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R/predict.time.R
In brainImageR: A Framework for visualizing gene set enrichment throughout neurodevelopment
Defines functions
predict_time
Documented in
predict_time
#' @title Predict developmental time from gene expression data
#'
#' @description
#' Predict human developmental time from expression dataset
#'
#' @param dat Normalized expression matrix
#' @param minage min pcw of the reference set. default = 8
#' @param maxage max pcw of the reference set. default = 2120
#' @param genelist Optional: restrict analysis to gene list
#' @param tissue Optional: restrict analysis to tissue (available)
#' @param minrsq (range 0-1) model leniency. default = 0.5.
#' @return spatiotemporal predictions.
#'
#' @examples
#' #brainImageR:::loadworkspace()
#' ##Load in the data
#' data(dat)
#' ##predict time
#' #time <- predict_time(dat)
#' @importFrom stats cor var quantile na.exclude sd predict
#' @export
predict_time <- function(dat = NULL, genelist = NULL, minage = 8,
maxage = 2120, tissue = NULL, minrsq = 0.6){
aba_fun <- function(x){cor(x = x, y = abapcw$pcw)}
alldev_colMeta <- .cache[["EH1450"]]
alldev_scale <- .cache[["EH1451"]]
#1) Check data
if(is.null(dat)){
stop("data is NULL.")
}
##################################
### SECTION 1 A genelist is provided
##################################
#3) Check genelist
# genelist is provided by the user
if(!is.null(genelist)){#Provided by the user
genelist <- unique(genelist)
}else {#no gene list given
v <- unlist(apply(dat, 1, var))
v_min <- quantile(v,probs = 0.33)
genelist <- rownames(dat[rowSums(dat) > 2 & v > v_min,])
}
###########################
#4A) Calculate model if not using a precomputed model
###########################
if(!is.null(genelist) ){
######
# Remove genes that don't cooperate well with randomforest
if(length(grep(pattern = "-", genelist, fixed = TRUE)) > 0){
a <- grep(pattern = "-", genelist, fixed = TRUE)
genelist <- genelist[-a]
}
if(length(grep(pattern = ".", genelist, fixed = TRUE)) > 0){
a <- grep(pattern = ".", genelist, fixed = TRUE)
genelist <- genelist[-a]
}
######
setgenes <- genelist
######
if(is.null(minage)){minage <- min(alldev_colMeta$pcw)}
if(is.null(maxage)){maxage <- max(alldev_colMeta$pcw)}
if(maxage > 2120){
maxage <- 2120
warning("Max age surpassed. Setting to 2120 pcw")
}
acpcw <- alldev_colMeta$pcw
aba <- alldev_scale[,acpcw < maxage & acpcw > minage ]
abapcw <- alldev_colMeta[acpcw < maxage & acpcw > minage,]
if(!is.null(tissue)){
aba <- aba[,abapcw$structure_acronym == tissue ]
abapcw <- abapcw[abapcw$structure_acronym == tissue,]
}
nm <- table(c(genelist,rownames(aba)))
nm <- names(nm[nm==2])
aba <- aba[nm,]
m <- apply(X = aba, MARGIN = 1,FUN = mean)
mq <- quantile(na.exclude(m))[2]
s <- apply(X = aba, MARGIN = 1,FUN = sd)
sq <- quantile(na.exclude(s))[2]
pickme <- m[m > mq & s > sq]
aba <- aba[names(na.exclude(pickme)),]
aba_pcw_cor <- apply(X = aba, MARGIN = 1, FUN = aba_fun)
loadgenes <- names(na.exclude(aba_pcw_cor[abs(aba_pcw_cor) > 0.5 ]))
if(length(loadgenes) < 1){
warning("No association with dev time. Try a new gene list.")
stop()
}
#Initialize
qp <- 0.1
tmp <- as.data.frame(t(rbind(aba[loadgenes,],abapcw$pcw)))
colnames(tmp) <- c(loadgenes,"pcw")
if(length(grep("-",colnames(tmp))) > 0){
tmp <- tmp[,-c(grep("-",colnames(tmp)))]
}
if(sum(is.na(tmp)) > 0){
tmp <- tmp[,-c(which(is.na(tmp[1,])))]
}
colnames(tmp)[length(tmp)] <- "pcw"
rf <- randomForest::randomForest(log(pcw) ~ ., tmp, ntree= 500)
gini <- as.data.frame(rf$importance)
colnames(gini) <- c("MeanDecreaseGini")
cutoff <- quantile((gini$MeanDecreaseGini),probs=qp)
tmpgenes <- rownames(gini)[gini$MeanDecreaseGini >= cutoff]
#Round 2
qp <- 0.5 #was 0.5
tmp <- as.data.frame(t(rbind(aba[tmpgenes,],abapcw$pcw)))
colnames(tmp) <- c(tmpgenes,"pcw")
rf <- randomForest::randomForest(log(pcw) ~ ., tmp, ntree= 150)
gini2 <- as.data.frame(rf$importance)
colnames(gini2) <- c("MeanDecreaseGini")
cutoff <- quantile((gini2$MeanDecreaseGini),probs=qp)
setgenes <- rownames(gini2)[gini2$MeanDecreaseGini >= cutoff]
if(length(setgenes) < 2 | mean(na.exclude(rf$rsq)) < minrsq){
warning("No association with dev time. Try a new gene list.")
stop()
}
}else{
warning("genelist empty")
stop()
}
###########################
#5) Use the model to predict time
###########################
#6) Check if the dataset contains the genes in the model.
genes <- table(c(rownames(dat), setgenes, setgenes))
if(sum(genes == 3) == 0){
warning("No genes in reference. Trying the transpose of the dataset...")
dat <- t(dat)
genes <- table(c(rownames(dat), setgenes, setgenes))
if(sum(genes == 3) == 0){
warning("Use official human gene symbol. Ex: REST, SOX11 ...")
stop()
}
}
missing <- names(genes[genes == 2])
genes <- names(genes[genes == 3])
#7) If there is not 100% overlap
# Or if the user recalculated the setgenes above
# ...calculate a new Model
#if(length(genes) != length(setgenes)){
tmp_genes <- na.exclude(aba[na.exclude(genes),])
tmp <- as.data.frame(t(rbind(tmp_genes,abapcw$pcw)))
colnames(tmp) <- c(rownames(tmp_genes),"pcw")
Model <- randomForest::randomForest(log(pcw) ~., tmp )
#}
dat.scale <- matrix(data=0,nrow=nrow(dat),ncol=ncol(dat))
dat <- round(dat, digits = 0)
for(i in brainrange(1,ncol(dat))){
dat.scale[,i] <- scale(dat[,i])[,1]
}
dimnames(dat.scale) <- dimnames(dat)
dat.scale <- as.data.frame(dat.scale)
NewData <- as.data.frame(t(dat.scale))
pred_age <- exp(predict(object=Model,newdata=NewData))
pred <- methods::new(Class="Pred", pred_age = data.frame(pred_age),
model = list(Model),
minage = as.numeric(minage),
maxage = as.numeric(maxage),
tissue = as.character(tissue)
)
return(pred)
}
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brainImageR documentation built on May 6, 2019, 3:54 a.m.
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Defines functions predict_time
Documented in predict_time
#' @title Predict developmental time from gene expression data
#'
#' @description
#' Predict human developmental time from expression dataset
#'
#' @param dat Normalized expression matrix
#' @param minage min pcw of the reference set. default = 8
#' @param maxage max pcw of the reference set. default = 2120
#' @param genelist Optional: restrict analysis to gene list
#' @param tissue Optional: restrict analysis to tissue (available)
#' @param minrsq (range 0-1) model leniency. default = 0.5.
#' @return spatiotemporal predictions.
#'
#' @examples
#' #brainImageR:::loadworkspace()
#' ##Load in the data
#' data(dat)
#' ##predict time
#' #time <- predict_time(dat)
#' @importFrom stats cor var quantile na.exclude sd predict
#' @export
predict_time <- function(dat = NULL, genelist = NULL, minage = 8,
maxage = 2120, tissue = NULL, minrsq = 0.6){
aba_fun <- function(x){cor(x = x, y = abapcw$pcw)}
alldev_colMeta <- .cache[["EH1450"]]
alldev_scale <- .cache[["EH1451"]]
#1) Check data
if(is.null(dat)){
stop("data is NULL.")
}
##################################
### SECTION 1 A genelist is provided
##################################
#3) Check genelist
# genelist is provided by the user
if(!is.null(genelist)){#Provided by the user
genelist <- unique(genelist)
}else {#no gene list given
v <- unlist(apply(dat, 1, var))
v_min <- quantile(v,probs = 0.33)
genelist <- rownames(dat[rowSums(dat) > 2 & v > v_min,])
}
###########################
#4A) Calculate model if not using a precomputed model
###########################
if(!is.null(genelist) ){
######
# Remove genes that don't cooperate well with randomforest
if(length(grep(pattern = "-", genelist, fixed = TRUE)) > 0){
a <- grep(pattern = "-", genelist, fixed = TRUE)
genelist <- genelist[-a]
}
if(length(grep(pattern = ".", genelist, fixed = TRUE)) > 0){
a <- grep(pattern = ".", genelist, fixed = TRUE)
genelist <- genelist[-a]
}
######
setgenes <- genelist
######
if(is.null(minage)){minage <- min(alldev_colMeta$pcw)}
if(is.null(maxage)){maxage <- max(alldev_colMeta$pcw)}
if(maxage > 2120){
maxage <- 2120
warning("Max age surpassed. Setting to 2120 pcw")
}
acpcw <- alldev_colMeta$pcw
aba <- alldev_scale[,acpcw < maxage & acpcw > minage ]
abapcw <- alldev_colMeta[acpcw < maxage & acpcw > minage,]
if(!is.null(tissue)){
aba <- aba[,abapcw$structure_acronym == tissue ]
abapcw <- abapcw[abapcw$structure_acronym == tissue,]
}
nm <- table(c(genelist,rownames(aba)))
nm <- names(nm[nm==2])
aba <- aba[nm,]
m <- apply(X = aba, MARGIN = 1,FUN = mean)
mq <- quantile(na.exclude(m))[2]
s <- apply(X = aba, MARGIN = 1,FUN = sd)
sq <- quantile(na.exclude(s))[2]
pickme <- m[m > mq & s > sq]
aba <- aba[names(na.exclude(pickme)),]
aba_pcw_cor <- apply(X = aba, MARGIN = 1, FUN = aba_fun)
loadgenes <- names(na.exclude(aba_pcw_cor[abs(aba_pcw_cor) > 0.5 ]))
if(length(loadgenes) < 1){
warning("No association with dev time. Try a new gene list.")
stop()
}
#Initialize
qp <- 0.1
tmp <- as.data.frame(t(rbind(aba[loadgenes,],abapcw$pcw)))
colnames(tmp) <- c(loadgenes,"pcw")
if(length(grep("-",colnames(tmp))) > 0){
tmp <- tmp[,-c(grep("-",colnames(tmp)))]
}
if(sum(is.na(tmp)) > 0){
tmp <- tmp[,-c(which(is.na(tmp[1,])))]
}
colnames(tmp)[length(tmp)] <- "pcw"
rf <- randomForest::randomForest(log(pcw) ~ ., tmp, ntree= 500)
gini <- as.data.frame(rf$importance)
colnames(gini) <- c("MeanDecreaseGini")
cutoff <- quantile((gini$MeanDecreaseGini),probs=qp)
tmpgenes <- rownames(gini)[gini$MeanDecreaseGini >= cutoff]
#Round 2
qp <- 0.5 #was 0.5
tmp <- as.data.frame(t(rbind(aba[tmpgenes,],abapcw$pcw)))
colnames(tmp) <- c(tmpgenes,"pcw")
rf <- randomForest::randomForest(log(pcw) ~ ., tmp, ntree= 150)
gini2 <- as.data.frame(rf$importance)
colnames(gini2) <- c("MeanDecreaseGini")
cutoff <- quantile((gini2$MeanDecreaseGini),probs=qp)
setgenes <- rownames(gini2)[gini2$MeanDecreaseGini >= cutoff]
if(length(setgenes) < 2 | mean(na.exclude(rf$rsq)) < minrsq){
warning("No association with dev time. Try a new gene list.")
stop()
}
}else{
warning("genelist empty")
stop()
}
###########################
#5) Use the model to predict time
###########################
#6) Check if the dataset contains the genes in the model.
genes <- table(c(rownames(dat), setgenes, setgenes))
if(sum(genes == 3) == 0){
warning("No genes in reference. Trying the transpose of the dataset...")
dat <- t(dat)
genes <- table(c(rownames(dat), setgenes, setgenes))
if(sum(genes == 3) == 0){
warning("Use official human gene symbol. Ex: REST, SOX11 ...")
stop()
}
}
missing <- names(genes[genes == 2])
genes <- names(genes[genes == 3])
#7) If there is not 100% overlap
# Or if the user recalculated the setgenes above
# ...calculate a new Model
#if(length(genes) != length(setgenes)){
tmp_genes <- na.exclude(aba[na.exclude(genes),])
tmp <- as.data.frame(t(rbind(tmp_genes,abapcw$pcw)))
colnames(tmp) <- c(rownames(tmp_genes),"pcw")
Model <- randomForest::randomForest(log(pcw) ~., tmp )
#}
dat.scale <- matrix(data=0,nrow=nrow(dat),ncol=ncol(dat))
dat <- round(dat, digits = 0)
for(i in brainrange(1,ncol(dat))){
dat.scale[,i] <- scale(dat[,i])[,1]
}
dimnames(dat.scale) <- dimnames(dat)
dat.scale <- as.data.frame(dat.scale)
NewData <- as.data.frame(t(dat.scale))
pred_age <- exp(predict(object=Model,newdata=NewData))
pred <- methods::new(Class="Pred", pred_age = data.frame(pred_age),
model = list(Model),
minage = as.numeric(minage),
maxage = as.numeric(maxage),
tissue = as.character(tissue)
)
return(pred)
}
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