Nothing
Getting Started with the peakPantheR package
In peakPantheR: Peak Picking and Annotation of High Resolution Experiments
BiocStyle::markdown()
knitr::opts_chunk$set(
collapse = TRUE,
comment = "#>"
)
Package: r Biocpkg("peakPantheR")
Authors: Arnaud Wolfer
## Silently loading all packages
library(BiocStyle)
library(peakPantheR)
library(faahKO)
library(pander)
Package for Peak Picking and ANnoTation of High resolution Experiments in R,
implemented in R and Shiny
Overview
peakPantheR implements functions to detect, integrate and report pre-defined
features in MS files (e.g. compounds, fragments, adducts, ...).
It is designed for:
- Real time feature detection and integration (see
Real Time Annotation)
- process
multiple compounds in one file at a time
- Post-acquisition feature detection, integration and reporting (see
Parallel Annotation)
- process
multiple compounds in multiple files in parallel, store
results in a single object
peakPantheR can process LC/MS data files in NetCDF, mzML/mzXML and
mzData format as data import is achieved using Bioconductor's
r Biocpkg("mzR") package.
Installation
To install peakPantheR from Bioconductor:
if (!requireNamespace("BiocManager", quietly = TRUE))
install.packages("BiocManager")
BiocManager::install("peakPantheR")
Install the development version of peakPantheR directly from GitHub with:
# Install devtools
if(!require("devtools")) install.packages("devtools")
devtools::install_github("phenomecentre/peakPantheR")
Getting Started
To get started peakPantheR's graphical user interface
implements all the functions to detect and integrate multiple compounds in
multiple files in parallel and store results in a single object. It
can be employed to integrate a large number of expected features across a
dataset:
library(peakPantheR)
peakPantheR_start_GUI(browser = TRUE)
# To exit press ESC in the command line
knitr::include_graphics("../man/figures/example-UI.png")
The GUI is to be preferred to understand the methodology, select the best
parameters on a subset of the samples before running the command line, or to
visually explore results.
If a very high number of samples and features is to be processed,
peakpantheR's command line functions are more efficient, as they can
be integrated in scripts and the reporting automated.
Input Data
Both real time and parallel compound integration require a common set of
information:
- Path(s) to
netCDF / mzML MS file(s)
- An expected region of interest (
RT / m/z window) for each compound.
MS files
For demonstration purpose we can annotate a set a set of raw MS spectra (in
NetCDF format) provided by the r Biocpkg("faahKO") package. Briefly, this
subset of the data from [@Saghatelian04] invesigate the metabolic consequences
of knocking out the fatty acid amide hydrolase (FAAH) gene in mice. The dataset
consists of samples from the spinal cords of 6 knock-out and 6 wild-type mice.
Each file contains data in centroid mode acquired in positive ion mode form
200-600 m/z and 2500-4500 seconds.
Below we install the r Biocpkg("faahKO") package and locate raw CDF files of
interest:
if (!requireNamespace("BiocManager", quietly = TRUE))
install.packages("BiocManager")
BiocManager::install("faahKO")
library(faahKO)
## file paths
input_spectraPaths <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"),
system.file('cdf/KO/ko16.CDF', package = "faahKO"),
system.file('cdf/KO/ko18.CDF', package = "faahKO"))
input_spectraPaths
Expected regions of interest
Expected regions of interest (targeted features) are specified using the
following information:
cpdID (numeric)cpdName (character)rtMin (sec)rtMax (sec)rt (sec, optional / NA)mzMin (m/z)mzMax (m/z)mz (m/z, optional / NA)
Below we define 2 features of interest that are present in the
r Biocpkg("faahKO") dataset and can be employed in subsequent vignettes:
# targetFeatTable
input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(),
c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin",
"mz", "mzMax"))), stringsAsFactors=FALSE)
input_targetFeatTable[1,] <- c(1, "Cpd 1", 3310., 3344.888, 3390., 522.194778,
522.2, 522.205222)
input_targetFeatTable[2,] <- c(2, "Cpd 2", 3280., 3385.577, 3440., 496.195038,
496.2, 496.204962)
input_targetFeatTable[,c(1,3:8)] <- sapply(input_targetFeatTable[,c(1,3:8)],
as.numeric)
# use pandoc for improved readability
input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(),
c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin",
"mz", "mzMax"))), stringsAsFactors=FALSE)
input_targetFeatTable[1,] <- c(1, "Cpd 1", 3310., 3344.888, 3390., 522.194778,
522.2, 522.205222)
input_targetFeatTable[2,] <- c(2, "Cpd 2", 3280., 3385.577, 3440., 496.195038,
496.2, 496.204962)
input_targetFeatTable[,c(1,3:8)] <- sapply(input_targetFeatTable[,c(1,3:8)],
as.numeric)
rownames(input_targetFeatTable) <- NULL
pander::pandoc.table(input_targetFeatTable, digits = 9)
Preparing input for the graphical user interface
While the command line functions accept Data.Frame and vectors as input, the
graphical user interface (GUI) will read the same information from a set of
.csv files, or an already set-up peakPantheRAnnotation object in .RData
format.
We can now generate GUI input files for the r Biocpkg("faahKO") example
dataset presented previously:
peakPantheRAnnotation .RData
A peakPantheRAnnotation (previously annotated or not) can be passed as input
in a .RData file. The peakPantheRAnnotation object must be named
annotationObject:
library(faahKO)
# Define the file paths (3 samples)
input_spectraPaths <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"),
system.file('cdf/KO/ko16.CDF', package = "faahKO"),
system.file('cdf/KO/ko18.CDF', package = "faahKO"))
# Define the targeted features (2 features)
input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(),
c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin",
"mz", "mzMax"))), stringsAsFactors=FALSE)
input_targetFeatTable[1,] <- c("ID-1", "Cpd 1", 3310., 3344.888, 3390.,
522.194778, 522.2, 522.205222)
input_targetFeatTable[2,] <- c("ID-1", "Cpd 2", 3280., 3385.577, 3440.,
496.195038, 496.2, 496.204962)
input_targetFeatTable[,3:8] <- sapply(input_targetFeatTable[,3:8], as.numeric)
# Define some random compound and spectra metadata
# cpdMetadata
input_cpdMetadata <- data.frame(matrix(data=c('a','b',1,2), nrow=2, ncol=2,
dimnames=list(c(), c('testcol1','testcol2')),
byrow=FALSE), stringsAsFactors=FALSE)
# spectraMetadata
input_spectraMetadata <- data.frame(matrix(data=c('c','d','e',3,4,5), nrow=3,
ncol=2,
dimnames=list(c(),c('testcol1','testcol2')),
byrow=FALSE), stringsAsFactors=FALSE)
# Initialise a simple peakPantheRAnnotation object
# [3 files, 2 features, no uROI, no FIR]
initAnnotation <- peakPantheRAnnotation(spectraPaths=input_spectraPaths,
targetFeatTable=input_targetFeatTable,
cpdMetadata=input_cpdMetadata,
spectraMetadata=input_spectraMetadata)
# Rename and save the annotation to disk
annotationObject <- initAnnotation
save(annotationObject,
file = './example_annotation_ppR_UI.RData',
compress=TRUE)
CSV file input
Another input option for the GUI input consists of a set of .csv files.
Targeted features
Targeted features are defined in a .csv with as rows each feature to target
(the first row must be the column name), and as columns the fit parameters to
use. At minimum the following parameters must be defined:
cpdID, cpdName, rtMin, rt, rtMax, mzMin, mz, mzMax
If uROI and FIR are to be set, the following columns must be provided:
cpdID, cpdName, ROI_rt, ROI_mz, ROI_rtMin, ROI_rtMax, ROI_mzMin,
ROI_mzMax, uROI_rtMin, uROI_rtMax, uROI_mzMin, uROI_mzMax, uROI_rt,
uROI_mz, FIR_rtMin, FIR_rtMax, FIR_mzMin, FIR_mzMax
# Define targeted features without uROI and FIR (2 features)
input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(),
c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin",
"mz", "mzMax"))), stringsAsFactors=FALSE)
input_targetFeatTable[1,] <- c("ID-1", "Cpd 1", 3310., 3344.888, 3390.,
522.194778, 522.2, 522.205222)
input_targetFeatTable[2,] <- c("ID-1", "Cpd 2", 3280., 3385.577, 3440.,
496.195038, 496.2, 496.204962)
input_targetFeatTable[,3:8] <- sapply(input_targetFeatTable[,3:8], as.numeric)
# save to disk
write.csv(input_targetFeatTable,
file = './1-fitParams_example_UI.csv',
row.names = FALSE)
# use pandoc for improved readability
input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(),
c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin",
"mz", "mzMax"))), stringsAsFactors=FALSE)
input_targetFeatTable[1,] <- c("ID-1", "Cpd 1", 3310., 3344.888, 3390.,
522.194778, 522.2, 522.205222)
input_targetFeatTable[2,] <- c("ID-1", "Cpd 2", 3280., 3385.577, 3440.,
496.195038, 496.2, 496.204962)
input_targetFeatTable[,3:8] <- sapply(input_targetFeatTable[,3:8], as.numeric)
rownames(input_targetFeatTable) <- NULL
pander::pandoc.table(input_targetFeatTable, digits = 9)
Files to process and spectra metadata (optional)
It is possible to select the files on disk directly through the GUI, or to
select a .csv file containing each file path as well as spectra metadata.
Each row correspond to a different spectra (the first row must define the
column names) while columns correspond to the path on disk and metadata. At
minimum a column filepath must be present, with subsequent columns defining
metadata properties.
# Define the spectra paths and metada
input_spectraMeta <- data.frame(matrix(vector(), 3, 3,
dimnames=list(c(),c("filepath","testcol1","testcol2"))),
stringsAsFactors=FALSE)
input_spectraMeta[1,] <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"),
"c", 3)
input_spectraMeta[2,] <- c(system.file('cdf/KO/ko16.CDF', package = "faahKO"),
"d", 4)
input_spectraMeta[3,] <- c(system.file('cdf/KO/ko18.CDF', package = "faahKO"),
"e", 5)
# save to disk
write.csv(input_spectraMeta,
file = './2-spectraMetaWPath_example_UI.csv',
row.names = FALSE)
# use pandoc for improved readability
input_spectraMeta <- data.frame(matrix(vector(), 3, 3,
dimnames=list(c(),c("filepath","testcol1","testcol2"))),
stringsAsFactors=FALSE)
input_spectraMeta[1,] <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"),
"c", 3)
input_spectraMeta[2,] <- c(system.file('cdf/KO/ko16.CDF', package = "faahKO"),
"d", 4)
input_spectraMeta[3,] <- c(system.file('cdf/KO/ko18.CDF', package = "faahKO"),
"e", 5)
rownames(input_spectraMeta) <- NULL
pander::pandoc.table(input_spectraMeta, digits = 0)
Feature meatadata (optional)
It is possible to define some feature metadata, with targeted features as
rows (same order as the fitting parameters, first row defining the column
names), and as columns the metadata.
# Define the feature metada
input_featMeta <- data.frame(matrix(vector(), 2, 2,
dimnames=list(c(),c("testcol1","testcol2"))),
stringsAsFactors=FALSE)
input_featMeta[1,] <- c("a", 1)
input_featMeta[2,] <- c("b", 2)
# save to disk
write.csv(input_featMeta,
file = './3-featMeta_example_UI.csv',
row.names = FALSE)
# use pandoc for improved readability
input_featMeta <- data.frame(matrix(vector(), 2, 2,
dimnames=list(c(),c("testcol1","testcol2"))),
stringsAsFactors=FALSE)
input_featMeta[1,] <- c("a", 1)
input_featMeta[2,] <- c("b", 2)
rownames(input_featMeta) <- NULL
pander::pandoc.table(input_featMeta, digits = 0)
See Also
References
Try the peakPantheR package in your browser
Any scripts or data that you put into this service are public.
peakPantheR documentation built on Nov. 8, 2020, 6:38 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
BiocStyle::markdown()
knitr::opts_chunk$set( collapse = TRUE, comment = "#>" )
Package: r Biocpkg("peakPantheR")
Authors: Arnaud Wolfer
## Silently loading all packages library(BiocStyle) library(peakPantheR) library(faahKO) library(pander)
Package for Peak Picking and ANnoTation of High resolution Experiments in R,
implemented in R and Shiny
Overview
peakPantheR implements functions to detect, integrate and report pre-defined
features in MS files (e.g. compounds, fragments, adducts, ...).
It is designed for:
- Real time feature detection and integration (see
Real Time Annotation)
- process
multiplecompounds inonefile at a time
- process
- Post-acquisition feature detection, integration and reporting (see
Parallel Annotation)
- process
multiplecompounds inmultiplefiles inparallel, store results in asingleobject
- process
peakPantheR can process LC/MS data files in NetCDF, mzML/mzXML and
mzData format as data import is achieved using Bioconductor's
r Biocpkg("mzR") package.
Installation
To install peakPantheR from Bioconductor:
if (!requireNamespace("BiocManager", quietly = TRUE)) install.packages("BiocManager") BiocManager::install("peakPantheR")
Install the development version of peakPantheR directly from GitHub with:
# Install devtools if(!require("devtools")) install.packages("devtools") devtools::install_github("phenomecentre/peakPantheR")
Getting Started
To get started peakPantheR's graphical user interface
implements all the functions to detect and integrate multiple compounds in
multiple files in parallel and store results in a single object. It
can be employed to integrate a large number of expected features across a
dataset:
library(peakPantheR) peakPantheR_start_GUI(browser = TRUE) # To exit press ESC in the command line
knitr::include_graphics("../man/figures/example-UI.png")
The GUI is to be preferred to understand the methodology, select the best parameters on a subset of the samples before running the command line, or to visually explore results.
If a very high number of samples and features is to be processed,
peakpantheR's command line functions are more efficient, as they can
be integrated in scripts and the reporting automated.
Input Data
Both real time and parallel compound integration require a common set of information:
- Path(s) to
netCDF/mzMLMS file(s) - An expected region of interest (
RT/m/zwindow) for each compound.
MS files
For demonstration purpose we can annotate a set a set of raw MS spectra (in
NetCDF format) provided by the r Biocpkg("faahKO") package. Briefly, this
subset of the data from [@Saghatelian04] invesigate the metabolic consequences
of knocking out the fatty acid amide hydrolase (FAAH) gene in mice. The dataset
consists of samples from the spinal cords of 6 knock-out and 6 wild-type mice.
Each file contains data in centroid mode acquired in positive ion mode form
200-600 m/z and 2500-4500 seconds.
Below we install the r Biocpkg("faahKO") package and locate raw CDF files of
interest:
if (!requireNamespace("BiocManager", quietly = TRUE)) install.packages("BiocManager") BiocManager::install("faahKO")
library(faahKO) ## file paths input_spectraPaths <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"), system.file('cdf/KO/ko16.CDF', package = "faahKO"), system.file('cdf/KO/ko18.CDF', package = "faahKO")) input_spectraPaths
Expected regions of interest
Expected regions of interest (targeted features) are specified using the following information:
cpdID(numeric)cpdName(character)rtMin(sec)rtMax(sec)rt(sec, optional /NA)mzMin(m/z)mzMax(m/z)mz(m/z, optional /NA)
Below we define 2 features of interest that are present in the
r Biocpkg("faahKO") dataset and can be employed in subsequent vignettes:
# targetFeatTable input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(), c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin", "mz", "mzMax"))), stringsAsFactors=FALSE) input_targetFeatTable[1,] <- c(1, "Cpd 1", 3310., 3344.888, 3390., 522.194778, 522.2, 522.205222) input_targetFeatTable[2,] <- c(2, "Cpd 2", 3280., 3385.577, 3440., 496.195038, 496.2, 496.204962) input_targetFeatTable[,c(1,3:8)] <- sapply(input_targetFeatTable[,c(1,3:8)], as.numeric)
# use pandoc for improved readability input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(), c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin", "mz", "mzMax"))), stringsAsFactors=FALSE) input_targetFeatTable[1,] <- c(1, "Cpd 1", 3310., 3344.888, 3390., 522.194778, 522.2, 522.205222) input_targetFeatTable[2,] <- c(2, "Cpd 2", 3280., 3385.577, 3440., 496.195038, 496.2, 496.204962) input_targetFeatTable[,c(1,3:8)] <- sapply(input_targetFeatTable[,c(1,3:8)], as.numeric) rownames(input_targetFeatTable) <- NULL pander::pandoc.table(input_targetFeatTable, digits = 9)
Preparing input for the graphical user interface
While the command line functions accept Data.Frame and vectors as input, the
graphical user interface (GUI) will read the same information from a set of
.csv files, or an already set-up peakPantheRAnnotation object in .RData
format.
We can now generate GUI input files for the r Biocpkg("faahKO") example
dataset presented previously:
peakPantheRAnnotation .RData
A peakPantheRAnnotation (previously annotated or not) can be passed as input
in a .RData file. The peakPantheRAnnotation object must be named
annotationObject:
library(faahKO) # Define the file paths (3 samples) input_spectraPaths <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"), system.file('cdf/KO/ko16.CDF', package = "faahKO"), system.file('cdf/KO/ko18.CDF', package = "faahKO")) # Define the targeted features (2 features) input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(), c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin", "mz", "mzMax"))), stringsAsFactors=FALSE) input_targetFeatTable[1,] <- c("ID-1", "Cpd 1", 3310., 3344.888, 3390., 522.194778, 522.2, 522.205222) input_targetFeatTable[2,] <- c("ID-1", "Cpd 2", 3280., 3385.577, 3440., 496.195038, 496.2, 496.204962) input_targetFeatTable[,3:8] <- sapply(input_targetFeatTable[,3:8], as.numeric) # Define some random compound and spectra metadata # cpdMetadata input_cpdMetadata <- data.frame(matrix(data=c('a','b',1,2), nrow=2, ncol=2, dimnames=list(c(), c('testcol1','testcol2')), byrow=FALSE), stringsAsFactors=FALSE) # spectraMetadata input_spectraMetadata <- data.frame(matrix(data=c('c','d','e',3,4,5), nrow=3, ncol=2, dimnames=list(c(),c('testcol1','testcol2')), byrow=FALSE), stringsAsFactors=FALSE) # Initialise a simple peakPantheRAnnotation object # [3 files, 2 features, no uROI, no FIR] initAnnotation <- peakPantheRAnnotation(spectraPaths=input_spectraPaths, targetFeatTable=input_targetFeatTable, cpdMetadata=input_cpdMetadata, spectraMetadata=input_spectraMetadata) # Rename and save the annotation to disk annotationObject <- initAnnotation save(annotationObject, file = './example_annotation_ppR_UI.RData', compress=TRUE)
CSV file input
Another input option for the GUI input consists of a set of .csv files.
Targeted features
Targeted features are defined in a .csv with as rows each feature to target
(the first row must be the column name), and as columns the fit parameters to
use. At minimum the following parameters must be defined:
cpdID, cpdName, rtMin, rt, rtMax, mzMin, mz, mzMax
If uROI and FIR are to be set, the following columns must be provided:
cpdID, cpdName, ROI_rt, ROI_mz, ROI_rtMin, ROI_rtMax, ROI_mzMin,
ROI_mzMax, uROI_rtMin, uROI_rtMax, uROI_mzMin, uROI_mzMax, uROI_rt,
uROI_mz, FIR_rtMin, FIR_rtMax, FIR_mzMin, FIR_mzMax
# Define targeted features without uROI and FIR (2 features) input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(), c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin", "mz", "mzMax"))), stringsAsFactors=FALSE) input_targetFeatTable[1,] <- c("ID-1", "Cpd 1", 3310., 3344.888, 3390., 522.194778, 522.2, 522.205222) input_targetFeatTable[2,] <- c("ID-1", "Cpd 2", 3280., 3385.577, 3440., 496.195038, 496.2, 496.204962) input_targetFeatTable[,3:8] <- sapply(input_targetFeatTable[,3:8], as.numeric) # save to disk write.csv(input_targetFeatTable, file = './1-fitParams_example_UI.csv', row.names = FALSE)
# use pandoc for improved readability input_targetFeatTable <- data.frame(matrix(vector(), 2, 8, dimnames=list(c(), c("cpdID", "cpdName", "rtMin", "rt", "rtMax", "mzMin", "mz", "mzMax"))), stringsAsFactors=FALSE) input_targetFeatTable[1,] <- c("ID-1", "Cpd 1", 3310., 3344.888, 3390., 522.194778, 522.2, 522.205222) input_targetFeatTable[2,] <- c("ID-1", "Cpd 2", 3280., 3385.577, 3440., 496.195038, 496.2, 496.204962) input_targetFeatTable[,3:8] <- sapply(input_targetFeatTable[,3:8], as.numeric) rownames(input_targetFeatTable) <- NULL pander::pandoc.table(input_targetFeatTable, digits = 9)
Files to process and spectra metadata (optional)
It is possible to select the files on disk directly through the GUI, or to
select a .csv file containing each file path as well as spectra metadata.
Each row correspond to a different spectra (the first row must define the
column names) while columns correspond to the path on disk and metadata. At
minimum a column filepath must be present, with subsequent columns defining
metadata properties.
# Define the spectra paths and metada input_spectraMeta <- data.frame(matrix(vector(), 3, 3, dimnames=list(c(),c("filepath","testcol1","testcol2"))), stringsAsFactors=FALSE) input_spectraMeta[1,] <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"), "c", 3) input_spectraMeta[2,] <- c(system.file('cdf/KO/ko16.CDF', package = "faahKO"), "d", 4) input_spectraMeta[3,] <- c(system.file('cdf/KO/ko18.CDF', package = "faahKO"), "e", 5) # save to disk write.csv(input_spectraMeta, file = './2-spectraMetaWPath_example_UI.csv', row.names = FALSE)
# use pandoc for improved readability input_spectraMeta <- data.frame(matrix(vector(), 3, 3, dimnames=list(c(),c("filepath","testcol1","testcol2"))), stringsAsFactors=FALSE) input_spectraMeta[1,] <- c(system.file('cdf/KO/ko15.CDF', package = "faahKO"), "c", 3) input_spectraMeta[2,] <- c(system.file('cdf/KO/ko16.CDF', package = "faahKO"), "d", 4) input_spectraMeta[3,] <- c(system.file('cdf/KO/ko18.CDF', package = "faahKO"), "e", 5) rownames(input_spectraMeta) <- NULL pander::pandoc.table(input_spectraMeta, digits = 0)
Feature meatadata (optional)
It is possible to define some feature metadata, with targeted features as rows (same order as the fitting parameters, first row defining the column names), and as columns the metadata.
# Define the feature metada input_featMeta <- data.frame(matrix(vector(), 2, 2, dimnames=list(c(),c("testcol1","testcol2"))), stringsAsFactors=FALSE) input_featMeta[1,] <- c("a", 1) input_featMeta[2,] <- c("b", 2) # save to disk write.csv(input_featMeta, file = './3-featMeta_example_UI.csv', row.names = FALSE)
# use pandoc for improved readability input_featMeta <- data.frame(matrix(vector(), 2, 2, dimnames=list(c(),c("testcol1","testcol2"))), stringsAsFactors=FALSE) input_featMeta[1,] <- c("a", 1) input_featMeta[2,] <- c("b", 2) rownames(input_featMeta) <- NULL pander::pandoc.table(input_featMeta, digits = 0)
See Also
References
Try the peakPantheR package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
Browse R Packages
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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