%% SFFT Topoplots of REST and PRE-CUE data clear; clc; close all; datalocation = ('D:\Project_EEG_CC\SFFT_TopoFigure\Data_Topo_new\'); cd(datalocation) savedirOFF='D:\Project_EEG_CC\SFFT_TopoFigure\Data_Topo_new\OFF\'; % OFF Data are here savedirON='D:\Project_EEG_CC\SFFT_TopoFigure\Data_Topo_new\ON\'; % ON Data are here savedirCTL='D:\Project_EEG_CC\SFFT_TopoFigure\Data_Topo_new\Control\'; % Control Data are here load('D:\Project_EEG_CC\mFiles\ONOFF.mat','ONOFF') BigN=size(ONOFF,1)./2; off = [2 1 1 2 2 1 1 1 2 2 2 1 2 2 1 1 2 1 1 2 2 1 1 2 2 1 1 1]; on = [ 1 2 2 1 1 2 2 2 1 1 1 2 1 1 2 2 1 2 2 1 1 2 1 1 1 2 2 2]; %%%%% OFF and Control data for mi=1:28 %%%%%%%%%% OFF data %%%%%%%%%%%%%%%%%%%%%%% PDsx=[801:811,813:829]; load([savedirOFF,num2str(PDsx(1,mi)),'_Session_',num2str(off(1,mi)),'_PDDys_CC_ALL_TOPO.mat']); mData_Cue_OFF = cell2mat(mData_Cue); CueDataOFF{mi,:} = mData_Cue_OFF; mData_REST_OFF = cell2mat(mData_REST); RESTDataOFF{mi,:} = mData_REST_OFF; clear mData_Cue mData_Cue_OFF mData_REST mData_REST_OFF %%%%%%%%%%%% ON data %%%%%%%%%%%%%%%%%%%%%% for 824 off= on %%%%%%%%%%%% load([savedirON,num2str(PDsx(1,mi)),'_Session_',num2str(on(1,mi)),'_PDDys_CC_ALL_TOPO.mat']); mData_Cue_ON = cell2mat(mData_Cue); CueDataON{mi,:} = mData_Cue_ON; mData_REST_ON = cell2mat(mData_REST); RESTDataON{mi,:} = mData_REST_ON; clear mData_Cue mData_Cue_ON mData_REST mData_REST_ON %%%%%%%%%%%%% Control %%%%%%%%%%%%%%%%%%%%%%%%% CTLsx=[8010,8070,8060,890:914]; load([savedirCTL,num2str(CTLsx(1,mi)),'_Session_1','_PDDys_CC_ALL_TOPO.mat']); mData_Cue_CTL = cell2mat(mData_Cue); CueDataCTL{mi,:} = mData_Cue_CTL; mData_REST_CTL = cell2mat(mData_REST); RESTDataCTL{mi,:} = mData_REST_CTL; clear mData_Cue mData_Cue_CTL mData_REST mData_REST_CTL end clearvars -except CueDataOFF RESTDataOFF CueDataON RESTDataON CueDataCTL RESTDataCTL tx2disp =-1500:2:4998; %% #############################%%%%%%%%%%%%% REST DATA %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% fs = 500; % define analysis parameters xlen = length(RESTDataOFF{1,:}(:,1)); % length of the signal wlen = 128; % window length (recomended to be power of 2) nop = []; % hop size (recomended to be power of 2) nfft = 256; % number of fft points (recomended to be power of 2) for n=1:28 for ch = 1:60 [sNr,fyr,txr] = spectrogram(RESTDataON {n,:}(:,ch),wlen,nop,nfft,fs, 'yaxis'); sON_All_Rt {n,:}.sub{ch,:} = abs(sNr).^2; % [sCr,fyr,txr] = spectrogram(RESTDataCTL{n,:}(:,ch),wlen,nop,nfft,fs, 'yaxis'); sCTL_All_Rt{n,:}.sub{ch,:} = abs(sCr).^2; % end end clear sFr sNr sCr % % %%%%%%%%%%%%%%%%%%%%% For REST Data 0-50 Hz frequncy band %%%%%%%%%%%%%%%%%%%%% band1= (find(fyr==0)); band2 = find(fyr<51, 1, 'last' ); % ch = 21; % channel Cz for n = 1:28 %%%%%%%%%%%%%%%% ON %%%%%%%%%%%%%%%% ONbandRt(n,:).band = sON_All_Rt{n, 1}.sub{ch, 1}(band1:band2,:) ; %%%%%%%%%%%%%%%% CONTROL %%%%%%%%%%%%%%%% CTLbandRt(n,:).band = sCTL_All_Rt{n, 1}.sub{ch, 1}(band1:band2,:) ; end % % for n = 1:28 %%%%%%%%%%%%%%%% ON %%%%%%%%%%%%%%%% ONRt_fband{n} = double(mean(ONbandRt(n).band,2)); %%%%%%%%%%%%%%%% CONTROL %%%%%%%%%%%%%%%% CTLRt_fband{n} = double(mean(CTLbandRt(n).band,2)); end % ONRt_fband = cell2mat(ONRt_fband); CTLRt_fband = cell2mat(CTLRt_fband); fyL2 = round (double(fyr(band1:band2)) ); tnR = size(ONRt_fband,2); sONRt = double(log10(ONRt_fband)); sCTLRt = double(log10(CTLRt_fband)); subplot(2,4,[1 5]) shadedErrorBar(fyL2,mean(sCTLRt,2),std(sCTLRt,0,2)/sqrt(tnR),'k',1); hold on; shadedErrorBar(fyL2,mean(sONRt,2), std(sONRt,0,2)/sqrt(tnR), 'r',1); hold on; % %% T test for FFT data TEMP_ON = ONRt_fband'; TEMP_CTL = CTLRt_fband'; %%%% ON vs CTL [~,P1,~,STATS1]=ttest2(TEMP_ON,TEMP_CTL); P1(P1>=.05)=NaN; P1(P1<.05)=1; plot(fyL2,log10(15*P1),'*b','MarkerSize',5); hold off; clear TEMP_ON TEMP_CTL xlim([0 50]); box off; ylim([0 5]); xlabel('Frequency (Hz)'); ylabel('Log power(\muV^2)'); title ('REST(Black=CTL; Red = PD ON)'); % % %%% for TOPO REST data Thr1= min(find(fyr>4)); Thr2 = max(find(fyr<8)); % Theta Alr1= min(find(fyr>8)); Alr2 = max(find(fyr<13)); % Alpha for n = 1:28 for ch = 1:60 %%%%%%%%%%%%%%%% ON %%%%%%%%%%%%%%%% ONfreqbandRt{n,ch}.Theta = double( mean2(sON_All_Rt{n, 1}.sub{ch, 1}(Thr1:Thr2, :)) ) ; ONfreqbandRt{n,ch}.Alpha = double( mean2(sON_All_Rt{n, 1}.sub{ch, 1}(Alr1:Alr2, :)) ) ; %%%%%%%%%%%%%%%% CONTROL %%%%%%%%%%%%%%%% CTLfreqbandRt{n,ch}.Theta = double( mean2(sCTL_All_Rt{n, 1}.sub{ch, 1}(Thr1:Thr2, :)) ) ; CTLfreqbandRt{n,ch}.Alpha = double( mean2(sCTL_All_Rt{n, 1}.sub{ch, 1}(Alr1:Alr2, :)) ) ; end end %% ############################################# Pre-Cue Data ########################################################### fs = 500; % define analysis parameters xlen = length(CueDataOFF{1,:}(:,1)); % length of the signal wlen = 128; % window length (recomended to be power of 2) nop = []; % hop size (recomended to be power of 2) nfft = 256; % number of fft points (recomended to be power of 2) for n=1:28 for ch = 1:60 %%%%%%%%%%%%% Pre Cue Data [sF,fy,tx] = spectrogram(CueDataOFF{n,:}(:,ch),wlen,nop,nfft,fs, 'yaxis'); sOFF_All{n,:}.sub{ch,:} = abs(sF).^2; % in power [sN,fy,tx] = spectrogram(CueDataON{n,:} (:,ch),wlen,nop,nfft,fs, 'yaxis'); sON_All {n,:}.sub{ch,:} = abs(sN).^2; % [sC,fy,tx] = spectrogram(CueDataCTL{n,:}(:,ch),wlen,nop,nfft,fs, 'yaxis'); sCTL_All{n,:}.sub{ch,:} = abs(sC).^2; % end end clearvars sF sN sC % % %%%%%%%%%%%%%%%%%%%%% For Pre-Cue Data 0-50 Hz frequncy band: -0.5 to 0 ms %%%%%%%%%%%%%%%%%%%%% band1= (find(fy==0)); band2 = find(fy<51, 1, 'last' ); % xp1 = max(find(tx<1.0)); xp2 = find(tx==1.5 | tx < 1.6, 1, 'last' ); %%% for Pre-Cue Data ch = 21; % channel Cz for n = 1:28 %%%%%%%%%%%%%%%% ON %%%%%%%%%%%%%%%% ONbandPC(n,:).band = sON_All{n, 1}.sub{ch, 1}(band1:band2, xp1:xp2) ; %%%%%%%%%%%%%%%% CONTROL %%%%%%%%%%%%%%%% CTLbandPC(n,:).band = sCTL_All{n, 1}.sub{ch, 1}(band1:band2, xp1:xp2) ; end for n = 1:28 %%%%%%%%%%%%%%%% ON %%%%%%%%%%%%%%%% ONPC_fband{n} = nanmean(ONbandPC(n).band,2); %%%%%%%%%%%%%%%% CONTROL %%%%%%%%%%%%%%%% CTLPC_fband{n} = nanmean(CTLbandPC(n).band,2); end ONPC_fband = cell2mat(ONPC_fband); CTLPC_fband = cell2mat(CTLPC_fband); fyL = round (double(fy(band1:band2)) ); tnP = size(ONPC_fband,2); sONPC = double(log10(ONPC_fband)); sCTLPC = double(log10(CTLPC_fband)); subplot(2,4,[3 7]) shadedErrorBar(fyL,mean(sCTLPC,2),std(sCTLPC,0,2)/sqrt(tnP),'k',1); hold on; shadedErrorBar(fyL,mean(sONPC,2), std(sONPC,0,2)/sqrt(tnP), 'r',1); hold on; % %% T test for FFT data TEMP_ON = ONPC_fband'; TEMP_CTL = CTLPC_fband'; %%%% ON vs CTL [~,P2,~,STATS2]=ttest2(TEMP_ON,TEMP_CTL); P2(P2>=.05)=NaN; P2(P2<.05)=1; plot(fyL2,log10(10*P2),'*b','MarkerSize',5); hold off; clear TEMP_ON TEMP_CTL xlim([0 50]); box off; ylim([-1 5]); xlabel('Frequency (Hz)'); ylabel('Log power(\muV^2)'); title ('Pre-Cue -500 -0(Black=CTL; Red = PD ON)'); %%%%% Get Frequency bands info for PreCue for TOPO Th1= min(find(fy>4)); Th2 = max(find(fy<8)); % Theta Al1= min(find(fy>8)); Al2 = max(find(fy<13)); % Alpha %%%%%%%%%%%%%%%%%%%%%%% For Pre-Cue Data %%%%%%%%%%%%%%%%%%%%% for n = 1:28 for ch = 1:60 %%%%%%%%%%%%%%%% ON %%%%%%%%%%%%%%%% ONfreqbandPC{n,ch}.Theta = double( mean2(sON_All{n, 1}.sub{ch, 1}(Th1:Th2, xp1:xp2)) ) ; ONfreqbandPC{n,ch}.Alpha = double( mean2(sON_All{n, 1}.sub{ch, 1}(Al1:Al2, xp1:xp2)) ) ; %%%%%%%%%%%%%%%% CONTROL %%%%%%%%%%%%%%%% CTLfreqbandPC{n,ch}.Theta = double( mean2(sCTL_All{n, 1}.sub{ch, 1}(Th1:Th2, xp1:xp2)) ) ; CTLfreqbandPC{n,ch}.Alpha = double( mean2(sCTL_All{n, 1}.sub{ch, 1}(Al1:Al2, xp1:xp2)) ) ; end end %% FOR TOPO % clearvars -except OFFfreqbandPC ONfreqbandPC CTLfreqbandPC OFFfreqbandRs ONfreqbandRs CTLfreqbandRs OFFfreqbandRt ONfreqbandRt CTLfreqbandRt % % Export data according to the band for n = 1:28 for ch = 1:60 %%%%%%%%% CONTROL %%%%%%%%%%%%%%%%%%%% %%%%% PreCue CTL.Theta.PC(n,ch) = CTLfreqbandPC{n, ch}.Theta; CTL.Alpha.PC(n,ch) = CTLfreqbandPC{n, ch}.Alpha; %%%% REST CTL.Theta.Rt(n,ch) = CTLfreqbandRt{n, ch}.Theta; CTL.Alpha.Rt(n,ch) = CTLfreqbandRt{n, ch}.Alpha; %%%%%%%%%%%%%% ON %%%%%%%%%%%%%% %%%%% PreCue ON.Theta.PC(n,ch) = ONfreqbandPC{n, ch}.Theta; ON.Alpha.PC(n,ch) = ONfreqbandPC{n, ch}.Alpha; %%%% REST ON.Theta.Rt(n,ch) = ONfreqbandRt{n, ch}.Theta; ON.Alpha.Rt(n,ch) = ONfreqbandRt{n, ch}.Alpha; end end %% statistics analysis for REST and Pre Cue...Theta and Alpha bands ch = 21; % channel Cz [~,Prt,~,STATSrt]=ttest2(CTL.Theta.Rt(:,ch), ON.Theta.Rt(:,ch)); Theta_state_RT = ['Theta REST: t value = ',num2str(STATSrt.tstat ),'; p value = ' num2str(Prt)]; disp(Theta_state_RT); [~,Pra,~,STATSra]=ttest2(CTL.Alpha.Rt(:,ch), ON.Alpha.Rt(:,ch)); Alpha_state_RT = ['Alpha REST: t value = ',num2str(STATSra.tstat ),'; p value = ' num2str(Pra)]; disp(Alpha_state_RT); [~,Ppt,~,STATSpt]=ttest2(CTL.Theta.PC(:,ch), ON.Theta.PC(:,ch)); Theta_state_PC = ['Theta PreCue: t value = ',num2str(STATSpt.tstat ),'; p value = ' num2str(Ppt)]; disp(Theta_state_PC); [~,Ppa,~,STATSpa]=ttest2(CTL.Alpha.PC(:,ch), ON.Alpha.PC(:,ch)); Alpha_state_PC = ['Alpha PreCue: t value = ',num2str(STATSpa.tstat ),'; p value = ' num2str(Ppa)]; disp(Alpha_state_PC); %% plot topo load('D:\Project_EEG_CC\mFiles\BV_Chanlocs_60.mat'); chanlocs = BV_Chanlocs_60; %%%% CONTROL - ON % %%%%%%%% for REST data cad =[-100000 100000]; cat =[-5000 5000]; caa = [-500 500]; cab = [-40 40]; cag = [-20 20]; subplot(242);[~,P,~,~]=ttest2(CTL.Theta.Rt, ON.Theta.Rt); P(P>=.05)=NaN; P(P<.05)=1; P(isnan(P))=0; topoplot((mean(CTL.Theta.Rt)- mean(ON.Theta.Rt)),chanlocs,'maplimits',[-3 3],'emarker2', {find(P),'d','k',5,1}); clear P; title ('REST:Theta (CTL-PD ON)');caxis(cat);colormap jet; subplot(246);[~,P,~,~]=ttest2(CTL.Alpha.Rt, ON.Alpha.Rt); P(P>=.05)=NaN; P(P<.05)=1; P(isnan(P))=0; topoplot((mean(CTL.Alpha.Rt)- mean(ON.Alpha.Rt)),chanlocs,'maplimits',[-3 3],'emarker2', {find(P),'d','k',5,1}); clear P; title ('REST:Alpha (CTL-PD ON)');caxis(caa);colormap jet; % %%%%%%%% for Pre-Cue data cad =[-20000 20000]; cat =[-500 500]; caa = [-30 30]; cab = [-20 20]; cag = [-10 10]; subplot(244);[~,P,~,~]=ttest2(CTL.Theta.PC, ON.Theta.PC); P(P>=.05)=NaN; P(P<.05)=1; P(isnan(P))=0; topoplot((mean(CTL.Theta.PC)- mean(ON.Theta.PC)),chanlocs,'maplimits',[-3 3],'emarker2', {find(P),'d','k',5,1}); clear P; title ('PreCue:Theta (CTL-PD ON)');caxis(cat);colormap jet; subplot(248);[~,P,~,~]=ttest2(CTL.Alpha.PC, ON.Alpha.PC); P(P>=.05)=NaN; P(P<.05)=1; P(isnan(P))=0; topoplot((mean(CTL.Alpha.PC)- mean(ON.Alpha.PC)),chanlocs,'maplimits',[-3 3],'emarker2', {find(P),'d','k',5,1}); clear P; title ('PreCue:Alpha (CTL-PD ON)');caxis(caa);colormap jet; suptitle ('Control and PD ON')