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R/flowPlate-accessors.R
In plateCore: Statistical tools and data structures for plate-based flow cytometry
################################################################################
##
## Filename: flowPlate-accessors.R
##
## Author: straine
##
## Data: Oct 10, 2007
##
## Description: Methods for accessing flowPlate objects.
##
################################################################################
################################################################################
## This method creates a virtual plate by combining 2 or more flowPlates.
## If the sample names are not unique, then they are changed using the
## make.unique function. I need to support binding a list of flowPlates, since
## the currenty approach of listing them in the arguments is not elegant. Also,
## it would be nice to be able to do an as(flowPlate,list), similar to
## as(flowSet,list) in flowCore.
## #############################################################################
setMethod("fpbind",signature("flowPlate","flowPlate"),
function(p1,p2,...,plateName="VirtPlate") {
## Get the number of arguments
na <- nargs()
argl <- list(p1,p2,...)
## Get rid of anything that's not a flowPlate'
while(na > 0 && is.null(argl[[na]])) { argl <- argl[-na]; na <- na - 1 }
argl <- argl[sapply(argl,class)=="flowPlate"]
## For now, don't bind two plates with the same name
plateIds <- unlist(sapply(argl,function(x) unique(x@wellAnnotation$plateName)) )
if(length(plateIds) != length(unique(plateIds))) {
stop("Binding flowPlates with identical plateNames is not supported.")
}
## This method can only bind flowPlates where the well annotation data frames have the same column headers
## I think I'll change this later, since well annotation changes over
## the course of an analysis (results columns are added)
annl <- lapply(argl,function(x) x@wellAnnotation)
for(i in 2:length(argl)) {
if(!all.equal(colnames(annl[[1]]),colnames(annl[[i]]))) {
stop("flowPlate Well Annotations must have identical column names.")
}
}
## The sample names have to be unique in order for the phenoData on
## the flowSet to work correctly. Can't have rows with identical names
sampNames <- unlist(lapply(argl,sampleNames))
uniqNames <-make.unique(sampNames)
sampLength <- lapply(argl,function(x) length(sampleNames(x)))
## Vector of lists containing sample names for each plate to be merged
uniqList <- vector("list",length=length(sampLength))
uniqList <- lapply(1:length(sampLength), function(i) {
index2 <- sum(sapply(sampLength[1:i],function(x) x[[1]]))
index1 <- index2 - sampLength[[i]] + 1
temp <- uniqNames[index1:index2]
names(temp) <- sampleNames(argl[[i]])
temp
})
## Remake the annotation list with the unique names
annl <- lapply(1:length(argl),function(i) {
anndf <- argl[[i]]@wellAnnotation
anndf$name <- uniqList[[i]][unlist(anndf$name)]
anndf$name[1]
anndf <- data.frame(name=anndf$name,subset(anndf,select=-name),stringsAsFactors=FALSE)
})
## rbind the annotations into a single data frame
wellAnnotation <- annl[[1]]
for(i in 2:length(annl)) {
wellAnnotation <- rbind(wellAnnotation,annl[[i]])
}
## Get the frames
frames <- unlist(lapply(1:length(argl),function(i) {
x <- argl[[i]]
temp <- x@plateSet@frames
fsList <- lapply(names(uniqList[[i]]),function(fileName) {
temp[[fileName]]
})
names(fsList) <- uniqList[[i]]
fsList
}))
## Now make a flowPlate
np <- flowPlate(as(frames,"flowSet"),wellAnnotation,plateName=plateName)
return(np)
})
################################################################################
## Get groups, which are currently just the negative control groups.
## These consist of the negative control well and all the associated test wells
################################################################################
setMethod("getGroups",signature("flowPlate"),function(data,type="Negative.Control",chan,...) {
## Declaring Variables, otherwise R check throws an error
Channel <- ""
Negative.Control <- ""
name <- ""
Well.Id <- ""
## Get the list negative control wells
wellIds <- unique(data@wellAnnotation$Negative.Control)
## If the negative control well is not in this flowPlate, then don't
## include it.
wellIds <- wellIds[wellIds %in% pData(phenoData(data@plateSet))$Well.Id]
wells <- list()
if(type=="Negative.Control") {
wells <- lapply(wellIds,function(x) {
wells <- unlist(subset(data@wellAnnotation,Channel==chan & Negative.Control==x,select=name))
wells <- c(unlist(subset(data@wellAnnotation,Channel==chan & Well.Id==x,select=name)),wells)
wells <- unique(wells)
if(!length(wells)) {
return(NA)
} else {
return(wells)
}
})
} else {
stop("invalid option for type")
}
wells <- wells[!is.na(wells)]
return(wells)
})
################################################################################
## This is used to transform the flowSet and the isotype gates. Other types
## of gates should be included later.
################################################################################
setMethod("%on%",signature(e2="flowPlate"),function(e1,e2) {
## If the data is transformed, then any gates associated with the plate
## should also be transformed if possible.
if("Negative.Control.Gate" %in% colnames(e2@wellAnnotation)) {
for(y in e1@transforms) {
wellList <- which(e2@wellAnnotation$Channel %in% y@input)
e2@wellAnnotation[wellList,"Negative.Control.Gate"] <- y@f(e2@wellAnnotation[wellList,"Negative.Control.Gate"])
}
}
## Apply the transformation to the flowSet
e2@plateSet <- fsApply(e2@plateSet,"%on%",e1=e1)
e2
})
################################################################################
## Constructor for flowPlates
################################################################################
setMethod("flowPlate",signature("flowSet"),function(data,wellAnnotation,plateName="",...) {
## Getting rid of R CMD Check errors
name <- ""
## Add plateName to well annotation if it doesn't exist
if(!"plateName" %in% colnames(wellAnnotation)) {
wellAnnot <- data.frame(wellAnnotation,plateName=plateName,stringsAsFactors=FALSE)
} else {
wellAnnot <- wellAnnotation
}
## Create a data.frame that corresponds to phenoData.
## All info about a well is on a single row
config <- makePlateLayout(wellAnnot)
##Add the phenoData to the flowSet
data <- flowPhenoMerge(data,config)
## When a flowPlate is first created from a plateLayout template, names are
## missing and need to be added. Names correspond to filenames
if(colnames(wellAnnot)[1]=="Well.Id") {
wellAnnot$name <- sapply(wellAnnot$Well.Id,function(x) {
rownames(pData(phenoData(data))[pData(phenoData(data))$Well.Id==x,])
})
}
## Only keep annotation for samples that are in the dataset
wellAnnot <- subset(wellAnnot,name %in% sampleNames(data) )
## No create the flowPlate
temp <- new("flowPlate")
temp@plateName <- plateName
temp@wellAnnotation <- wellAnnot
temp@plateSet <- data
return(temp)
})
################################################################################
## Fit linear model to FSC vs channel of interest.
## Correct for autofluoresence and then set the median back to it's orignal
## value. The fitting is performed on log transformed data.
################################################################################
setMethod("fixAutoFl",signature("flowPlate"),
function(fp,fsc,chanCols,unstain=NULL,minCut=10) {
plateSet <- fp@plateSet
## Identify the wells containing unstained samples
if(is.null(unstain)) {
unstainWells <- unique(unlist(subset(fp@wellAnnotation,Sample.Type=="Unstained",select="name")))
} else {
unstainWells <- unstain
}
## One or more of the unstained wells needs to have at least 10 or more
## events
numEvents <- fsApply(plateSet[unstainWells],function(x) {
nrow(exprs(x))
})
if (all(numEvents<10)) {
stop("Unstained wells contain too few events!")
} else {
unstainWells <- unstainWells[numEvents>=10]
}
## Fit a linear model to the unstained data, get the slope
unstainFits <- fsApply(plateSet[unstainWells], function(x) {
unlist(lapply(chanCols,function(y) {
## pdh: the data less than 10 seem to throw off the fit
## eas: maybe throw a warning? Or ignore wells with <10 if we have
## other unstained wells?
exprData <- exprs(x)[(exprs(x)[,y]> minCut),]
ltsReg(as.formula(paste(gsub("-",".",y)," ~ ",gsub("-",".",fsc),sep="")), log(data.frame(exprData)))$coefficients[gsub("-",".",fsc)]
}))
})
## Get a matrix of mean slopes
coeff.mat <- matrix(apply(unstainFits,2,mean),nrow=1)
colnames(coeff.mat) <- chanCols
## Apply the correction to the channels of interest in chanCols
## Truncate values less than 0 at 0
plateSet <- fsApply(plateSet,function(x) {
initMFIs <- log(apply(exprs(x)[,chanCols],2,median))
## these are values that are 1 (minimum value before the correction, we want them to be the same after the
## corrrection
selectOnes <- (exprs(x) == 1)
exprs(x)[,chanCols] <- exp(log(exprs(x)[,chanCols])-(log(exprs(x)[,fsc]) %*% coeff.mat))
diffMFI <- matrix(rep(initMFIs - log(apply(exprs(x)[,chanCols],2,median)),nrow(exprs(x))),ncol=length(chanCols),byrow=TRUE)
exprs(x)[,chanCols] <- exp(log(exprs(x)[,chanCols]) + diffMFI)
x@exprs[x@exprs<0] <- 0
## no reset any values that were 1 before to be 1 again
x@exprs[selectOnes] <- 1
x
})
fp@plateSet <- plateSet
return(fp)
})
################################################################################
## Compensate, but only for dyes that were added.
## I shouldn't need to make a copy of the flowSet, but I did in case it
## would save me trouble with environments hanging around.
################################################################################
setMethod("compensate", signature(x="flowPlate"), function(x,spillover) {
temp <- x@plateSet@frames
frames <- lapply(ls(temp),function(fileName) {
well <- pData(phenoData(x@plateSet))[fileName,]
dyeCols <- colnames(spillover)[!is.na(well[,gsub("-",".",colnames(spillover))])]
## Use the compensate method from flowCore on individual wells
if(length(dyeCols)>=2) {
compensate(temp[[fileName]],spillover[dyeCols,dyeCols])
} else {
temp[[fileName]]
}
})
names(frames) <- ls(temp)
config <- makePlateLayout(x@wellAnnotation)
plateSet <- flowPhenoMerge(as(frames,"flowSet"),config)
x@plateSet <- plateSet
return(x)
})
################################################################################
## The summaryStats method calculates some simple statistics for a flowPlate
## that has been processed using setControlGates and applyControlGates. Results
## are stored as new columns in the wellAnnotation data.frame
################################################################################
setMethod("summaryStats", signature("flowPlate"), function(data,Events="Percentage",...) {
## Declare variables for R check
Well.Id <- ""
Channel <- ""
plateName <- ""
Sample.Type <- ""
## Make a local copy of the well annotation
wellAnnotation <- data.frame(data@wellAnnotation)
## Calculate the median fluoresence intensities
wellAnnotation$MFI <- apply(wellAnnotation,1,function(x) {
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0) {
return(median(exprs(frame)[,chan]))
} else { NA }
})
## Calculate the MFI ratio, which is the ratio of MFIs of test wells to
## their associated isotype control on a linear scale.
wellAnnotation$MFI.Ratio <- apply(wellAnnotation,1,function(x) {
negWell <- x[["Negative.Control"]]
chan <- x[["Channel"]]
plateN <- x[["plateName"]]
frame <- data@plateSet[[x[["name"]]]]
if(chan %in% colnames(exprs(frame)) && negWell!="" && nrow(exprs(frame))>0) {
negMFI <- subset(wellAnnotation,Well.Id==negWell & Channel==chan & plateName==plateN)$MFI
if(!is.na(negMFI) && !is.na(x[["MFI"]])) {
return(as.numeric(x[["MFI"]])/as.numeric(negMFI))
}
} else {
return(NA)
}
})
## Fit a robust glm to the MFI ratio vs Percent Positive to assess the
## quality of the gating, uses glmrob from robustbase
if("Percent.Positive" %in% colnames(wellAnnotation)) {
mfiDf <- subset(wellAnnotation, Sample.Type=="Test")
mfiDf$LogMFI.Ratio = log10(mfiDf$MFI.Ratio)
if(Events == "Actual") {
mfiDf$PosCount <- mfiDf$Positive.Count
mfiDf$NegCount <- mfiDf$Total.Count - mfiDf$Positive.Count
} else if (Events == "Percentage") {
mfiDf$PosCount <- round(mfiDf$Percent.Positive,0)
mfiDf$NegCount <- 100-mfiDf$PosCount
}
robMFI <- glmrob(cbind(PosCount,NegCount) ~ LogMFI.Ratio, data=mfiDf,
family=binomial(link="logit"))
x <- -robMFI$coefficients[[1]]-robMFI$coefficients[[2]]*log(wellAnnotation$MFI.Ratio)
wellAnnotation$Predict.PP <- 100/(1 + exp(x))
#diffR <- wellAnnotation$Percent.Positive-wellAnnotation$Predict.PP
resids <- (robMFI$residuals-mean(robMFI$residuals,na.rm=TRUE))/sd(robMFI$residuals,na.rm=TRUE)
wellAnnotation$Gate.Score <- NA
wellAnnotation$Gate.Score[wellAnnotation$Sample.Type=="Test"] <- resids
}
data@wellAnnotation <- wellAnnotation
return(data)
})
################################################################################
## setControl gates the negative control wells to establish a threshold between
## positive and negative cells. Currenty, this threshold can be estimated using
## either some number of MADs or a set quantile.
################################################################################
setMethod("setControlGates", signature("flowPlate"), function(data,gateType="Negative.Control",
threshType="MAD",numMads=5,isoquantile=.995,minCut=NULL,...) {
if(gateType=="Negative.Control") {
## First get the control gate for each of the isotype groups.
isoWells <- subset(data@wellAnnotation,(Sample.Type %in% c("Isotype","Negative.Control")) & !is.na(Channel))
## Create a threshold based on median absolute deviations
if(threshType=="MAD"){
isoGates <- lapply(unique(isoWells$name), function(x) {
sapply(isoWells[isoWells$name==x,"Channel"], function(i) {
mfi <- median(exprs(data[[x]])[,i])
mfi.mad <- mad(exprs(data[[x]])[,i])
thresh <- mfi+numMads*mfi.mad
thresh
})
})
## Quantile based threshold
} else if(threshType=="isoQuant"){
isoGates <- lapply(unique(isoWells$name), function(x) {
sapply(isoWells[isoWells$name==x,"Channel"], function(i) {
y <- exprs(data[[x]])[,i]
if(is.null(minCut)) {
thresh <- quantile(y,isoquantile)
} else {
y = y[y>=minCut]
thresh <- quantile(y,isoquantile)
}
thresh <- as.numeric(thresh)
})
})
} else {
stop("invalid option for threshType")
}
## Copy the gates to the corresponding test wells
names(isoGates) <- unique(isoWells$name)
data@wellAnnotation$Negative.Control.Gate <- apply(data@wellAnnotation,1,function(x) {
well <- subset(data@wellAnnotation,Well.Id== x[["Negative.Control"]] & plateName == x[["plateName"]],select=name)[1,][[1]]
if(length(well) && well %in% names(isoGates)) {
isoGates[[well]][x[["Channel"]]]
} else if (x[["name"]] %in% unique(isoWells$name)) {
isoGates[[x[["name"]]]][x[["Channel"]]]
} else {
return(NA)
}
})
} else {
stop("gateType not supported")
}
return(data)
})
################################################################################
## Gates/Thresholds created using setControlGates are applied to the test wells
## and the percentage of positive cells and number of positive cells are
## reported.
################################################################################
setMethod("applyControlGates", signature("flowPlate"), function(data,gateType="Negative.Control",...) {
if(gateType %in% c("Isogate","Negative.Control")) {
## First get the control gate for each of the isotype groups.
wa <- data@wellAnnotation
##If any applyControlGate or summaryStats columns already exist, get rid of them
newNames <- c('Percent.Positive','Total.Count','Positive.Count','MFI','MFI.Ratio','Predict.PP','Gate.Score')
if(any(newNames %in% colnames(wa))) {
keepCols <- which(!colnames(wa) %in% newNames)
wa <- wa[,keepCols]
}
## Calculate percent positive
wa$Percent.Positive <- apply(data@wellAnnotation,1,function(x) {
thresh <- as.numeric(x[["Negative.Control.Gate"]])
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(!is.na(thresh) && chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0 ) {
iso <- new("rectangleGate",filterId="rectangleGate",parameters=chan,min=thresh,max=Inf)
isoResult <- filter(frame,iso)
return(100*(sum(isoResult@subSet)/nrow(exprs(frame))))
} else {
return(NA)
}
})
## Get the total number of events in each well
wa$Total.Count <- apply(data@wellAnnotation,1,function(x) {
thresh <- as.numeric(x[["Negative.Control.Gate"]])
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(!is.na(thresh) && chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0 ) {
return(nrow(exprs(frame)))
} else {
return(NA)
}
})
## Calculate the number of positive events
wa$Positive.Count <- apply(data@wellAnnotation,1,function(x) {
thresh <- as.numeric(x[["Negative.Control.Gate"]])
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(!is.na(thresh) && chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0 ) {
iso <- new("rectangleGate",filterId="rectangleGate",parameters=chan,min=thresh,max=Inf)
isoResult <- filter(frame,iso)
return(sum(isoResult@subSet))
} else {
return(NA)
}
})
data@wellAnnotation <- wa
} else {
stop("gateType not supported")
}
return(data)
})
################################################################################
## Some convenience functions, primarily wrappers to flowCore, Biobase
################################################################################
setMethod("phenoData","flowPlate",function(object) {
return(phenoData(object@plateSet))
})
setMethod("plateSet","flowPlate",function(fp,...) {
return(fp@plateSet)
})
setMethod("Subset","flowPlate",function(x,subset,select=NULL,...) {
if(is.null(select)) {
x@plateSet <- Subset(x@plateSet,subset)
} else {
select <- unlist(select)
copy = select[select %in% sampleNames(x)]
if(length(copy) != length(select)) copy <- c(copy,sampleNames(x)[pData(phenoData(x@plateSet))[,"Well.Id"] %in% select[!(select %in% sampleNames(x))]])
temp <- x@plateSet@frames
frames <- lapply(ls(temp),function(fileName) {
well <- pData(phenoData(x@plateSet))[fileName,]
if(fileName %in% copy) {
Subset(temp[[fileName]],subset)
} else {
temp[[fileName]]
}
})
names(frames) <- ls(temp)
config <- makePlateLayout(x@wellAnnotation)
plateSet <- flowPhenoMerge(as(frames,"flowSet"),config)
x@plateSet <- plateSet
}
return(x)
})
setMethod("sampleNames","flowPlate",function(object) {
sampleNames(phenoData(object@plateSet))
})
setMethod("wellAnnotation","flowPlate",function(fp,...) {
return(fp@wellAnnotation)
})
################################################################################
## subsetting methods
################################################################################
setMethod("[",c("flowPlate"),function(x,i,j,...,drop=FALSE) {
name <- ""
if(missing(drop)) drop = FALSE
if(missing(i)) return(x)
if(is.numeric(i) || is.logical(i)) {
copy = sampleNames(x)[i]
} else {
i <- unlist(i)
copy = i[i %in% sampleNames(x)]
if(length(copy) != length(i)) copy <- c(copy,sampleNames(x)[pData(phenoData(x@plateSet))[,"Well.Id"] %in% i[!(i %in% sampleNames(x))]])
}
x@plateSet <- x@plateSet[copy]
x@wellAnnotation <- subset(x@wellAnnotation,name %in% copy)
x
})
setMethod("[[","flowPlate",function(x,i,j,...) {
if(length(i)!=1)
stop("subscript out of bounds (index must have length 1)")
if(is.numeric(i)) fr <- sampleNames(x)[[i]]
else if(i %in% sampleNames(x)) fr <- i
else fr <- sampleNames(x)[pData(phenoData(x@plateSet))[,"Well.Id"] == i]
if(is.na(fr)) stop("subscript out of bounds")
fr <- x@plateSet[[fr]]
})
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################################################################################
##
## Filename: flowPlate-accessors.R
##
## Author: straine
##
## Data: Oct 10, 2007
##
## Description: Methods for accessing flowPlate objects.
##
################################################################################
################################################################################
## This method creates a virtual plate by combining 2 or more flowPlates.
## If the sample names are not unique, then they are changed using the
## make.unique function. I need to support binding a list of flowPlates, since
## the currenty approach of listing them in the arguments is not elegant. Also,
## it would be nice to be able to do an as(flowPlate,list), similar to
## as(flowSet,list) in flowCore.
## #############################################################################
setMethod("fpbind",signature("flowPlate","flowPlate"),
function(p1,p2,...,plateName="VirtPlate") {
## Get the number of arguments
na <- nargs()
argl <- list(p1,p2,...)
## Get rid of anything that's not a flowPlate'
while(na > 0 && is.null(argl[[na]])) { argl <- argl[-na]; na <- na - 1 }
argl <- argl[sapply(argl,class)=="flowPlate"]
## For now, don't bind two plates with the same name
plateIds <- unlist(sapply(argl,function(x) unique(x@wellAnnotation$plateName)) )
if(length(plateIds) != length(unique(plateIds))) {
stop("Binding flowPlates with identical plateNames is not supported.")
}
## This method can only bind flowPlates where the well annotation data frames have the same column headers
## I think I'll change this later, since well annotation changes over
## the course of an analysis (results columns are added)
annl <- lapply(argl,function(x) x@wellAnnotation)
for(i in 2:length(argl)) {
if(!all.equal(colnames(annl[[1]]),colnames(annl[[i]]))) {
stop("flowPlate Well Annotations must have identical column names.")
}
}
## The sample names have to be unique in order for the phenoData on
## the flowSet to work correctly. Can't have rows with identical names
sampNames <- unlist(lapply(argl,sampleNames))
uniqNames <-make.unique(sampNames)
sampLength <- lapply(argl,function(x) length(sampleNames(x)))
## Vector of lists containing sample names for each plate to be merged
uniqList <- vector("list",length=length(sampLength))
uniqList <- lapply(1:length(sampLength), function(i) {
index2 <- sum(sapply(sampLength[1:i],function(x) x[[1]]))
index1 <- index2 - sampLength[[i]] + 1
temp <- uniqNames[index1:index2]
names(temp) <- sampleNames(argl[[i]])
temp
})
## Remake the annotation list with the unique names
annl <- lapply(1:length(argl),function(i) {
anndf <- argl[[i]]@wellAnnotation
anndf$name <- uniqList[[i]][unlist(anndf$name)]
anndf$name[1]
anndf <- data.frame(name=anndf$name,subset(anndf,select=-name),stringsAsFactors=FALSE)
})
## rbind the annotations into a single data frame
wellAnnotation <- annl[[1]]
for(i in 2:length(annl)) {
wellAnnotation <- rbind(wellAnnotation,annl[[i]])
}
## Get the frames
frames <- unlist(lapply(1:length(argl),function(i) {
x <- argl[[i]]
temp <- x@plateSet@frames
fsList <- lapply(names(uniqList[[i]]),function(fileName) {
temp[[fileName]]
})
names(fsList) <- uniqList[[i]]
fsList
}))
## Now make a flowPlate
np <- flowPlate(as(frames,"flowSet"),wellAnnotation,plateName=plateName)
return(np)
})
################################################################################
## Get groups, which are currently just the negative control groups.
## These consist of the negative control well and all the associated test wells
################################################################################
setMethod("getGroups",signature("flowPlate"),function(data,type="Negative.Control",chan,...) {
## Declaring Variables, otherwise R check throws an error
Channel <- ""
Negative.Control <- ""
name <- ""
Well.Id <- ""
## Get the list negative control wells
wellIds <- unique(data@wellAnnotation$Negative.Control)
## If the negative control well is not in this flowPlate, then don't
## include it.
wellIds <- wellIds[wellIds %in% pData(phenoData(data@plateSet))$Well.Id]
wells <- list()
if(type=="Negative.Control") {
wells <- lapply(wellIds,function(x) {
wells <- unlist(subset(data@wellAnnotation,Channel==chan & Negative.Control==x,select=name))
wells <- c(unlist(subset(data@wellAnnotation,Channel==chan & Well.Id==x,select=name)),wells)
wells <- unique(wells)
if(!length(wells)) {
return(NA)
} else {
return(wells)
}
})
} else {
stop("invalid option for type")
}
wells <- wells[!is.na(wells)]
return(wells)
})
################################################################################
## This is used to transform the flowSet and the isotype gates. Other types
## of gates should be included later.
################################################################################
setMethod("%on%",signature(e2="flowPlate"),function(e1,e2) {
## If the data is transformed, then any gates associated with the plate
## should also be transformed if possible.
if("Negative.Control.Gate" %in% colnames(e2@wellAnnotation)) {
for(y in e1@transforms) {
wellList <- which(e2@wellAnnotation$Channel %in% y@input)
e2@wellAnnotation[wellList,"Negative.Control.Gate"] <- y@f(e2@wellAnnotation[wellList,"Negative.Control.Gate"])
}
}
## Apply the transformation to the flowSet
e2@plateSet <- fsApply(e2@plateSet,"%on%",e1=e1)
e2
})
################################################################################
## Constructor for flowPlates
################################################################################
setMethod("flowPlate",signature("flowSet"),function(data,wellAnnotation,plateName="",...) {
## Getting rid of R CMD Check errors
name <- ""
## Add plateName to well annotation if it doesn't exist
if(!"plateName" %in% colnames(wellAnnotation)) {
wellAnnot <- data.frame(wellAnnotation,plateName=plateName,stringsAsFactors=FALSE)
} else {
wellAnnot <- wellAnnotation
}
## Create a data.frame that corresponds to phenoData.
## All info about a well is on a single row
config <- makePlateLayout(wellAnnot)
##Add the phenoData to the flowSet
data <- flowPhenoMerge(data,config)
## When a flowPlate is first created from a plateLayout template, names are
## missing and need to be added. Names correspond to filenames
if(colnames(wellAnnot)[1]=="Well.Id") {
wellAnnot$name <- sapply(wellAnnot$Well.Id,function(x) {
rownames(pData(phenoData(data))[pData(phenoData(data))$Well.Id==x,])
})
}
## Only keep annotation for samples that are in the dataset
wellAnnot <- subset(wellAnnot,name %in% sampleNames(data) )
## No create the flowPlate
temp <- new("flowPlate")
temp@plateName <- plateName
temp@wellAnnotation <- wellAnnot
temp@plateSet <- data
return(temp)
})
################################################################################
## Fit linear model to FSC vs channel of interest.
## Correct for autofluoresence and then set the median back to it's orignal
## value. The fitting is performed on log transformed data.
################################################################################
setMethod("fixAutoFl",signature("flowPlate"),
function(fp,fsc,chanCols,unstain=NULL,minCut=10) {
plateSet <- fp@plateSet
## Identify the wells containing unstained samples
if(is.null(unstain)) {
unstainWells <- unique(unlist(subset(fp@wellAnnotation,Sample.Type=="Unstained",select="name")))
} else {
unstainWells <- unstain
}
## One or more of the unstained wells needs to have at least 10 or more
## events
numEvents <- fsApply(plateSet[unstainWells],function(x) {
nrow(exprs(x))
})
if (all(numEvents<10)) {
stop("Unstained wells contain too few events!")
} else {
unstainWells <- unstainWells[numEvents>=10]
}
## Fit a linear model to the unstained data, get the slope
unstainFits <- fsApply(plateSet[unstainWells], function(x) {
unlist(lapply(chanCols,function(y) {
## pdh: the data less than 10 seem to throw off the fit
## eas: maybe throw a warning? Or ignore wells with <10 if we have
## other unstained wells?
exprData <- exprs(x)[(exprs(x)[,y]> minCut),]
ltsReg(as.formula(paste(gsub("-",".",y)," ~ ",gsub("-",".",fsc),sep="")), log(data.frame(exprData)))$coefficients[gsub("-",".",fsc)]
}))
})
## Get a matrix of mean slopes
coeff.mat <- matrix(apply(unstainFits,2,mean),nrow=1)
colnames(coeff.mat) <- chanCols
## Apply the correction to the channels of interest in chanCols
## Truncate values less than 0 at 0
plateSet <- fsApply(plateSet,function(x) {
initMFIs <- log(apply(exprs(x)[,chanCols],2,median))
## these are values that are 1 (minimum value before the correction, we want them to be the same after the
## corrrection
selectOnes <- (exprs(x) == 1)
exprs(x)[,chanCols] <- exp(log(exprs(x)[,chanCols])-(log(exprs(x)[,fsc]) %*% coeff.mat))
diffMFI <- matrix(rep(initMFIs - log(apply(exprs(x)[,chanCols],2,median)),nrow(exprs(x))),ncol=length(chanCols),byrow=TRUE)
exprs(x)[,chanCols] <- exp(log(exprs(x)[,chanCols]) + diffMFI)
x@exprs[x@exprs<0] <- 0
## no reset any values that were 1 before to be 1 again
x@exprs[selectOnes] <- 1
x
})
fp@plateSet <- plateSet
return(fp)
})
################################################################################
## Compensate, but only for dyes that were added.
## I shouldn't need to make a copy of the flowSet, but I did in case it
## would save me trouble with environments hanging around.
################################################################################
setMethod("compensate", signature(x="flowPlate"), function(x,spillover) {
temp <- x@plateSet@frames
frames <- lapply(ls(temp),function(fileName) {
well <- pData(phenoData(x@plateSet))[fileName,]
dyeCols <- colnames(spillover)[!is.na(well[,gsub("-",".",colnames(spillover))])]
## Use the compensate method from flowCore on individual wells
if(length(dyeCols)>=2) {
compensate(temp[[fileName]],spillover[dyeCols,dyeCols])
} else {
temp[[fileName]]
}
})
names(frames) <- ls(temp)
config <- makePlateLayout(x@wellAnnotation)
plateSet <- flowPhenoMerge(as(frames,"flowSet"),config)
x@plateSet <- plateSet
return(x)
})
################################################################################
## The summaryStats method calculates some simple statistics for a flowPlate
## that has been processed using setControlGates and applyControlGates. Results
## are stored as new columns in the wellAnnotation data.frame
################################################################################
setMethod("summaryStats", signature("flowPlate"), function(data,Events="Percentage",...) {
## Declare variables for R check
Well.Id <- ""
Channel <- ""
plateName <- ""
Sample.Type <- ""
## Make a local copy of the well annotation
wellAnnotation <- data.frame(data@wellAnnotation)
## Calculate the median fluoresence intensities
wellAnnotation$MFI <- apply(wellAnnotation,1,function(x) {
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0) {
return(median(exprs(frame)[,chan]))
} else { NA }
})
## Calculate the MFI ratio, which is the ratio of MFIs of test wells to
## their associated isotype control on a linear scale.
wellAnnotation$MFI.Ratio <- apply(wellAnnotation,1,function(x) {
negWell <- x[["Negative.Control"]]
chan <- x[["Channel"]]
plateN <- x[["plateName"]]
frame <- data@plateSet[[x[["name"]]]]
if(chan %in% colnames(exprs(frame)) && negWell!="" && nrow(exprs(frame))>0) {
negMFI <- subset(wellAnnotation,Well.Id==negWell & Channel==chan & plateName==plateN)$MFI
if(!is.na(negMFI) && !is.na(x[["MFI"]])) {
return(as.numeric(x[["MFI"]])/as.numeric(negMFI))
}
} else {
return(NA)
}
})
## Fit a robust glm to the MFI ratio vs Percent Positive to assess the
## quality of the gating, uses glmrob from robustbase
if("Percent.Positive" %in% colnames(wellAnnotation)) {
mfiDf <- subset(wellAnnotation, Sample.Type=="Test")
mfiDf$LogMFI.Ratio = log10(mfiDf$MFI.Ratio)
if(Events == "Actual") {
mfiDf$PosCount <- mfiDf$Positive.Count
mfiDf$NegCount <- mfiDf$Total.Count - mfiDf$Positive.Count
} else if (Events == "Percentage") {
mfiDf$PosCount <- round(mfiDf$Percent.Positive,0)
mfiDf$NegCount <- 100-mfiDf$PosCount
}
robMFI <- glmrob(cbind(PosCount,NegCount) ~ LogMFI.Ratio, data=mfiDf,
family=binomial(link="logit"))
x <- -robMFI$coefficients[[1]]-robMFI$coefficients[[2]]*log(wellAnnotation$MFI.Ratio)
wellAnnotation$Predict.PP <- 100/(1 + exp(x))
#diffR <- wellAnnotation$Percent.Positive-wellAnnotation$Predict.PP
resids <- (robMFI$residuals-mean(robMFI$residuals,na.rm=TRUE))/sd(robMFI$residuals,na.rm=TRUE)
wellAnnotation$Gate.Score <- NA
wellAnnotation$Gate.Score[wellAnnotation$Sample.Type=="Test"] <- resids
}
data@wellAnnotation <- wellAnnotation
return(data)
})
################################################################################
## setControl gates the negative control wells to establish a threshold between
## positive and negative cells. Currenty, this threshold can be estimated using
## either some number of MADs or a set quantile.
################################################################################
setMethod("setControlGates", signature("flowPlate"), function(data,gateType="Negative.Control",
threshType="MAD",numMads=5,isoquantile=.995,minCut=NULL,...) {
if(gateType=="Negative.Control") {
## First get the control gate for each of the isotype groups.
isoWells <- subset(data@wellAnnotation,(Sample.Type %in% c("Isotype","Negative.Control")) & !is.na(Channel))
## Create a threshold based on median absolute deviations
if(threshType=="MAD"){
isoGates <- lapply(unique(isoWells$name), function(x) {
sapply(isoWells[isoWells$name==x,"Channel"], function(i) {
mfi <- median(exprs(data[[x]])[,i])
mfi.mad <- mad(exprs(data[[x]])[,i])
thresh <- mfi+numMads*mfi.mad
thresh
})
})
## Quantile based threshold
} else if(threshType=="isoQuant"){
isoGates <- lapply(unique(isoWells$name), function(x) {
sapply(isoWells[isoWells$name==x,"Channel"], function(i) {
y <- exprs(data[[x]])[,i]
if(is.null(minCut)) {
thresh <- quantile(y,isoquantile)
} else {
y = y[y>=minCut]
thresh <- quantile(y,isoquantile)
}
thresh <- as.numeric(thresh)
})
})
} else {
stop("invalid option for threshType")
}
## Copy the gates to the corresponding test wells
names(isoGates) <- unique(isoWells$name)
data@wellAnnotation$Negative.Control.Gate <- apply(data@wellAnnotation,1,function(x) {
well <- subset(data@wellAnnotation,Well.Id== x[["Negative.Control"]] & plateName == x[["plateName"]],select=name)[1,][[1]]
if(length(well) && well %in% names(isoGates)) {
isoGates[[well]][x[["Channel"]]]
} else if (x[["name"]] %in% unique(isoWells$name)) {
isoGates[[x[["name"]]]][x[["Channel"]]]
} else {
return(NA)
}
})
} else {
stop("gateType not supported")
}
return(data)
})
################################################################################
## Gates/Thresholds created using setControlGates are applied to the test wells
## and the percentage of positive cells and number of positive cells are
## reported.
################################################################################
setMethod("applyControlGates", signature("flowPlate"), function(data,gateType="Negative.Control",...) {
if(gateType %in% c("Isogate","Negative.Control")) {
## First get the control gate for each of the isotype groups.
wa <- data@wellAnnotation
##If any applyControlGate or summaryStats columns already exist, get rid of them
newNames <- c('Percent.Positive','Total.Count','Positive.Count','MFI','MFI.Ratio','Predict.PP','Gate.Score')
if(any(newNames %in% colnames(wa))) {
keepCols <- which(!colnames(wa) %in% newNames)
wa <- wa[,keepCols]
}
## Calculate percent positive
wa$Percent.Positive <- apply(data@wellAnnotation,1,function(x) {
thresh <- as.numeric(x[["Negative.Control.Gate"]])
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(!is.na(thresh) && chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0 ) {
iso <- new("rectangleGate",filterId="rectangleGate",parameters=chan,min=thresh,max=Inf)
isoResult <- filter(frame,iso)
return(100*(sum(isoResult@subSet)/nrow(exprs(frame))))
} else {
return(NA)
}
})
## Get the total number of events in each well
wa$Total.Count <- apply(data@wellAnnotation,1,function(x) {
thresh <- as.numeric(x[["Negative.Control.Gate"]])
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(!is.na(thresh) && chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0 ) {
return(nrow(exprs(frame)))
} else {
return(NA)
}
})
## Calculate the number of positive events
wa$Positive.Count <- apply(data@wellAnnotation,1,function(x) {
thresh <- as.numeric(x[["Negative.Control.Gate"]])
chan <- x[["Channel"]]
frame <- data@plateSet[[x[["name"]]]]
if(!is.na(thresh) && chan %in% colnames(exprs(frame)) && nrow(exprs(frame))>0 ) {
iso <- new("rectangleGate",filterId="rectangleGate",parameters=chan,min=thresh,max=Inf)
isoResult <- filter(frame,iso)
return(sum(isoResult@subSet))
} else {
return(NA)
}
})
data@wellAnnotation <- wa
} else {
stop("gateType not supported")
}
return(data)
})
################################################################################
## Some convenience functions, primarily wrappers to flowCore, Biobase
################################################################################
setMethod("phenoData","flowPlate",function(object) {
return(phenoData(object@plateSet))
})
setMethod("plateSet","flowPlate",function(fp,...) {
return(fp@plateSet)
})
setMethod("Subset","flowPlate",function(x,subset,select=NULL,...) {
if(is.null(select)) {
x@plateSet <- Subset(x@plateSet,subset)
} else {
select <- unlist(select)
copy = select[select %in% sampleNames(x)]
if(length(copy) != length(select)) copy <- c(copy,sampleNames(x)[pData(phenoData(x@plateSet))[,"Well.Id"] %in% select[!(select %in% sampleNames(x))]])
temp <- x@plateSet@frames
frames <- lapply(ls(temp),function(fileName) {
well <- pData(phenoData(x@plateSet))[fileName,]
if(fileName %in% copy) {
Subset(temp[[fileName]],subset)
} else {
temp[[fileName]]
}
})
names(frames) <- ls(temp)
config <- makePlateLayout(x@wellAnnotation)
plateSet <- flowPhenoMerge(as(frames,"flowSet"),config)
x@plateSet <- plateSet
}
return(x)
})
setMethod("sampleNames","flowPlate",function(object) {
sampleNames(phenoData(object@plateSet))
})
setMethod("wellAnnotation","flowPlate",function(fp,...) {
return(fp@wellAnnotation)
})
################################################################################
## subsetting methods
################################################################################
setMethod("[",c("flowPlate"),function(x,i,j,...,drop=FALSE) {
name <- ""
if(missing(drop)) drop = FALSE
if(missing(i)) return(x)
if(is.numeric(i) || is.logical(i)) {
copy = sampleNames(x)[i]
} else {
i <- unlist(i)
copy = i[i %in% sampleNames(x)]
if(length(copy) != length(i)) copy <- c(copy,sampleNames(x)[pData(phenoData(x@plateSet))[,"Well.Id"] %in% i[!(i %in% sampleNames(x))]])
}
x@plateSet <- x@plateSet[copy]
x@wellAnnotation <- subset(x@wellAnnotation,name %in% copy)
x
})
setMethod("[[","flowPlate",function(x,i,j,...) {
if(length(i)!=1)
stop("subscript out of bounds (index must have length 1)")
if(is.numeric(i)) fr <- sampleNames(x)[[i]]
else if(i %in% sampleNames(x)) fr <- i
else fr <- sampleNames(x)[pData(phenoData(x@plateSet))[,"Well.Id"] == i]
if(is.na(fr)) stop("subscript out of bounds")
fr <- x@plateSet[[fr]]
})
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