R/hs_phenoRam.R
In CMET-UGent/MicroRaman: Phenotyping of microbial Raman spectroscopy data
Defines functions
hs_phenoRam
Documented in
hs_phenoRam
#' Calculate the phenotypic heterogeneity indices for each cell
#'
#' @param hs.x HyperSpec object
#' @param preprocess Preprocess? TRUE/FALSE. Defaults to FALSE.
#' @param smooth Option for preprocessing. Defaults to FALSE.
#' @param align Align option for preprocessing. Defaults to FALSE.
#' @param niter Number of iteration Option for preprocessing. Defaults to FALSE.
#' @param return_spectra Should hyperSpec object be returned as final object? Defaults to TRUE.
#' @param peak_detection Should peak detection be used instead of raw spectra for Hill calculations? Defaults to FALSE
#' @param peak_window Peak windows size for a peak to be considered a signal. Defaults to 20.
#' @param peak_method Which peak detection method should be used (requires peak_detection == TRUE).
#' @param path path where Raman data is located, only useful if preprocess==TRUE
#' @param trim.range Wavenumber range to trim from raw spectra. Only used if preprocess==TRUE
#' @param pattern (POSIX) regular expression used to select files (defaults to ".spc"), only used if preprocess==TRUE
#' Options are "MAD" and "SuperSmoother"
#' @importFrom MALDIquant isMassSpectrum intensity createMassSpectrum mass calibrateIntensity trim estimateBaseline removeBaseline
#' @importFrom MALDIquant alignSpectra detectPeaks
#' @importFrom tidyr spread
#' @importFrom graphics lines legend plot
#' @importFrom hyperSpec hy.setOptions spc.loess orderwl
#' @examples
#' # Short example
#' data("hs_example")
#'
#' # Preprocess
#' hs_example <- hs_preprocess(hs_example)
#'
#' # Calculate metrics
#' hs_phenoRam(hs.x = hs_example, preprocess = TRUE, peak_detection = TRUE)
#' @export
#'
hs_phenoRam <- function(hs.x,
preprocess = FALSE,
smooth = FALSE,
align = FALSE,
path = NULL,
trim.range = c(400, 1800),
pattern = ".spc",
niter = 10,
return_spectra = TRUE,
peak_detection = FALSE,
peak_window = 20,
peak_method = c("MAD")) {
# Make sure to keep file names on import
hy.setOptions(file.keep.name = TRUE)
# Check if hyperspec object
if (is.null(hs.x) | class(hs.x) != "hyperSpec") {
stop(
"Error: you did not supply a valid hyperSpec object,
and there is no default, please correct"
)
}
# Preprocess data according to Garcia-Timermans et al. (2020)
if(preprocess){
hs.x <- hs_preprocess(hs.x,
smooth = smooth,
align = align,
path = path,
pattern = pattern,
trim.range = c(400, 1800),
niter = 10)
}
# Peak detection algorithm
if (peak_detection) {
# hyperspec --> maldiquant
mq <- hs_conv_mq(hs.x)
mq.peaks <- detectPeaks(mq, halfWindowSize = peak_window, method = peak_method)
# maldiquant --> hyperspec
wavelengths.trim <-
mass(mq.peaks[[1]])
for (i in 1:length(mq.peaks)) {
tmp <- data.frame(Spectrum_ID = i,
wavenumber = mass(mq.peaks[[i]]),
intensity = intensity(mq.peaks[[i]])
)
if(i == 1) {
df_peaks <- tmp
} else {
df_peaks <- rbind(df_peaks, tmp)
}
}
df_peaks <- tidyr::spread(df_peaks, .data$wavenumber, .data$intensity)
wavelengths.trim <- as.numeric(colnames(df_peaks)[-1])
hs.x <-
new(
"hyperSpec",
spc = as.matrix(df_peaks[-1]),
wavelength = wavelengths.trim,
labels = sapply(mq, function(x)
x@metaData$name)
)
rownames(hs.x@data$spc) <- sapply(mq, function(x)
x@metaData$name)
}
# Extract spectra
x <- hs.x@data$spc
# Normalize spectra by sum of peak intensities
# This assumes that each peak width is identical
x <- x / rowSums(x, na.rm = TRUE)
# Calculate Hill numbers
D2.fun <- function(x) {
x <- x[!is.na(x)]
1 / sum((x) ^ 2)
}
D1.fun <- function(x) {
x <- x[x != 0]
x <- x[!is.na(x)]
exp(-sum((x) * log(x)))
}
D0.fun <- function(x) {
x <- x[!is.na(x)]
sum(x != 0)
}
### D0
D0 <- apply(x,
1,
FUN = D0.fun)
### D1
D1 <- apply(x,
1,
FUN = D1.fun)
### D2
D2 <- apply(x,
1,
FUN = D2.fun)
results <-
data.frame(
Spectrum_ID = rownames(hs.x@data$spc),
D0 = D0,
D1 = D1,
D2 = D2
)
colnames(results) = c("Spectrum_ID", "D0", "D1", "D2")
if (return_spectra) {
results_comb <- list(results, hs.x)
return(results_comb)
} else {
return(results)
}
}
CMET-UGent/MicroRaman documentation built on July 25, 2020, 6:20 p.m.
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Defines functions hs_phenoRam
Documented in hs_phenoRam
#' Calculate the phenotypic heterogeneity indices for each cell
#'
#' @param hs.x HyperSpec object
#' @param preprocess Preprocess? TRUE/FALSE. Defaults to FALSE.
#' @param smooth Option for preprocessing. Defaults to FALSE.
#' @param align Align option for preprocessing. Defaults to FALSE.
#' @param niter Number of iteration Option for preprocessing. Defaults to FALSE.
#' @param return_spectra Should hyperSpec object be returned as final object? Defaults to TRUE.
#' @param peak_detection Should peak detection be used instead of raw spectra for Hill calculations? Defaults to FALSE
#' @param peak_window Peak windows size for a peak to be considered a signal. Defaults to 20.
#' @param peak_method Which peak detection method should be used (requires peak_detection == TRUE).
#' @param path path where Raman data is located, only useful if preprocess==TRUE
#' @param trim.range Wavenumber range to trim from raw spectra. Only used if preprocess==TRUE
#' @param pattern (POSIX) regular expression used to select files (defaults to ".spc"), only used if preprocess==TRUE
#' Options are "MAD" and "SuperSmoother"
#' @importFrom MALDIquant isMassSpectrum intensity createMassSpectrum mass calibrateIntensity trim estimateBaseline removeBaseline
#' @importFrom MALDIquant alignSpectra detectPeaks
#' @importFrom tidyr spread
#' @importFrom graphics lines legend plot
#' @importFrom hyperSpec hy.setOptions spc.loess orderwl
#' @examples
#' # Short example
#' data("hs_example")
#'
#' # Preprocess
#' hs_example <- hs_preprocess(hs_example)
#'
#' # Calculate metrics
#' hs_phenoRam(hs.x = hs_example, preprocess = TRUE, peak_detection = TRUE)
#' @export
#'
hs_phenoRam <- function(hs.x,
preprocess = FALSE,
smooth = FALSE,
align = FALSE,
path = NULL,
trim.range = c(400, 1800),
pattern = ".spc",
niter = 10,
return_spectra = TRUE,
peak_detection = FALSE,
peak_window = 20,
peak_method = c("MAD")) {
# Make sure to keep file names on import
hy.setOptions(file.keep.name = TRUE)
# Check if hyperspec object
if (is.null(hs.x) | class(hs.x) != "hyperSpec") {
stop(
"Error: you did not supply a valid hyperSpec object,
and there is no default, please correct"
)
}
# Preprocess data according to Garcia-Timermans et al. (2020)
if(preprocess){
hs.x <- hs_preprocess(hs.x,
smooth = smooth,
align = align,
path = path,
pattern = pattern,
trim.range = c(400, 1800),
niter = 10)
}
# Peak detection algorithm
if (peak_detection) {
# hyperspec --> maldiquant
mq <- hs_conv_mq(hs.x)
mq.peaks <- detectPeaks(mq, halfWindowSize = peak_window, method = peak_method)
# maldiquant --> hyperspec
wavelengths.trim <-
mass(mq.peaks[[1]])
for (i in 1:length(mq.peaks)) {
tmp <- data.frame(Spectrum_ID = i,
wavenumber = mass(mq.peaks[[i]]),
intensity = intensity(mq.peaks[[i]])
)
if(i == 1) {
df_peaks <- tmp
} else {
df_peaks <- rbind(df_peaks, tmp)
}
}
df_peaks <- tidyr::spread(df_peaks, .data$wavenumber, .data$intensity)
wavelengths.trim <- as.numeric(colnames(df_peaks)[-1])
hs.x <-
new(
"hyperSpec",
spc = as.matrix(df_peaks[-1]),
wavelength = wavelengths.trim,
labels = sapply(mq, function(x)
x@metaData$name)
)
rownames(hs.x@data$spc) <- sapply(mq, function(x)
x@metaData$name)
}
# Extract spectra
x <- hs.x@data$spc
# Normalize spectra by sum of peak intensities
# This assumes that each peak width is identical
x <- x / rowSums(x, na.rm = TRUE)
# Calculate Hill numbers
D2.fun <- function(x) {
x <- x[!is.na(x)]
1 / sum((x) ^ 2)
}
D1.fun <- function(x) {
x <- x[x != 0]
x <- x[!is.na(x)]
exp(-sum((x) * log(x)))
}
D0.fun <- function(x) {
x <- x[!is.na(x)]
sum(x != 0)
}
### D0
D0 <- apply(x,
1,
FUN = D0.fun)
### D1
D1 <- apply(x,
1,
FUN = D1.fun)
### D2
D2 <- apply(x,
1,
FUN = D2.fun)
results <-
data.frame(
Spectrum_ID = rownames(hs.x@data$spc),
D0 = D0,
D1 = D1,
D2 = D2
)
colnames(results) = c("Spectrum_ID", "D0", "D1", "D2")
if (return_spectra) {
results_comb <- list(results, hs.x)
return(results_comb)
} else {
return(results)
}
}
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