I am wondering if it's possible to use survival analysis on my dataset.

I have percent mortality of organisms in 50 unique treatments of 3 predictor variables (all continuous). I want to know how these predictors affect time to death of the population. The problem is, we only have a ratio every 2 days in each cup. for example, Cup A was 20% dead on day 2, 40% dead on day 4, 70% dead on day 6, etc. But since I didn't track individuals in the population i.e. (starting with 1000, 800 alive on day 2, 600 alive on day 4, etc.) I don't know if I can run a Cox test on a dataset like this. I want to use these predictors to model time to death (survival < 15%) of populations.

I can use the time-to-15%threshold across my 50 treatments, but that largely ignores the survivorship slope in each unique treatment. Since I have the survival ratio (same as survival probability?) in each cup, I have potential to make a survival analysis plot for each treatment, no? How can I predict time to death as a function of these treatment variables?

I've used "survival" and "survminer" packages to model with my observed time to death per treatment already (coxph(Surv(timetodead,status)~var1+var2+var3), but I feel I'm losing a lot of information this way. This is just giving a binary output of under or over 85% mortality, but that lumps together all treatments that are 10% dead with those that are 80% dead, which is not very useful.

Code to create 2 dfs. df1 is the percent survival in each treatment over 10 days. df2 is the time to event (event being survival goes <15%). df2 is what I know I can use for a cox test, but I feel like I should be able to do something more with df1 since I could essentially make 50 survival probability over time lines instead of just 1. Please excuse the imperfect dataset fabrication.

```
# Pt.1 create df1 - all mortality ratios over time
#======================================================
set.seed(5)
df1 <- data.frame(matrix(ncol=7,nrow=300))
colnames(df1) <- c("Trt","Day","PercentSurv","Status","V1","V2","V3")
df1$Trt <- rep(1:50, each=6)
df1$Day <- rep(c(0,2,4,6,8,10), times=50)
for(i in df1$Trt){
df1$PercentSurv[df1$Trt %in% c(i)] <-
c("100",sort(sample(1:100,size=5),decreasing=TRUE))
df1$V1[df1$Trt %in% c(i)] <- sample(12:30,size=1)
df1$V2[df1$Trt %in% c(i)] <- sample(10:40,size=1)
df1$V3[df1$Trt %in% c(i)] <- sample(1:5,size=1)
}
df1$PercentSurv <- as.numeric(df1$PercentSurv)
df1$Status[df1$PercentSurv > 15] <- as.numeric(1) # status 1 = under 85% dead
df1$Status[df1$PercentSurv <=15] <-as.numeric(2) # status 2 = over 85% dead
# Pt.2 create df2 - time-to-event with variables only
#==========================================================
df2 <- data.frame(matrix(ncol = 6,nrow=50))
colnames(df2) <- c("Trt", "Time", "Status","V1","V2","V3")
df2$Trt <- c(1:50)
for(i in df2$Trt){
df2$Status[df2$Trt %in% c(i)] <- ifelse( min( df1$PercentSurv[df1$Trt
%in% c(i)]) <= 15,2,1)
df2$Time[df2$Trt %in% c(i)] <- ifelse(df2$Status[df2$Trt %in%
c(i)]=="2", df1$Day[df1$Trt %in% c(i)]
[min(which(df1$PercentSurv[df1$Trt %in% c(i)]<=15))],10)
df2$V1[df2$Trt %in% c(i)] <- min(df1$V1[df1$Trt %in% c(i)])
df2$V2[df2$Trt %in% c(i)] <- min(df1$V2[df1$Trt %in% c(i)])
df2$V3[df2$Trt %in% c(i)] <- min(df1$V3[df1$Trt %in% c(i)])
}
df2$Time <- as.numeric(df2$Time)
# Pt.3 use survival analysis on variables in df2 - cox test
#=========================================================
install.packages("survival")
install.packages("survminer")
library("survival")
library("survminer")
coxmodel <- coxph(Surv(Time, Status) ~ V1 + V2 + V3, data=df2)
summary(coxmodel)
ggsurvplot(survfit(coxmodel),data=df2, color = "#2E9FDF",
ggtheme = theme_minimal())
```

The graph and summary in Pt.3 show one survival probability graph for all 50 cups, showing that at day 8, survival (i.e. populations completely dying) goes down. And, that in this case, none of the Variables are significant (Makes sense since they're random). But, I still think there's more I can get from DF1. I'm just not sure what it is.