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- %DS firing analysis and correl with response latency
- clear all;clc;
- tic
- global Dura Baseline Tm Tbase BSIZE Tbin
- SAVE_FLAG=1;
- BSIZE=0.01;
- Dura=[-2 4]; Tm=Dura(1):BSIZE:Dura(2);
- Baseline=[-2 0]; Tbase=Baseline(1):BSIZE:Baseline(2); %used to calculate Z-scores
- Tbin=-1:0.005:1; %window used to determine the optimal binsize
- PStat=0.05;
- prewin=[Dura(1) 0];
- postwin=[0 .5];
- postwin2=[Dura(1):0.05:Dura(2)]; %bounds should match Dura
- Slopebounds=[-.5:.05:.5];
- R2Bounds=[0:0.05:0.5];
- PvalBounds=[0:0.01:0.5];
- XI=[1 -1];
- RunRegress=1;
- SAVEFIG=1;
- %R=[];R.Ninfo={};
- NN=0;
- pre=[]; post=[];
- if ~exist('RAW'), load ('RAWextendedtraining.mat'); RAW=RAW; end
- if ~exist('R'), load('Rextendedtraining.mat'); R=R; end
- if RunRegress==0, load('C'); end
- load('Celltype_extendedTraining.mat')
- %path='C:\FRED\GALLO\Exps\2009-present GoNoGo\FINAL\PLX Files GoNoGo\GoNoGo NEX files\RESULTgn14.xls';
- %%
- for i=1:length(RAW)
- EvInd=strmatch('Last_LP',RAW(i).Einfo(:,2),'exact'); %finds the index of the event
- Rind=strmatch('FirstPE_PostRew',RAW(i).Einfo(:,2),'exact'); %finds the index of the event
-
- if sum(EvInd)~=0 && sum(Rind)~=0
- DS(i)=length(RAW(i).Erast{EvInd});
- Neur(i)=length(RAW(i).Nrast);
- end
- end
- MaxTrials=max(DS); MaxNeur=sum(Neur); MaxWin=length(postwin);
- if RunRegress
- % PREALLOCATING
- C.LatPE=NaN(MaxNeur, MaxTrials); % (neurons, trials)
- C.prePE=NaN(MaxNeur,MaxTrials); % (neurons, trials)
- C.postPE=NaN(MaxNeur,MaxTrials); % (neurons, trials)
- C.postwinPE=NaN(MaxNeur,MaxTrials,MaxWin); % (neurons, trials, windows)
-
- Cshuffle.LatPE=NaN(MaxNeur, MaxTrials); % (neurons, trials)
- Cshuffle.prePE=NaN(MaxNeur,MaxTrials); % (neurons, trials)
- Cshuffle.postPE=NaN(MaxNeur,MaxTrials); % (neurons, trials)
- Cshuffle.postwinPE=NaN(MaxNeur,MaxTrials,MaxWin); % (neurons, trials, windows)
-
- for i=1:length(RAW) %loops through sessions
- EvInd=strmatch('Last_LP',RAW(i).Einfo(:,2),'exact'); %finds the index of the event
- Rind=strmatch('FirstPE_PostRew',RAW(i).Einfo(:,2),'exact'); %finds the index of the event
-
- if sum(EvInd)~=0 && sum(Rind)~=0
- Dcell=MakePSR04(RAW(i).Erast(Rind),RAW(i).Erast{EvInd},[-1 10],{2,'first'});
- D=cell2mat(Dcell); %inds=find(~isnan(D));
- D(isnan(D))=60; %trials with no response are set to 10.25 to allow to use them in the correlation
- for j= 1:size(RAW(i).Nrast,1) %Number of neurons within sessions
- NN=NN+1;
- Cshuffle.LatPE(NN,1:length(RAW(i).Erast{EvInd}))=D;
- [PSR2,N2]=MakePSR04(RAW(i).Nrast(j),RAW(i).Erast{EvInd},Dura,{2});% ref= last lever press / makes trial by trail rasters.
- for m=1:size(RAW(i).Erast{Rind},1) %loops through trials
- PElatency=RAW(i).Erast{Rind}(m)-RAW(i).Erast{EvInd}(m);
- Cshuffle.prePE(NN,m)=sum(PSR2{1,m}<prewin(2) & PSR2{1,m}>prewin(1))/(abs(prewin(2)-prewin(1))); %neurons, trials
- Cshuffle.postPE1(NN,m)=sum(PSR2{1,m}<postwin(2) & PSR2{1,m}>postwin(1))/(abs(postwin(2)-postwin(1))); %When last LP is ref, postwin is 0-0.5s post LP
- end %m loop
- fprintf('Neuron ID # %d\n',NN);
- end %j loop
- end %if
- end %i loop
-
- %% Runs the regression analysis on XX number of iterations of shuffled data
-
- XX=1000;
- for n=1:XX
- for NN=1:MaxNeur
- Cshuffle.LatShuffled(NN,:)=shuffle(Cshuffle.LatPE(NN,:));
- RegX=[Cshuffle.LatShuffled(NN,:)', ones(size(Cshuffle.LatShuffled,2),1)];
- [Cshuffle.SLOPEpostshuffled(NN,n),Cshuffle.STATSpostshuffled(NN,n)]= corr(Cshuffle.postPE1(NN,:)',Cshuffle.LatShuffled(NN,:)','rows','pairwise','type','Spearman');
- end
- fprintf('Shuffled Iteration # %d\n',n);
- % Saving data in C structure and excel file
- save('Cshuffle.mat', 'Cshuffle');
- end
- end
- %% Calculates number of significant correlations and the mean correlation coefficient for each
- selection1=R.Structure~=0;
- for q=1:length(Cshuffle.SLOPEpostshuffled(1,:))
- Cshuffle.SLOPEmeanshuffled(q)=nanmean(Cshuffle.SLOPEpostshuffled(selection1,q));
- Cshuffle.SIGshuffled(q)=sum(Cshuffle.STATSpostshuffled(selection1,q)<0.05);
- Cshuffle.NEGSIGshuffled(q)=sum(Cshuffle.STATSpostshuffled(selection1,q)<0.05 & Cshuffle.SLOPEpostshuffled(selection1,q)<0);
- end
- %% Calculates correlation coefficients and significant values for real data
- for NN=1:MaxNeur
- RegX=[Cshuffle.LatPE(NN,:)', ones(size(Cshuffle.LatPE,2),1)];
- [Cshuffle.SLOPEpre,Cshuffle.STATSpre]=corr(Cshuffle.prePE(NN,:)',Cshuffle.LatPE(NN,:)','rows','pairwise','type','Spearman');
- [Cshuffle.SLOPEpost(NN,:),Cshuffle.STATSpost(NN,:)]= corr(Cshuffle.postPE1(NN,:)',Cshuffle.LatPE(NN,:)','rows','pairwise','type','Spearman');
- [Cshuffle.SLOPEpostpre(NN,:),Cshuffle.STATSpostpre(NN,:)]= corr((Cshuffle.postPE1(NN,:)-Cshuffle.prePE(NN,:))',Cshuffle.LatPE(NN,:)','rows','pairwise','type','Spearman');
- fprintf('CORREL Neuron ID # %d\n',NN);
- end
-
- Cshuffle.SelectionLAT(:,1)=R.Structure==10 & R.TRN(:,1)~=0 & Cshuffle.STATSpost(:,1)<PStat;
- Cshuffle.SelectionLAT(:,2)=R.Structure==20 & R.TRN(:,1)~=0 & Cshuffle.STATSpost(:,1)<PStat;
- % Saving data in C structure and excel file
- save('Cshuffle.mat', 'Cshuffle');
-
- %% Figure of distributions of means correlation coefficients and number of significant neurons
- selection1=R.Structure==10 & Celltype(:,1)==1;
- selection2=R.Structure==20 & Celltype(:,1)==1;
- figure;
- % Plot of distribution of mean correlation coefficients for all of the
- % shuffled data
- subplot(2,2,3);
- histogram(Cshuffle.SLOPEmeanshuffled,100);
- hold on;
- MEANsel1=nanmean(Cshuffle.SLOPEpost(selection1,1));
- MEANsel2=nanmean(Cshuffle.SLOPEpost(selection2,1));
- plot([MEANsel1 MEANsel1], [0 50],'Color','b');
- plot([MEANsel2 MEANsel2], [0 50],'Color','r');
- xlabel('Mean correlation coefficient') % x-axis label
- ylabel('# of iterations')% y-axis label
- %Plot of distribution of number of significantly correlated neurons across
- %all the shuffled data sets
- subplot(2,2,4);
- histogram((Cshuffle.SIGshuffled*100/sum(Celltype(:,1)==1)),40);
- xlabel('% of significantly correlated unit') % x-axis label
- ylabel('# of iterations')% y-axis label
- hold on;
- SigNUM1=100*sum(Cshuffle.STATSpost(selection1,1)<0.05)/(sum(selection1));
- SigNUM2=100*sum(Cshuffle.STATSpost(selection2,1)<0.05)/(sum(selection2));
- plot([SigNUM1 SigNUM1], [0 100],'Color','b');
- plot([SigNUM2 SigNUM2], [0 100],'Color','r');
- propSigSh=Cshuffle.SIGshuffled*100/sum(Celltype(:,1)==1);
- OTpval(1,1)=(sum(propSigSh>SigNUM1)+1)/(length(propSigSh)+1);
- OTpval(2,1)=(sum(propSigSh>SigNUM2)+1)/(length(propSigSh)+1);
- % Plot of correlation coefficients from example shuffled data set
- subplot(2,2,1);
- sel1=R.Structure~=0;
- sel2=sel1 & Cshuffle.STATSpostshuffled(:,1)<PStat;
- xmin=floor(min(Cshuffle.SLOPEpostshuffled(sel1,1)));
- xmax=ceil(max(Cshuffle.SLOPEpostshuffled(sel1,1)));
- step=0.05;
- xcenters=xmin:step:xmax;
- Nsel1=hist(Cshuffle.SLOPEpostshuffled(sel1,1),xcenters);
- Nsel2=hist(Cshuffle.SLOPEpostshuffled(sel2,1),xcenters);
- hold on;
- bar(xcenters, Nsel1, 'w', 'EdgeColor', 'k', 'BarWidth', 1);alpha(0.3);
- bar(xcenters, Nsel2, 'k', 'EdgeColor', 'k', 'BarWidth', 1);
- plot([0 0], [0 30],'LineStyle',':','Color','k');
- MEANsel1=mean(Cshuffle.SLOPEpostshuffled(sel1,1));
- plot([MEANsel1 MEANsel1], [0 10],'Color','r');
- xlabel('% correlation coefficient shuffle data') % x-axis label
- ylabel('# of neurons')% y-axis label
- hold on;
- % %Plot of correlation coefficients with significance marked based on
- % %bootstrapping
- subplot(2,2,2);
- sel1=R.Structure~=0;
- sel2= sel1 & Cshuffle.STATSpost(:,1)<PStat;
- xmin=floor(min(Cshuffle.SLOPEpost(sel1,1)));
- xmax=ceil(max(Cshuffle.SLOPEpost(sel1,1)));
- step=0.05;
- xcenters=xmin:step:xmax;
- Nsel1=hist(Cshuffle.SLOPEpost(sel1,1),xcenters);
- Nsel2=hist(Cshuffle.SLOPEpost(sel2,1),xcenters);
- hold on;
- bar(xcenters, Nsel1, 'w', 'EdgeColor', 'k', 'BarWidth', 1);alpha(0.3);
- bar(xcenters, Nsel2, 'k', 'EdgeColor', 'k', 'BarWidth', 1);
- plot([0 0], [0 30],'LineStyle',':','Color','k');
- MEANsel1=mean(Cshuffle.SLOPEpost(sel2,1));
- plot([MEANsel1 MEANsel1], [0 10],'Color','r');
- xlabel('% correlation coefficient real data') % x-axis label
- ylabel('# of neurons')% y-axis label
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