Last updated: 2021-06-19
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# rm(list=ls())
library(knitr)
library(tictoc)
library(workflowr)
library(VennDiagram)
Loading required package: grid
Loading required package: futile.logger
library(dplyr)
Warning: package 'dplyr' was built under R version 4.0.2
Attaching package: 'dplyr'
The following objects are masked from 'package:stats':
filter, lag
The following objects are masked from 'package:base':
intersect, setdiff, setequal, union
library(foreach)
library(doParallel)
Loading required package: iterators
Loading required package: parallel
library(ggplot2)
Warning: package 'ggplot2' was built under R version 4.0.2
library(reshape2)
library(RColorBrewer)
library(devtools)
Loading required package: usethis
Error in get(genname, envir = envir) : object 'testthat_print' not found
library(ggsignif)
library(plotly)
Attaching package: 'plotly'
The following object is masked from 'package:ggplot2':
last_plot
The following object is masked from 'package:stats':
filter
The following object is masked from 'package:graphics':
layout
library(BiocManager)
Bioconductor version 3.12 (BiocManager 1.30.10), ?BiocManager::install for help
Bioconductor version '3.12' is out-of-date; the current release version '3.13'
is available with R version '4.1'; see https://bioconductor.org/install
Attaching package: 'BiocManager'
The following object is masked from 'package:devtools':
install
# library(ensembldb) #Loading this with Dplyr commands seems to throw an error in Rmd
# library(EnsDb.Hsapiens.v86) #Loading this with Dplyr commands seems to throw an error in Rmd
source("code/contab_maker.R")
source("code/alldata_compiler.R")
source("code/quadratic_solver.R")
source("code/mut_excl_genes_generator.R")
source("code/mut_excl_genes_datapoints.R")
source("code/simresults_generator.R")
# source("../code/contab_maker.R")
# source("../code/alldata_compiler.R")
# source("../code/quadratic_solver.R")
# source("../code/mut_excl_genes_generator.R")
# source("../code/mut_excl_genes_datapoints.R")
# source("../code/simresults_generator.R")
######################Cleanup for GGPlot2#########################################
cleanup=theme_bw() +
theme(plot.title = element_text(hjust=.5),
panel.grid.major = element_blank(),
panel.grid.major.y = element_blank(),
panel.background = element_blank(),
# axis.line = element_line(color = "black"),
axis.text = element_text(face="bold",color="black",size="11"),
text=element_text(size=11,face="bold"),
axis.title=element_text(face="bold",size="11"))
nameposctrl1<-'BRAF'
#Positive control 1
nameposctrl2<-'NRAS'
#Oncogene in Question
namegene<-'ATI'
#Mutation Boolean (Y or N)
mtn<-'N'
#Name Mutation for Positive Ctrl 1
nameposctrl1mt<-'V600E'
#Name of Mutation for Positive Ctrl 2
nameposctrl2mt<-'Q61L'
alldata=read.csv("output/all_data_skcm.csv",sep=",",header=T,stringsAsFactors=F)
# alldata=read.csv("../output/all_data_skcm.csv",sep=",",header=T,stringsAsFactors=F)
head(alldata)
X Patid mean_RPKM_1.19 mean_RPKM_20.29 Ratio20.29 mRNA_count BRAF
1 1 TCGA-BF-A1PU 0.62445977 1.24042009 1.986389 948 V600E
2 2 TCGA-BF-A1PV 0.02099345 0.15815619 7.533598 82 NaN
3 3 TCGA-BF-A1PX 0.01752838 0.09612414 5.483914 92 V600E
4 4 TCGA-BF-A1PZ 0.19874434 7.27553619 36.607514 2822 NaN
5 5 TCGA-BF-A1Q0 2.13353636 3.71661801 1.741999 2211 NaN
6 6 TCGA-BF-A3DJ 0.06244694 0.55656239 8.912565 281 V600E
NRAS RSEM_normalized ATI
1 NaN 107.1429 0
2 Q61L 8.9659 0
3 NaN 14.5985 0
4 Q61R 329.0810 1
5 NaN 277.0434 0
6 NaN 35.1542 0
Contab downsampler function that the next code chunk uses:
contab_downsampler<- function(contab,prob) {
p11=contab[1,1]
p10=contab[1,2]
p01=contab[2,1]
p00=contab[2,2]
contab_downsampled=contab ###Just making a dummy contingency table
contab_downsampled[1,1]=prob*p11/(p10+p11)
contab_downsampled[1,2]=prob*p10/(p10+p11)
contab_downsampled[2,1]=(1-prob)*p01/(p00+p01)
contab_downsampled[2,2]=(1-prob)*p00/(p00+p01)
contab_downsampled
}
mut_excl_genes_generator2=function(cohort_size,incidence,or_pair1,or_pair2){
# or_pair1=.9
# or_pair2=.01
#
# incidence=40
# cohort_size=1000
or_p=or_pair2
or_q=or_pair1
q00=0.05
p00=0.05
###PC1 vs GOI pair###
p_goi=incidence/cohort_size
q10=(1-q00)-p_goi
q11=(p_goi*(1/q00)*or_q*((1-q00)-p_goi))/(1+(1/q00)*or_q*((1-q00)-p_goi))
q01=(p_goi)/(1+(1/q00)*or_q*((1-q00)-p_goi))
###PC1 vs PC2 pair###
p_pc1=q11+q10
p01=(1-p00)-p_pc1
p11=(p_pc1*(1/p00)*or_p*((1-p00)-p_pc1))/(1+((1/p00)*or_p*((1-p00)-p_pc1)))
p10=(p_pc1)/(1+(1/p00)*or_p*((1-p00)-p_pc1))
# gene_pair_1=(as.numeric(c(q11,q10,q01,q00)))
# gene_pair_2=(as.numeric(c(p11,p10,p01,p00)))
gene_pair_1=(as.numeric(c(q11,q01,q10,q00)))
gene_pair_2=(as.numeric(c(p11,p10,p01,p00)))
return(list(gene_pair_1,gene_pair_2))
}
# mut_excl_genes_generator2(500,12,.1,.05)
# mut_excl_genes_generator2(500,36,.1,.05)
# mut_excl_genes_generator(500,12,.1,.05)
# mut_excl_genes_generator(500,36,.1,.05)
Another function that takes in a contingency table, and resamples is based on its probabilities on a multinomial distribution. Number of resampling simulations are an input of the function
contab_simulator=function(contab,nsims,cohort_size){
contabs_resampled=rmultinom(nsims, #number of datasets to generate
cohort_size, #sample size of the total population
c(contab[1,1],
contab[1,2],
contab[2,1],
contab[2,2])) #probability of positive event
contabs_resampled_t=t(contabs_resampled)
colnames(contabs_resampled_t)=c("p11","p10","p01","p00")
contabs_resampled_t
}
# contab_simulator=function(contab,nsims,cohort_size){
# contabs_resampled=rmultinom(nsims, #number of datasets to generate
# 1, #sample size of the total population
# c(contab[1,1],
# contab[1,2],
# contab[2,1],
# contab[2,2])) #probability of positive event
# contabs_resampled_t=t(contabs_resampled)
# colnames(contabs_resampled_t)=c("p11","p10","p01","p00")
# contabs_resampled_t
# }
# contab=pc1pc2_contab_probabilities
# nsims=1000
# cohort_size=cohort_size_curr
# pc1rawpc2_contabs_sims=contab_simulator(pc1pc2_contab_probabilities,1000,cohort_size_curr)
# rm(list=ls())
###Not mutation specific generation of counts###
alldata_comp=alldata_compiler(alldata,nameposctrl1,nameposctrl2,namegene,'N',"N/A","N/A")[[2]]
head(alldata_comp)
X Patid Positive_Ctrl1 Positive_Ctrl2 genex rndmarray
1 1 TCGA-BF-A1PU 1 0 0 0
2 2 TCGA-BF-A1PV 0 1 0 1
3 3 TCGA-BF-A1PX 1 0 0 0
4 4 TCGA-BF-A1PZ 0 1 1 0
5 5 TCGA-BF-A1Q0 0 0 0 0
6 6 TCGA-BF-A3DJ 1 0 0 0
###Calculating Odds ratios and GOI frequencies for the raw data###
cohort_size=length(alldata_comp$Positive_Ctrl1)
pc1pc2_contab_counts=contab_maker(alldata_comp$Positive_Ctrl1,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
goipc1_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl1,alldata_comp)[2:1, 2:1]
###Had to add the 2:1 bits because the contab maker spits out NN YY whereas we wanted YNYN
goipc2_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
# pc1pc2_contab_counts=gene_pair_2_table
# goipc1_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl1,alldata_comp)[2:1, 2:1]
# goipc1_contab_counts=gene_pair_1_table
cohort_size_curr=cohort_size
# goipc2_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
pc1pc2_contab_probabilities=pc1pc2_contab_counts/cohort_size_curr
goipc1_contab_probabilities=goipc1_contab_counts/cohort_size_curr
goipc2_contab_probabilities=goipc2_contab_counts/cohort_size_curr
# pc1pc2_contab_probabilities=pc1pc2_contab_counts
# goipc1_contab_probabilities=goipc1_contab_counts
# goipc2_contab_probabilities=goipc2_contab_counts/cohort_size
or_pc1pc2=pc1pc2_contab_probabilities[1,1]*pc1pc2_contab_probabilities[2,2]/(pc1pc2_contab_probabilities[1,2]*pc1pc2_contab_probabilities[2,1])
or_goipc1=goipc1_contab_probabilities[1,1]*goipc1_contab_probabilities[2,2]/(goipc1_contab_probabilities[1,2]*goipc1_contab_probabilities[2,1])
or_goipc2=goipc2_contab_probabilities[1,1]*goipc2_contab_probabilities[2,2]/(goipc2_contab_probabilities[1,2]*goipc2_contab_probabilities[2,1])
goi_freq=goipc1_contab_probabilities[1,1]+goipc1_contab_probabilities[1,2]
goi_freq=.25
# class(goi_freq)
###
###Downsampling PC1 to the probability of GOI without changing ORs###
###The function below converts contingency table data to a new contingency table in which the data is downsampled to the desired frequency, aka the frequency of the GOI in this case###
pc1new_pc2_contab=contab_downsampler(pc1pc2_contab_probabilities,goi_freq)
goinew_pc1_contab=contab_downsampler(goipc1_contab_probabilities,goi_freq)
goinew_pc2_contab=contab_downsampler(goipc2_contab_probabilities,goi_freq)
##original contab:
head(pc1pc2_contab_probabilities)
[,1] [,2]
[1,] 0.01424501 0.4985755
[2,] 0.25925926 0.2279202
###downsampled contab:
head(pc1new_pc2_contab)
[,1] [,2]
[1,] 0.006944444 0.2430556
[2,] 0.399122807 0.3508772
pc1rawpc2_contabs_sims=contab_simulator(pc1pc2_contab_probabilities,1000,cohort_size_curr)
pc1pc2_contabs_sims=contab_simulator(pc1new_pc2_contab,1000,cohort_size_curr)
goipc1_contabs_sims=contab_simulator(goinew_pc1_contab,1000,cohort_size_curr)
goipc2_contabs_sims=contab_simulator(goinew_pc2_contab,1000,cohort_size_curr)
# goipc2_contabs_sims=contab_simulator(goinew_pc2_contab,1000,cohort_size)
# head(pc1pc2_contabs_sims) #each row in this dataset is a new contab
pc1rawpc2_contabs_sims=data.frame(pc1rawpc2_contabs_sims)
pc1rawpc2_contabs_sims=pc1rawpc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
pc1pc2_contabs_sims=data.frame(pc1pc2_contabs_sims)
pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
goipc1_contabs_sims=data.frame(goipc1_contabs_sims)
goipc1_contabs_sims=goipc1_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
goipc2_contabs_sims=data.frame(goipc2_contabs_sims)
goipc2_contabs_sims=goipc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
# goipc2_contabs_sims=data.frame(goipc2_contabs_sims)
# goipc2_contabs_sims=goipc2_contabs_sims%>%
# mutate(or=p11*p00/(p10*p01))
pc1rawpc2_contabs_sims$comparison="pc1rawpc2"
pc1pc2_contabs_sims$comparison="pc1pc2"
goipc1_contabs_sims$comparison="goipc1"
goipc2_contabs_sims$comparison="goipc2"
or_median_raw=quantile(pc1rawpc2_contabs_sims$or,na.rm = T)[3]
or_uq_raw=quantile(pc1rawpc2_contabs_sims$or,na.rm = T)[4]
or_median_downsampled=quantile(pc1pc2_contabs_sims$or,na.rm = T)[3]
or_uq_downsampled=quantile(pc1pc2_contabs_sims$or,na.rm = T)[4]
pc1rawpc2_contabs_sims=pc1rawpc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
goipc1_contabs_sims=goipc1_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
goipc2_contabs_sims=goipc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
# pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
# goipc1_contabs_sims=goipc1_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
# goipc2_contabs_sims=goipc2_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
pc1rawpc2_isgreater_raw_median=sum(pc1rawpc2_contabs_sims$isgreater_raw_median)
pc1rawpc2_isgreater_raw_uq=sum(pc1rawpc2_contabs_sims$isgreater_raw_uq)
pc1rawpc2_isgreater_median=sum(pc1rawpc2_contabs_sims$isgreater_median)
pc1rawpc2_isgreater_uq=sum(pc1rawpc2_contabs_sims$isgreater_uq)
pc1pc2_isgreater_raw_median=sum(pc1pc2_contabs_sims$isgreater_raw_median)
pc1pc2_isgreater_raw_uq=sum(pc1pc2_contabs_sims$isgreater_raw_uq)
pc1pc2_isgreater_median=sum(pc1pc2_contabs_sims$isgreater_median)
pc1pc2_isgreater_uq=sum(pc1pc2_contabs_sims$isgreater_uq)
goipc1_isgreater_raw_median=sum(goipc1_contabs_sims$isgreater_raw_median)
goipc1_isgreater_raw_uq=sum(goipc1_contabs_sims$isgreater_raw_uq)
goipc1_isgreater_median=sum(goipc1_contabs_sims$isgreater_median)
goipc1_isgreater_uq=sum(goipc1_contabs_sims$isgreater_uq)
plotting_df=rbind(pc1pc2_contabs_sims,goipc1_contabs_sims,goipc2_contabs_sims)
# plotting_df=rbind(pc1pc2_contabs_sims,goipc1_contabs_sims)
#
ggplot(plotting_df,aes(x=(or),fill=comparison))+
geom_histogram(bins=40,alpha=0.55,position="identity")+
# geom_histogram(bins=50,alpha=0.55)+
scale_y_continuous(expand=c(0,0),name="Count")+
scale_x_continuous(expand=c(0,0),trans="log10",name="Odds Ratio")+
scale_fill_brewer(palette="Set2")+
# geom_vline(xintercept = or_pc1pc2)+
cleanup
Warning: Transformation introduced infinite values in continuous x-axis
Warning: Removed 86 rows containing non-finite values (stat_bin).
ggplot(plotting_df,aes(y=(or),x=comparison),fill=factor(comparison))+
geom_boxplot()+
scale_y_continuous(name="Odds Ratio",trans="log10")+
scale_x_discrete(name="")+
scale_fill_brewer(palette="Set2")+
geom_hline(yintercept = or_uq_downsampled,linetype="dashed")+
cleanup+
theme(legend.position = "none",
axis.ticks.x = element_blank())
Warning: Transformation introduced infinite values in continuous y-axis
Warning: Removed 86 rows containing non-finite values (stat_boxplot).
# ggsave("paircon_boxplot.pdf",width = 3,height=2,units="in",useDingbats=F)
ggplot(plotting_df%>%filter(comparison%in%"pc1pc2"),aes(x=or,fill=comparison))+
geom_histogram(bins=50,alpha=0.55,position="identity")+
geom_density(alpha=.6)+
scale_y_continuous(expand=c(0,0),name="Count")+
scale_x_continuous(expand=c(0,0),name="Odds Ratio")+
# geom_vline(xintercept = or_pc1pc2)+
cleanup
# rm(list=ls())
###Not mutation specific generation of counts###
alldata_comp=alldata_compiler(alldata,nameposctrl1,nameposctrl2,namegene,'N',"N/A","N/A")[[2]]
###Mutation specific
####Decided to not look at mutation specific counts too closely because co-occurrence of brafv600e and nrasq61L is a VERY high bar
# alldata_comp=alldata_compiler(alldata,nameposctrl1,nameposctrl2,namegene,'Y',"V600E","Q61L")[[2]]
head(alldata_comp)
X Patid Positive_Ctrl1 Positive_Ctrl2 genex rndmarray
1 1 TCGA-BF-A1PU 1 0 0 0
2 2 TCGA-BF-A1PV 0 1 0 1
3 3 TCGA-BF-A1PX 1 0 0 0
4 4 TCGA-BF-A1PZ 0 1 1 0
5 5 TCGA-BF-A1Q0 0 0 0 0
6 6 TCGA-BF-A3DJ 1 0 0 0
###Calculating Odds ratios and GOI frequencies for the raw data###
cohort_size=length(alldata_comp$Positive_Ctrl1)
pc1pc2_contab_counts=contab_maker(alldata_comp$Positive_Ctrl1,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
pc1pc2_contab_counts=rbind(c(15,25),c(81,230)) ###NRAS ATI
goipc1_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl1,alldata_comp)[2:1, 2:1]
# goipc1_contab_counts=rbind(c(1,110),c(186,365)) ###EGFR KRAS
fisher.test(goipc1_contab_counts)
Fisher's Exact Test for Count Data
data: goipc1_contab_counts
p-value = 0.4071
alternative hypothesis: true odds ratio is not equal to 1
95 percent confidence interval:
0.365048 1.535988
sample estimates:
odds ratio
0.7531399
###Had to add the 2:1 bits because the contab maker spits out NN YY whereas we wanted YNYN
goipc2_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
# pc1pc2_contab_counts=gene_pair_2_table
# goipc1_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl1,alldata_comp)[2:1, 2:1]
# goipc1_contab_counts=gene_pair_1_table
cohort_size_curr=cohort_size
# goipc2_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
pc1pc2_contab_probabilities=pc1pc2_contab_counts/cohort_size_curr
goipc1_contab_probabilities=goipc1_contab_counts/cohort_size_curr
goipc2_contab_probabilities=goipc2_contab_counts/cohort_size_curr
# pc1pc2_contab_probabilities=pc1pc2_contab_counts
# goipc1_contab_probabilities=goipc1_contab_counts
# goipc2_contab_probabilities=goipc2_contab_counts/cohort_size
or_pc1pc2=pc1pc2_contab_probabilities[1,1]*pc1pc2_contab_probabilities[2,2]/(pc1pc2_contab_probabilities[1,2]*pc1pc2_contab_probabilities[2,1])
or_goipc1=goipc1_contab_probabilities[1,1]*goipc1_contab_probabilities[2,2]/(goipc1_contab_probabilities[1,2]*goipc1_contab_probabilities[2,1])
or_goipc2=goipc2_contab_probabilities[1,1]*goipc2_contab_probabilities[2,2]/(goipc2_contab_probabilities[1,2]*goipc2_contab_probabilities[2,1])
goi_freq=goipc1_contab_probabilities[1,1]+goipc1_contab_probabilities[1,2]
# goi_freq=.25
# class(goi_freq)
###
###Downsampling PC1 to the probability of GOI without changing ORs###
###The function below converts contingency table data to a new contingency table in which the data is downsampled to the desired frequency, aka the frequency of the GOI in this case###
pc1new_pc2_contab=contab_downsampler(pc1pc2_contab_probabilities,goi_freq)
goinew_pc1_contab=contab_downsampler(goipc1_contab_probabilities,goi_freq)
goinew_pc2_contab=contab_downsampler(goipc2_contab_probabilities,goi_freq)
##original contab:
head(pc1pc2_contab_probabilities)
[,1] [,2]
[1,] 0.04273504 0.07122507
[2,] 0.23076923 0.65527066
###downsampled contab:
head(pc1new_pc2_contab)
[,1] [,2]
[1,] 0.04273504 0.07122507
[2,] 0.23076923 0.65527066
pc1rawpc2_contabs_sims=contab_simulator(pc1pc2_contab_probabilities,1000,cohort_size_curr)
pc1pc2_contabs_sims=contab_simulator(pc1new_pc2_contab,1000,cohort_size_curr)
goipc1_contabs_sims=contab_simulator(goinew_pc1_contab,1000,cohort_size_curr)
goipc2_contabs_sims=contab_simulator(goinew_pc2_contab,1000,cohort_size_curr)
# goipc2_contabs_sims=contab_simulator(goinew_pc2_contab,1000,cohort_size)
# head(pc1pc2_contabs_sims) #each row in this dataset is a new contab
pc1rawpc2_contabs_sims=data.frame(pc1rawpc2_contabs_sims)
pc1rawpc2_contabs_sims=pc1rawpc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
pc1pc2_contabs_sims=data.frame(pc1pc2_contabs_sims)
pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
goipc1_contabs_sims=data.frame(goipc1_contabs_sims)
goipc1_contabs_sims=goipc1_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
goipc2_contabs_sims=data.frame(goipc2_contabs_sims)
goipc2_contabs_sims=goipc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
# goipc2_contabs_sims=data.frame(goipc2_contabs_sims)
# goipc2_contabs_sims=goipc2_contabs_sims%>%
# mutate(or=p11*p00/(p10*p01))
pc1rawpc2_contabs_sims$comparison="pc1rawpc2"
pc1pc2_contabs_sims$comparison="pc1pc2"
goipc1_contabs_sims$comparison="goipc1"
goipc2_contabs_sims$comparison="goipc2"
or_median_raw=quantile(pc1rawpc2_contabs_sims$or,na.rm = T)[3]
or_uq_raw=quantile(pc1rawpc2_contabs_sims$or,na.rm = T)[4]
or_median_downsampled=quantile(pc1pc2_contabs_sims$or,na.rm = T)[3]
or_uq_downsampled=quantile(pc1pc2_contabs_sims$or,na.rm = T)[4]
pc1rawpc2_contabs_sims=pc1rawpc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>=or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
goipc1_contabs_sims=goipc1_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
goipc2_contabs_sims=goipc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
# pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
# goipc1_contabs_sims=goipc1_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
# goipc2_contabs_sims=goipc2_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
pc1rawpc2_isgreater_raw_median=sum(pc1rawpc2_contabs_sims$isgreater_raw_median)
pc1rawpc2_isgreater_raw_uq=sum(pc1rawpc2_contabs_sims$isgreater_raw_uq)
pc1rawpc2_isgreater_median=sum(pc1rawpc2_contabs_sims$isgreater_median)
pc1rawpc2_isgreater_uq=sum(pc1rawpc2_contabs_sims$isgreater_uq)
pc1pc2_isgreater_raw_median=sum(pc1pc2_contabs_sims$isgreater_raw_median)
pc1pc2_isgreater_raw_uq=sum(pc1pc2_contabs_sims$isgreater_raw_uq)
pc1pc2_isgreater_median=sum(pc1pc2_contabs_sims$isgreater_median)
pc1pc2_isgreater_uq=sum(pc1pc2_contabs_sims$isgreater_uq)
goipc1_isgreater_raw_median=sum(goipc1_contabs_sims$isgreater_raw_median)
goipc1_isgreater_raw_uq=sum(goipc1_contabs_sims$isgreater_raw_uq)
goipc1_isgreater_median=sum(goipc1_contabs_sims$isgreater_median)
goipc1_isgreater_uq=sum(goipc1_contabs_sims$isgreater_uq)
plotting_df=rbind(pc1pc2_contabs_sims,goipc1_contabs_sims,goipc2_contabs_sims)
# plotting_df=rbind(pc1pc2_contabs_sims,goipc1_contabs_sims)
#
# a=plotting_df%>%filter(comparison%in%"pc1pc2")
ggplot(plotting_df,aes(x=(or),fill=comparison))+
geom_histogram(bins=40,alpha=0.55,position="identity")+
# geom_histogram(bins=50,alpha=0.55)+
scale_y_continuous(expand=c(0,0),name="Count")+
scale_x_continuous(expand=c(0,0),trans="log10",name="Odds Ratio")+
scale_fill_brewer(palette="Set2")+
# geom_vline(xintercept = or_pc1pc2)+
cleanup
ggplot(plotting_df,aes(y=(or),x=comparison),fill=factor(comparison))+
geom_boxplot()+
scale_y_continuous(name="Odds Ratio",trans="log10")+
scale_x_discrete(name="")+
scale_fill_brewer(palette="Set2")+
geom_hline(yintercept = or_uq_downsampled,linetype="dashed")+
cleanup+
theme(legend.position = "none",
axis.ticks.x = element_blank())
ggsave("paircon_boxplot_alkati.pdf",width = 3,height=2,units="in",useDingbats=F)
ggplot(plotting_df%>%filter(comparison%in%"pc1pc2"),aes(x=or,fill=comparison))+
geom_histogram(bins=50,alpha=0.55,position="identity")+
geom_density(alpha=.6)+
scale_y_continuous(expand=c(0,0),name="Count")+
scale_x_continuous(expand=c(0,0),name="Odds Ratio")+
# geom_vline(xintercept = or_pc1pc2)+
cleanup
# rm(list=ls())
or_pair1=c(.01,.05,.1,.2,.3,.4,.5,.6,.7,.8,.9,1)
or_pair2=seq(.01,.2,by=.02)
incidence=seq(4,36,by=2)
cohort_size=seq(100,1000,by=200)
# or_pair1=c(.01,.05)
# or_pair2=seq(.01,.1,by=.05)
# incidence=seq(4,36,by=20)
# cohort_size=seq(100,1000,by=400)
# or_pair1=.05
# or_pair2=.01
# incidence=12
# cohort_size=500
# i=1
# j=1
# k=1
# l=1
true_or_vals=or_pair1
cohort_size_vals=cohort_size
gene1_total_vals=incidence
simresults_compiled_alldata=as.list(length(or_pair2)*length(or_pair1)*length(incidence)*length(cohort_size))
simresults_compiled=matrix(,length(or_pair2)*length(or_pair1)*length(incidence)*length(cohort_size),ncol=16)
ct=1
for(j in 1:length(incidence)){
tic()
for(l in 1:length(or_pair2)){
for(k in 1:length(cohort_size_vals)){
for(i in 1:length(true_or_vals)){
gene_pair_1=unlist(mut_excl_genes_generator(cohort_size[k],incidence[j],or_pair1[i],or_pair2[l])[1])
gene_pair_1_table=rbind(c(gene_pair_1[1],gene_pair_1[2]),c(gene_pair_1[3],gene_pair_1[4])) ###make sure these are the right indices
gene_pair_2=unlist(mut_excl_genes_generator(cohort_size[k],incidence[j],or_pair1[i],or_pair2[l])[2])
gene_pair_2_table=rbind(c(gene_pair_2[1],gene_pair_2[2]),c(gene_pair_2[3],gene_pair_2[4]))
# alldata_1=mut_excl_genes_datapoints(gene_pair_1)
#
# alldata_2=mut_excl_genes_datapoints(gene_pair_2)
# alldata_comp_1=alldata_compiler(alldata_1,"gene2","gene3","gene1",'N',"N/A","N/A")[[2]]
#
# genex_replication_prop_1=alldata_compiler(alldata_1,"gene2","gene3","gene1",'N',"N/A","N/A")[[1]]
# alldata_comp_2=alldata_compiler(alldata_2,"gene2","gene3","gene1",'N',"N/A","N/A")[[2]]
# genex_replication_prop_2=alldata_compiler(alldata_2,"gene2","gene3","gene1",'N',"N/A","N/A")[[1]]
###Calculating Odds ratios and GOI frequencies for the raw data###
# cohort_size_curr=length(alldata_comp$Positive_Ctrl1)
cohort_size_curr=cohort_size[k]
# pc1pc2_contab_counts=contab_maker(alldata_comp$Positive_Ctrl1,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
pc1pc2_contab_counts=gene_pair_2_table
# goipc1_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl1,alldata_comp)[2:1, 2:1]
goipc1_contab_counts=gene_pair_1_table
# goipc2_contab_counts=contab_maker(alldata_comp$genex,alldata_comp$Positive_Ctrl2,alldata_comp)[2:1, 2:1]
# pc1pc2_contab_probabilities=pc1pc2_contab_counts/cohort_size_curr
# goipc1_contab_probabilities=goipc1_contab_counts/cohort_size_curr
pc1pc2_contab_probabilities=pc1pc2_contab_counts
goipc1_contab_probabilities=goipc1_contab_counts
# goipc2_contab_probabilities=goipc2_contab_counts/cohort_size
or_pc1pc2=pc1pc2_contab_probabilities[1,1]*pc1pc2_contab_probabilities[2,2]/(pc1pc2_contab_probabilities[1,2]*pc1pc2_contab_probabilities[2,1])
or_goipc1=goipc1_contab_probabilities[1,1]*goipc1_contab_probabilities[2,2]/(goipc1_contab_probabilities[1,2]*goipc1_contab_probabilities[2,1])
# or_goipc2=goipc2_contab_probabilities[1,1]*goipc2_contab_probabilities[2,2]/(goipc2_contab_probabilities[1,2]*goipc2_contab_probabilities[2,1])
goi_freq=goipc1_contab_probabilities[1,1]+goipc1_contab_probabilities[1,2]
# goi_freq=.01
# class(goi_freq)
###
###Downsampling PC1 to the probability of GOI without changing ORs###
###The function below converts contingency table data to a new contingency table in which the data is downsampled to the desired frequency, aka the frequency of the GOI in this case###
pc1new_pc2_contab=contab_downsampler(pc1pc2_contab_probabilities,goi_freq)
goinew_pc1_contab=contab_downsampler(goipc1_contab_probabilities,goi_freq)
# goinew_pc2_contab=contab_downsampler(goipc2_contab_probabilities,goi_freq)
###original contab:
# head(pc1pc2_contab_probabilities)
###downsampled contab:
# head(pc1new_pc2_contab)
pc1rawpc2_contabs_sims=contab_simulator(pc1pc2_contab_probabilities,1000,cohort_size_curr)
pc1pc2_contabs_sims=contab_simulator(pc1new_pc2_contab,1000,cohort_size_curr)
goipc1_contabs_sims=contab_simulator(goinew_pc1_contab,1000,cohort_size_curr)
# goipc2_contabs_sims=contab_simulator(goinew_pc2_contab,1000,cohort_size)
# head(pc1pc2_contabs_sims) #each row in this dataset is a new contab
pc1rawpc2_contabs_sims=data.frame(pc1rawpc2_contabs_sims)
pc1rawpc2_contabs_sims=pc1rawpc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
pc1pc2_contabs_sims=data.frame(pc1pc2_contabs_sims)
pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
goipc1_contabs_sims=data.frame(goipc1_contabs_sims)
goipc1_contabs_sims=goipc1_contabs_sims%>%
mutate(or=p11*p00/(p10*p01))
# goipc2_contabs_sims=data.frame(goipc2_contabs_sims)
# goipc2_contabs_sims=goipc2_contabs_sims%>%
# mutate(or=p11*p00/(p10*p01))
pc1rawpc2_contabs_sims$comparison="pc1rawpc2"
pc1pc2_contabs_sims$comparison="pc1pc2"
goipc1_contabs_sims$comparison="goipc1"
# goipc2_contabs_sims$comparison="goipc2"
or_median_raw=quantile(pc1rawpc2_contabs_sims$or,na.rm = T)[3]
or_uq_raw=quantile(pc1rawpc2_contabs_sims$or,na.rm = T)[4]
or_median_downsampled=quantile(pc1pc2_contabs_sims$or,na.rm = T)[3]
or_uq_downsampled=quantile(pc1pc2_contabs_sims$or,na.rm = T)[4]
# pc1rawpc2_contabs_sims=pc1rawpc2_contabs_sims%>%
# mutate(isgreater_raw_median=case_when(or>=or_median_raw~1,
# TRUE~0),
# isgreater_raw_uq=case_when(or>=or_uq_raw~1,
# TRUE~0),
# isgreater_median=case_when(or>=or_median_downsampled~1,
# TRUE~0),
# isgreater_uq=case_when(or>=or_uq_downsampled~1,
# TRUE~0)
# )
# pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
# mutate(isgreater_raw_median=case_when(or>=or_median_raw~1,
# TRUE~0),
# isgreater_raw_uq=case_when(or>=or_uq_raw~1,
# TRUE~0),
# isgreater_median=case_when(or>=or_median_downsampled~1,
# TRUE~0),
# isgreater_uq=case_when(or>=or_uq_downsampled~1,
# TRUE~0)
# )
# goipc1_contabs_sims=goipc1_contabs_sims%>%
# mutate(isgreater_raw_median=case_when(or>=or_median_raw~1,
# TRUE~0),
# isgreater_raw_uq=case_when(or>=or_uq_raw~1,
# TRUE~0),
# isgreater_median=case_when(or>=or_median_downsampled~1,
# TRUE~0),
# isgreater_uq=case_when(or>=or_uq_downsampled~1,
# TRUE~0)
# )
pc1rawpc2_contabs_sims=pc1rawpc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>=or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>=or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
goipc1_contabs_sims=goipc1_contabs_sims%>%
mutate(isgreater_raw_median=case_when(or>or_median_raw~1,
TRUE~0),
isgreater_raw_uq=case_when(or>or_uq_raw~1,
TRUE~0),
isgreater_median=case_when(or>or_median_downsampled~1,
TRUE~0),
isgreater_uq=case_when(or>or_uq_downsampled~1,
TRUE~0)
)
# pc1pc2_contabs_sims=pc1pc2_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
# goipc1_contabs_sims=goipc1_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
# goipc2_contabs_sims=goipc2_contabs_sims%>%
# mutate(isgreater=case_when(or>=or_pc1pc2~1,
# TRUE~0))
pc1rawpc2_isgreater_raw_median=sum(pc1rawpc2_contabs_sims$isgreater_raw_median)
pc1rawpc2_isgreater_raw_uq=sum(pc1rawpc2_contabs_sims$isgreater_raw_uq)
pc1rawpc2_isgreater_median=sum(pc1rawpc2_contabs_sims$isgreater_median)
pc1rawpc2_isgreater_uq=sum(pc1rawpc2_contabs_sims$isgreater_uq)
pc1pc2_isgreater_raw_median=sum(pc1pc2_contabs_sims$isgreater_raw_median)
pc1pc2_isgreater_raw_uq=sum(pc1pc2_contabs_sims$isgreater_raw_uq)
pc1pc2_isgreater_median=sum(pc1pc2_contabs_sims$isgreater_median)
pc1pc2_isgreater_uq=sum(pc1pc2_contabs_sims$isgreater_uq)
goipc1_isgreater_raw_median=sum(goipc1_contabs_sims$isgreater_raw_median)
goipc1_isgreater_raw_uq=sum(goipc1_contabs_sims$isgreater_raw_uq)
goipc1_isgreater_median=sum(goipc1_contabs_sims$isgreater_median)
goipc1_isgreater_uq=sum(goipc1_contabs_sims$isgreater_uq)
# pc1rawpc2_isgreater=sum(pc1rawpc2_contabs_sims$isgreater)
# pc1pc2_isgreater=sum(pc1pc2_contabs_sims$isgreater)
# goipc1_isgreater=sum(goipc1_contabs_sims$isgreater)
simresults=c(cohort_size[k],
incidence[j],
or_pair1[i],
or_pair2[l],
pc1rawpc2_isgreater_raw_median,
pc1rawpc2_isgreater_raw_uq,
pc1rawpc2_isgreater_median,
pc1rawpc2_isgreater_uq,
pc1pc2_isgreater_raw_median,
pc1pc2_isgreater_raw_uq,
pc1pc2_isgreater_median,
pc1pc2_isgreater_uq,
goipc1_isgreater_raw_median,
goipc1_isgreater_raw_uq,
goipc1_isgreater_median,
goipc1_isgreater_uq)
simresults_alldata=c(cohort_size[k],
incidence[j],
or_pair1[i],
or_pair2[l],
list(goipc1_contabs_sims$or),
list(pc1pc2_contabs_sims$or))
######Comment out this section to not gather all the 1,000 ORs for each simulation####
simresults_compiled_alldata[[ct]]=simresults_alldata
# a=simresults_compiled_alldata[[1]]
simresults_compiled[ct,]=simresults
ct=ct+1
}
}
}
toc()
}
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simresults_compiled=data.frame(simresults_compiled)
colnames(simresults_compiled)=c("cohort_size",
"incidence",
"or1",
"or2",
"pc1rawpc2_isgreater_raw_median",
"pc1rawpc2_isgreater_raw_uq",
"pc1rawpc2_isgreater_median",
"pc1rawpc2_isgreater_uq",
"pc1pc2_isgreater_raw_median",
"pc1pc2_isgreater_raw_uq",
"pc1pc2_isgreater_median",
"pc1pc2_isgreater_uq",
"goipc1_isgreater_raw_median",
"goipc1_isgreater_raw_uq",
"goipc1_isgreater_median",
"goipc1_isgreater_uq")
simresults_compiled$delta_median=simresults_compiled$goipc1_isgreater_raw_median-simresults_compiled$goipc1_isgreater_median
simresults_compiled$delta_uq=simresults_compiled$goipc1_isgreater_raw_uq-simresults_compiled$goipc1_isgreater_uq
simresults_compiled=simresults_compiled%>%
mutate(fp_corrected_95=case_when(
goipc1_isgreater_raw_uq<950~-1,
(goipc1_isgreater_raw_uq>=950&(goipc1_isgreater_raw_uq-delta_uq)<=950)~1,
TRUE~0),
fp_corrected_99=case_when(
goipc1_isgreater_raw_uq<990~-1,
(goipc1_isgreater_raw_uq>=990&(goipc1_isgreater_raw_uq-delta_uq)<=990)~1,
TRUE~0))
# simresults_compiled$goipc1_isgreater_percent=simresults_compiled$goipc1_isgreater*100/1000
simresults_subset=simresults_compiled%>%filter(cohort_size%in%500)
ggplot(simresults_compiled%>%filter(or1<=.4),aes(x=incidence,y=or2))+geom_tile(aes(fill=goipc1_isgreater_median/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")
ggplot(simresults_compiled%>%filter(or1<=.4),aes(x=incidence,y=or2))+geom_tile(aes(fill=goipc1_isgreater_raw_median/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Percent succesful trials")
ggplot(simresults_compiled%>%filter(or1<=.4),aes(x=incidence,y=or2))+geom_tile(aes(fill=goipc1_isgreater_uq/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Percent succesful trials")
ggplot(simresults_compiled%>%filter(or1<=.4),aes(x=incidence,y=or2))+geom_tile(aes(fill=goipc1_isgreater_raw_uq/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Percent succesful trials")
ggplot(simresults_compiled%>%filter(or1<=.7,or1>=.2),aes(x=incidence,y=or2))+geom_tile(aes(fill=delta_median))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",high ="blue",name="Delta bw raw and downsampled")
ggplot(simresults_compiled%>%filter(or1<=.7,or1>=.2),aes(x=incidence,y=or2))+geom_tile(aes(fill=delta_uq))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",high ="blue",name="Delta bw raw and downsampled")
ggplot(simresults_compiled%>%filter(or1<=.7,or1>=.2),aes(x=incidence,y=or2))+geom_tile(color="black",aes(fill=fp_corrected_95))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",high ="blue",name="Regions where downsampling helps")
ggplot(simresults_compiled%>%filter(or1<=.7,or1>=.2),aes(x=incidence,y=or2))+geom_tile(color="black",aes(fill=fp_corrected_99))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",high ="blue",name="Regions where downsampling helps")
ggplot(simresults_compiled%>%filter(or1<=.4),aes(x=incidence,y=or2))+geom_tile(aes(fill=goipc1_isgreater_median/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")
ggplot(simresults_compiled%>%filter(or1<=.4,cohort_size%in%500),aes(x=incidence,y=or2))+geom_tile(aes(fill=goipc1_isgreater_median/10))+facet_wrap(~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")
ggplot(simresults_compiled%>%filter(or1<=.4,cohort_size%in%500),aes(x=incidence,y=or2))+geom_tile(aes(fill=goipc1_isgreater_median/10))+facet_wrap(~or1,ncol=6)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")
ggplot(simresults_compiled%>%filter(or1%in%c(.05,0.1,.5),cohort_size%in%500),aes(x=incidence,y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_median/10))+facet_wrap(~or1,ncol=6)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_continuous(expand = c(0,0),name="Incidence")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1vsPC2")+ggtitle("Odds ratio of GOIvsPC1")+
theme(plot.title = element_text(hjust = 0.5))
# ggsave("score_heatmap.pdf",width=8,heigh=3,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(or1%in%c(.05,0.1,.5),cohort_size%in%c(100,500,900)),aes(x=incidence,y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_median/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_continuous(expand = c(0,0),name="Incidence")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1vsPC2")+ggtitle("Odds ratio of GOIvsPC1")+
theme(plot.title = element_text(hjust = 0.5))
# ggsave("score_heatmap_supplement.pdf",width=8,heigh=7,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(or2%in%.05,cohort_size%in%c(500)),aes(x=factor(or1),y=goipc1_isgreater_median/10))+geom_boxplot()+scale_x_discrete(name="Odds ratio of PC1vsPC2")+
scale_y_continuous(name="Score")+
theme(plot.title = element_text(hjust = 0.5))+cleanup
# ggsave("score_plot.pdf",width=8,heigh=3,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(incidence%in%c(6,16,26,36),cohort_size%in%c(100,300,500,900)),aes(x=factor(or1),y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_uq/10))+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Odds ratio of GOI and PC1")+facet_grid(cohort_size~incidence)+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(plot.title = element_text(hjust = 0.5))
ggplot(simresults_compiled%>%filter(incidence%in%c(6,16,26,36),cohort_size%in%500),aes(x=factor(or1),y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_uq/10))+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Odds ratio of GOI and PC1")+facet_wrap(~incidence,ncol=4)+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(plot.title = element_text(hjust = 0.5),axis.text.x=element_text(angle=90,hjust=.5,vjust=.5),axis.text=element_text(face="bold",size="9",color="black"))
# ggsave("score_heatmap_bestoption1.pdf",width=8,heigh=2.5,units="in",useDingbats=F)
# sort(unique(simresults_compiled$or2))
ggplot(simresults_compiled%>%filter(cohort_size%in%500),aes(x=factor(or1),y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_median/10))+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Odds ratio of GOI and PC1")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(plot.title = element_text(hjust = 0.5))
# ggsave("score_heatmap_bestoption.pdf",width=4,heigh=3,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(or1%in%.3,or2%in%.09),aes(x=incidence/cohort_size,y=goipc1_isgreater_median/10))+geom_point()
ggplot(simresults_compiled%>%filter(or1%in%.1,or2%in%.05,cohort_size%in%500),aes(x=incidence,y=goipc1_isgreater_median/10))+geom_point()
# scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Odds ratio of GOI and PC1")+
# scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(plot.title = element_text(hjust = 0.5))
# or1%in%c(.05,0.1,.5),cohort_size%in%c(100,500,900)
ggplot(simresults_compiled%>%filter(cohort_size%in%c(100,300,500)),aes(x=incidence,y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_median/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_continuous(expand = c(0,0),name="Incidence")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1vsPC2")+ggtitle("Odds ratio of GOIvsPC1")+
theme(plot.title = element_text(hjust = 0.5))
Choosing plots for putting in paper
ggplot(simresults_compiled%>%filter(cohort_size%in%500),aes(x=factor(or1),y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_uq/10))+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Odds ratio of GOI and PC1")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(plot.title = element_text(hjust = 0.5))+theme(plot.title = element_text(hjust = 0.5),axis.text.x=element_text(angle=90,hjust=.5,vjust=.5),axis.text=element_text(face="bold",size="9",color="black"))
# ggsave("score_heatmap_bestoption.pdf",width=4,heigh=3,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(or1%in%c(.05,.3,.6),incidence%in%c(4,8,12,16,20,24,28,32,36),cohort_size%in%500),aes(x=factor(incidence),y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_median/10))+facet_wrap(~or1,ncol=6)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Incidence")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(strip.text=element_blank(),plot.title = element_text(hjust = 0.5),axis.text.x=element_text(angle=90,hjust=.5,vjust=.5),axis.text=element_text(face="bold",size="9",color="black"),legend.position = "none")
# ggsave("score_heatmap_bestoption1.pdf",width=6,heigh=2.5,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(or1%in%c(.1,.2,.5),incidence%in%c(4,8,12,16,20,24,28,32,36),cohort_size%in%500),aes(x=factor(incidence),y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_raw_median/10))+facet_wrap(~or1,ncol=6)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Incidence")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(strip.text=element_blank(),plot.title = element_text(hjust = 0.5),axis.text.x=element_text(angle=90,hjust=.5,vjust=.5),axis.text=element_text(face="bold",size="9",color="black"),legend.position = "none")
# ggsave("score_heatmap_bestoption1.pdf",width=6,heigh=2.5,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(cohort_size%in%500,incidence%in%c(4,8,12,16,20,24,28,32,36)),aes(x=factor(incidence),y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_raw_median/10))+facet_wrap(~or1,ncol=4)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Incidence")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")+theme(plot.title = element_text(hjust = 0.5),axis.text.x=element_text(angle=90,hjust=.5,vjust=.5),axis.text=element_text(face="bold",size="9",color="black"),legend.position = "none")
# ggsave("score_heatmap_bestoption1_supplement.pdf",width=6,heigh=6,units="in",useDingbats=F)
ggplot(simresults_compiled%>%filter(or1%in%c(.05,.1,.5),cohort_size%in%c(100,300,500)),aes(x=incidence,y=or2))+geom_tile(color="black",aes(fill=goipc1_isgreater_median/10))+facet_grid(cohort_size~or1)+scale_fill_gradient2(low ="red" ,mid ="white",midpoint=50,high ="blue",name="Score")+scale_x_discrete(expand = c(0,0),name="Incidence")+
scale_y_continuous(expand = c(0,0),name="Odds ratio of PC1 and PC2")
# a=simresults_compiled%>%filter(cohort_size%in%500,or1%in%.7,or2%in%.05,incidence%in%)
# simresults_subset=simresults_compiled%>%filter(or2%in%0.01,or1%in%c(0.01,.1,1))
simresults_subset=unlist(simresults_compiled_alldata)
simresults_unlisted=data.frame(unlist(lapply(simresults_compiled_alldata,'[[',1)),
unlist(lapply(simresults_compiled_alldata,'[[',2)),
unlist(lapply(simresults_compiled_alldata,'[[',3)),
unlist(lapply(simresults_compiled_alldata,'[[',4)))
simresults_unlisted$list1=(lapply(simresults_compiled_alldata,'[[',5))
simresults_unlisted$list2=(lapply(simresults_compiled_alldata,'[[',6))
colnames(simresults_unlisted)=c("cohort_size","incidence","or1","or2","or1_list","or2_list")
simresults_unlisted=simresults_unlisted%>%filter(or2%in%0.01,or1%in%c(0.05,.1,1),cohort_size%in%500,incidence%in%c(4,8,12,16,20))
# library(reshape2)
a=simresults_unlisted%>%filter(incidence%in%8,or2%in%0.01,or1%in%.05)
# b=unnest(a)
median(b$or2_list)>median(b$or1_list)
library(tidyr)
simresults_melted=unnest(simresults_unlisted)
simresults_melted2=melt(simresults_melted,
id.vars = c("cohort_size","or1","or2","incidence"),
measure.vars =c("or1_list","or2_list"),
variable.name = "Comparison",
value.name = "OR"
)
ggplot(simresults_melted2,aes(x=factor(incidence),y=OR,fill=Comparison))+facet_wrap(~or1)+geom_boxplot()+scale_y_continuous(trans="log2")+cleanup
plotly=ggplot(simresults_melted2,aes(x=factor(incidence),y=OR,fill=Comparison))+facet_wrap(~or1)+geom_boxplot()+cleanup
ggplotly(plotly)
simresults_unlisted=data.frame(unlist(lapply(simresults_compiled_alldata,'[[',1)),
unlist(lapply(simresults_compiled_alldata,'[[',2)),
unlist(lapply(simresults_compiled_alldata,'[[',3)),
unlist(lapply(simresults_compiled_alldata,'[[',4)))
simresults_unlisted$list1=(lapply(simresults_compiled_alldata,'[[',5))
simresults_unlisted$list2=(lapply(simresults_compiled_alldata,'[[',6))
colnames(simresults_unlisted)=c("cohort_size","incidence","or1","or2","or1_list","or2_list")
simresults_unlisted=simresults_unlisted%>%filter(or1%in%.5,or2%in%c(0.05,.11,.19),cohort_size%in%500,incidence%in%c(4,8,12,16,20))
simresults_melted=unnest(simresults_unlisted)
simresults_melted2=melt(simresults_melted,
id.vars = c("cohort_size","or1","or2","incidence"),
measure.vars =c("or1_list","or2_list"),
variable.name = "Comparison",
value.name = "OR"
)
ggplot(simresults_melted2,aes(x=factor(incidence),y=OR,fill=Comparison))+facet_wrap(~or2)+geom_boxplot()+scale_y_continuous(trans="log2")+cleanup
plotly=ggplot(simresults_melted2,aes(x=factor(incidence),y=OR,fill=Comparison))+facet_wrap(~or2)+geom_boxplot()+cleanup
ggplotly(plotly)
# sort(unique(simresults_unlisted$or2))
#I used the following website to make sure that my Gaussian elimination was working properly
# https://www.emathhelp.net/calculators/linear-algebra/gauss-jordan-elimination-calculator/?i=%5B%5B1%2C1%2C0%2C0%2C.4836%5D%2C%5B1%2C1%2C1%2C1%2C1%5D%2C%5B0%2C1%2C0%2C-1%2C0%5D%2C%5B1%2C0%2C-0.01%2C0%2C0%5D%5D&reduced=on
sessionInfo()
R version 4.0.0 (2020-04-24)
Platform: x86_64-apple-darwin17.0 (64-bit)
Running under: macOS 10.16
Matrix products: default
BLAS: /Library/Frameworks/R.framework/Versions/4.0/Resources/lib/libRblas.dylib
LAPACK: /Library/Frameworks/R.framework/Versions/4.0/Resources/lib/libRlapack.dylib
locale:
[1] en_US.UTF-8/en_US.UTF-8/en_US.UTF-8/C/en_US.UTF-8/en_US.UTF-8
attached base packages:
[1] parallel grid stats graphics grDevices utils datasets
[8] methods base
other attached packages:
[1] BiocManager_1.30.10 plotly_4.9.2.1 ggsignif_0.6.0
[4] devtools_2.3.0 usethis_1.6.1 RColorBrewer_1.1-2
[7] reshape2_1.4.4 ggplot2_3.3.3 doParallel_1.0.15
[10] iterators_1.0.12 foreach_1.5.0 dplyr_1.0.6
[13] VennDiagram_1.6.20 futile.logger_1.4.3 tictoc_1.0
[16] knitr_1.28 workflowr_1.6.2
loaded via a namespace (and not attached):
[1] Rcpp_1.0.4.6 tidyr_1.1.3 prettyunits_1.1.1
[4] ps_1.3.3 assertthat_0.2.1 rprojroot_1.3-2
[7] digest_0.6.25 utf8_1.1.4 R6_2.4.1
[10] plyr_1.8.6 futile.options_1.0.1 backports_1.1.7
[13] evaluate_0.14 httr_1.4.2 pillar_1.6.1
[16] rlang_0.4.11 lazyeval_0.2.2 data.table_1.12.8
[19] whisker_0.4 callr_3.7.0 rmarkdown_2.8
[22] labeling_0.3 desc_1.2.0 stringr_1.4.0
[25] htmlwidgets_1.5.1 munsell_0.5.0 compiler_4.0.0
[28] httpuv_1.5.2 xfun_0.22 pkgconfig_2.0.3
[31] pkgbuild_1.0.8 htmltools_0.4.0 tidyselect_1.1.0
[34] tibble_3.1.2 codetools_0.2-16 viridisLite_0.3.0
[37] fansi_0.4.1 crayon_1.4.1 withr_2.4.2
[40] later_1.0.0 jsonlite_1.7.2 gtable_0.3.0
[43] lifecycle_1.0.0 DBI_1.1.0 git2r_0.27.1
[46] magrittr_2.0.1 formatR_1.7 scales_1.1.1
[49] cli_2.5.0 stringi_1.4.6 farver_2.0.3
[52] fs_1.4.1 promises_1.1.0 remotes_2.1.1
[55] testthat_2.3.2 ellipsis_0.3.2 generics_0.0.2
[58] vctrs_0.3.8 lambda.r_1.2.4 tools_4.0.0
[61] glue_1.4.1 purrr_0.3.4 processx_3.5.2
[64] pkgload_1.0.2 yaml_2.2.1 colorspace_1.4-1
[67] sessioninfo_1.1.1 memoise_1.1.0