeruginosa | S | S | S | R | S | S |
Stenotrophomonas maltophilia | R | R | R | R | R | R |
Pseudomonas aeruginosa | S | S | S | R | S | |
Pseudomonas aeruginosa | S | S | S | R | S | |
Pseudomonas aeruginosa | S | S | S | R | S | S |
A base R equivalent would be, giving the exact same results:
example_isolates$bacteria <- mo_fullname(example_isolates$mo)
example_isolates[which(mo_is_gram_negative() &
mo_is_intrinsic_resistant(ab = "cefotax")),
c("bacteria", aminoglycosides(), carbapenems())]
This package can be used for:
This package is available here on the official R network (CRAN). Install this package in R from CRAN by using the command:
install.packages("AMR")
It will be downloaded and installed automatically. For RStudio, click on the menu Tools > Install Packages… and then type in “AMR” and press Install.
Note: Not all functions on this website may be available in this latest release. To use all functions and data sets mentioned on this website, install the latest development version.
The latest and unpublished development version can be installed from GitHub in two ways:
Manually, using:
install.packages("remotes") # if you haven't already
remotes::install_github("msberends/AMR")
Automatically, using the rOpenSci R-universe platform, by adding our R-universe address to your list of repositories (‘repos’):
After this, you can install and update this AMR
package
like any official release (e.g., using
install.packages("AMR")
or in RStudio via Tools
> Check for Package Updates…).
You can also download the latest build from our repository: https://github.com/msberends/AMR/raw/main/data-raw/AMR_latest.tar.gz
To find out how to conduct AMR data analysis, please continue reading here to get started or click a link in the ‘How to’ menu.
This package contains the complete taxonomic tree of almost all
~71,000 microorganisms from the authoritative and comprehensive
Catalogue of Life (CoL, www.catalogueoflife.org),
supplemented by data from the List of Prokaryotic names with Standing in
Nomenclature (LPSN, lpsn.dsmz.de).
This supplementation is needed until the CoL+ project is finished,
which we await. With catalogue_of_life_version()
can be
checked which version of the CoL is included in this package.
Read more about which data from the Catalogue of Life in our manual.
This package contains all ~570 antibiotic, antimycotic and antiviral drugs and their Anatomical Therapeutic Chemical (ATC) codes, ATC groups and Defined Daily Dose (DDD, oral and IV) from the World Health Organization Collaborating Centre for Drug Statistics Methodology (WHOCC, https://www.whocc.no) and the Pharmaceuticals Community Register of the European Commission.
NOTE: The WHOCC copyright does not allow use for commercial purposes, unlike any other info from this package. See https://www.whocc.no/copyright_disclaimer/.
Read more about the data from WHOCC in our manual.
We support WHONET and EARS-Net data. Exported files from WHONET can
be imported into R and can be analysed easily using this package. For
education purposes, we created an example data set WHONET
with the exact same structure as a WHONET export file. Furthermore, this
package also contains a data set
antibiotics with all EARS-Net antibiotic abbreviations, and knows
almost all WHONET abbreviations for microorganisms. When using WHONET
data as input for analysis, all input parameters will be set
automatically.
Read our tutorial about how to work with WHONET data here.
The AMR
package basically does four important
things:
It cleanses existing data by providing new classes for microoganisms, antibiotics and antimicrobial results (both S/I/R and MIC). By installing this package, you teach R everything about microbiology that is needed for analysis. These functions all use intelligent rules to guess results that you would expect:
as.mo()
to get a microbial ID. The IDs are human
readable for the trained eye - the ID of Klebsiella pneumoniae
is “B_KLBSL_PNMN” (B stands for Bacteria) and the ID of S.
aureus is “B_STPHY_AURS”. The function takes almost any text as
input that looks like the name or code of a microorganism like “E.
coli”, “esco” or “esccol” and tries to find expected results using
intelligent rules combined with the included Catalogue of Life data set.
It only takes milliseconds to find results, please see our benchmarks. Moreover, it can group
Staphylococci into coagulase negative and positive (CoNS and
CoPS, see source) and can
categorise Streptococci into Lancefield groups (like
beta-haemolytic Streptococcus Group B, source).as.ab()
to get an antibiotic ID. Like microbial
IDs, these IDs are also human readable based on those used by EARS-Net.
For example, the ID of amoxicillin is AMX
and the ID of
gentamicin is GEN
. The as.ab()
function also
uses intelligent rules to find results like accepting misspelling, trade
names and abbrevations used in many laboratory systems. For instance,
the values “Furabid”, “Furadantin”, “nitro” all return the ID of
Nitrofurantoine. To accomplish this, the package contains a database
with most LIS codes, official names, trade names, ATC codes, defined
daily doses (DDD) and drug categories of antibiotics.as.rsi()
to get antibiotic interpretations based on
raw MIC values (in mg/L) or disk diffusion values (in mm), or transform
existing values to valid antimicrobial results. It produces just S, I or
R based on your input and warns about invalid values. Even values like
“<=0.002; S” (combined MIC/RSI) will result in “S”.as.mic()
to cleanse your MIC values. It produces a
so-called factor (called ordinal in SPSS) with valid MIC values
as levels. A value like “<=0.002; S” (combined MIC/RSI) will result
in “<=0.002”.It enhances existing data and adds new data from data sets included in this package.
eucast_rules()
to apply EUCAST
expert rules to isolates (not the translation from MIC to R/SI
values, use as.rsi()
for that).first_isolate()
to identify the first isolates of
every patient using
guidelines from the CLSI (Clinical and Laboratory Standards
Institute).
mdro()
to determine which micro-organisms are
multi-drug resistant organisms (MDRO). It supports a variety of
international guidelines, such as the MDR-paper by Magiorakos et
al. (2012, PMID
21793988), the exceptional phenotype definitions of EUCAST and the
WHO guideline on multi-drug resistant TB. It also supports the national
guidelines of the Netherlands and Germany.mo_genus()
,
mo_family()
, mo_gramstain()
or even
mo_phylum()
. Use mo_snomed()
to look up any
SNOMED CT code associated with a microorganism. As all these function
use as.mo()
internally, they also use the same intelligent
rules for determination. For example, mo_genus("MRSA")
and
mo_genus("S. aureus")
will both return
"Staphylococcus"
. They also come with support for German,
Danish, Dutch, Spanish, Italian, French and Portuguese. These functions
can be used to add new variables to your data.ab_name()
, ab_group()
, ab_atc()
,
ab_loinc()
and ab_tradenames()
to look up
values. The ab_*
functions use as.ab()
internally so they support the same intelligent rules to guess the most
probable result. For example, ab_name("Fluclox")
,
ab_name("Floxapen")
and ab_name("J01CF05")
will all return "Flucloxacillin"
. These functions can again
be used to add new variables to your data.It analyses the data with convenient functions that use well-known methods.
susceptibility()
and
resistance()
functions, or be even more specific with the
proportion_R()
, proportion_IR()
,
proportion_I()
, proportion_SI()
and
proportion_S()
functions. Similarly, the number of
isolates can be determined with the count_resistant()
,
count_susceptible()
and count_all()
functions.
All these functions can be used with the dplyr
package
(e.g. in conjunction with summarise()
)geom_rsi()
, a function made for
the ggplot2
packageresistance_predict()
functionIt teaches the user how to use all the above actions.
example_isolates
data set. This data set contains 2,000 microbial isolates with their
full antibiograms. It reflects reality and can be used to practice AMR
data analysis.WHONET
data
set. This data set only contains fake data, but with the exact same
structure as files exported by WHONET. Read more about WHONET on its tutorial page.This R package is free, open-source software and licensed under the GNU General Public License v2.0 (GPL-2). In a nutshell, this means that this package:
May be used for commercial purposes
May be used for private purposes
May not be used for patent purposes
May be modified, although:
May be distributed, although:
Comes with a LIMITATION of liability
Comes with NO warranty