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riskRegression (version 2020.02.05)

predictRisk: Extrating predicting risks from regression models

Description

Extract event probabilities from fitted regression models and machine learning objects. The function predictRisk is a generic function, meaning that it invokes specifically designed functions depending on the 'class' of the first argument. See predictRisk.

Usage

predictRisk(object, newdata, ...)

# S3 method for default predictRisk(object, newdata, times, cause, ...)

# S3 method for double predictRisk(object, newdata, times, cause, ...)

# S3 method for integer predictRisk(object, newdata, times, cause, ...)

# S3 method for factor predictRisk(object, newdata, times, cause, ...)

# S3 method for numeric predictRisk(object, newdata, times, cause, ...)

# S3 method for glm predictRisk(object, newdata, iid = FALSE, average.iid = FALSE, ...)

# S3 method for formula predictRisk(object, newdata, ...)

# S3 method for BinaryTree predictRisk(object, newdata, ...)

# S3 method for lrm predictRisk(object, newdata, ...)

# S3 method for rpart predictRisk(object, newdata, ...)

# S3 method for randomForest predictRisk(object, newdata, ...)

# S3 method for matrix predictRisk(object, newdata, times, cause, ...)

# S3 method for aalen predictRisk(object, newdata, times, ...)

# S3 method for cox.aalen predictRisk(object, newdata, times, ...)

# S3 method for coxph predictRisk( object, newdata, times, product.limit = FALSE, iid = FALSE, average.iid = FALSE, ... )

# S3 method for coxphTD predictRisk(object, newdata, times, landmark, ...)

# S3 method for CSCTD predictRisk(object, newdata, times, cause, landmark, ...)

# S3 method for coxph.penal predictRisk(object, newdata, times, ...)

# S3 method for cph predictRisk( object, newdata, times, product.limit = FALSE, iid = FALSE, average.iid = FALSE, ... )

# S3 method for selectCox predictRisk(object, newdata, times, ...)

# S3 method for prodlim predictRisk(object, newdata, times, cause, ...)

# S3 method for survfit predictRisk(object, newdata, times, ...)

# S3 method for psm predictRisk(object, newdata, times, ...)

# S3 method for ranger predictRisk(object, newdata, times, cause, ...)

# S3 method for rfsrc predictRisk(object, newdata, times, cause, ...)

# S3 method for FGR predictRisk(object, newdata, times, cause, ...)

# S3 method for riskRegression predictRisk(object, newdata, times, cause, ...)

# S3 method for ARR predictRisk(object, newdata, times, cause, ...)

# S3 method for CauseSpecificCox predictRisk( object, newdata, times, cause, product.limit = TRUE, iid = FALSE, average.iid = FALSE, ... )

# S3 method for penfitS3 predictRisk(object, newdata, times, ...)

# S3 method for SuperPredictor predictRisk(object, newdata, ...)

# S3 method for gbm predictRisk(object, newdata, times, ...)

# S3 method for flexsurvreg predictRisk(object, newdata, times, ...)

Arguments

object

A fitted model from which to extract predicted event probabilities.

newdata

A data frame containing predictor variable combinations for which to compute predicted event probabilities.

Additional arguments that are passed on to the current method.

times

A vector of times in the range of the response variable, for which the cumulative incidences event probabilities are computed.

cause

Identifies the cause of interest among the competing events.

iid

Should the iid decomposition be output using an attribute?

average.iid

Should the average iid decomposition be output using an attribute?

product.limit

If TRUE the survival is computed using the product limit estimator. Otherwise the exponential approximation is used (i.e. exp(-cumulative hazard)).

landmark

The starting time for the computation of the cumulative risk.

Value

For binary outcome a vector with predicted risks. For survival outcome with and without competing risks a matrix with as many rows as NROW(newdata) and as many columns as length(times). Each entry is a probability and in rows the values should be increasing.

Details

In uncensored binary outcome data there is no need to choose a time point.

When operating on models for survival analysis (without competing risks) the function still predicts the risk, as 1 - S(t|X) where S(t|X) is survival chance of a subject characterized by X.

When there are competing risks (and the data are right censored) one needs to specify both the time horizon for prediction (can be a vector) and the cause of the event. The function then extracts the absolute risks F_c(t|X) aka the cumulative incidence of an event of type/cause c until time t for a subject characterized by X. Depending on the model it may or not be possible to predict the risk of all causes in a competing risks setting. For example. a cause-specific Cox (CSC) object allows to predict both cases whereas a Fine-Gray regression model (FGR) is specific to one of the causes.

Examples

Run this code
# NOT RUN {
## binary outcome
library(rms)
set.seed(7)
d <- sampleData(80,outcome="binary")
nd <- sampleData(80,outcome="binary")
fit <- lrm(Y~X1+X8,data=d)
predictRisk(fit,newdata=nd)
# }
# NOT RUN {
library(SuperLearner)
set.seed(1)
sl = SuperLearner(Y = d$Y, X = d[,-1], family = binomial(),
      SL.library = c("SL.mean", "SL.glmnet", "SL.randomForest"))
# }
# NOT RUN {
## survival outcome
# generate survival data
library(prodlim)
set.seed(100)
d <- sampleData(100,outcome="survival")
d[,X1:=as.numeric(as.character(X1))]
d[,X2:=as.numeric(as.character(X2))]
# then fit a Cox model
library(rms)
cphmodel <- cph(Surv(time,event)~X1+X2,data=d,surv=TRUE,x=TRUE,y=TRUE)
# or via survival
library(survival)
coxphmodel <- coxph(Surv(time,event)~X1+X2,data=d,x=TRUE,y=TRUE)

# Extract predicted survival probabilities 
# at selected time-points:
ttt <- quantile(d$time)
# for selected predictor values:
ndat <- data.frame(X1=c(0.25,0.25,-0.05,0.05),X2=c(0,1,0,1))
# as follows
predictRisk(cphmodel,newdata=ndat,times=ttt)
predictRisk(coxphmodel,newdata=ndat,times=ttt)

# stratified cox model
sfit <- coxph(Surv(time,event)~strata(X1)+X2,data=d,x=TRUE,y=TRUE)
predictRisk(sfit,newdata=d[1:3,],times=c(1,3,5,10))

## simulate learning and validation data
learndat <- sampleData(100,outcome="survival")
valdat <- sampleData(100,outcome="survival")
## use the learning data to fit a Cox model
library(survival)
fitCox <- coxph(Surv(time,event)~X1+X2,data=learndat,x=TRUE,y=TRUE)
## suppose we want to predict the survival probabilities for all subjects
## in the validation data at the following time points:
## 0, 12, 24, 36, 48, 60
psurv <- predictRisk(fitCox,newdata=valdat,times=seq(0,60,12))
## This is a matrix with event probabilities (1-survival)
## one column for each of the 5 time points
## one row for each validation set individual

# Do the same for a randomSurvivalForest model
# library(randomForestSRC)
# rsfmodel <- rfsrc(Surv(time,event)~X1+X2,data=learndat)
# prsfsurv=predictRisk(rsfmodel,newdata=valdat,times=seq(0,60,12))
# plot(psurv,prsfsurv)

## Cox with ridge option
f1 <- coxph(Surv(time,event)~X1+X2,data=learndat,x=TRUE,y=TRUE)
f2 <- coxph(Surv(time,event)~ridge(X1)+ridge(X2),data=learndat,x=TRUE,y=TRUE)
# }
# NOT RUN {
plot(predictRisk(f1,newdata=valdat,times=10),
     riskRegression:::predictRisk.coxph(f2,newdata=valdat,times=10),
     xlim=c(0,1),
     ylim=c(0,1),
     xlab="Unpenalized predicted survival chance at 10",
     ylab="Ridge predicted survival chance at 10")
# }
# NOT RUN {
## competing risks

library(survival)
library(riskRegression)
library(prodlim)
train <- prodlim::SimCompRisk(100)
test <- prodlim::SimCompRisk(10)
cox.fit  <- CSC(Hist(time,cause)~X1+X2,data=train)
predictRisk(cox.fit,newdata=test,times=seq(1:10),cause=1)

## with strata
cox.fit2  <- CSC(list(Hist(time,cause)~strata(X1)+X2,Hist(time,cause)~X1+X2),data=train)
predictRisk(cox.fit2,newdata=test,times=seq(1:10),cause=1)

# }

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