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Looking-to-cue-sides-and-modulation-of-value-in-OFC
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10.12751/g-node.evlnq5
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neuralAnalyses.m

neuralAnalyses.m 24 KB
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  1. addpath('./support_functions');
    2. 

  2. 

  3. clearvars -except subjsData poolstack* pooltw*
    4. 

  4. close all; clc; %clear all;
    5. 

  5. 

  6. recompute_mfit=0; 
    7. 

  7. reload_eye_spk_data=0;
    8. 

  8. Nlag=10; Nspan=200; Nshf=10; 
    9. 

  9. %Nlag=10; Nspan=200; Nshf=1000; %Set default
    10. 

  10. normstr='minus';  %normstr='no'; %normstr='div';
    11. 

  11. 

  12. poissfitflag=0; 
    13. 

  13. if poissfitflag && strcmpi(normstr,'div'); error('please combine poissfitflag with normstr=no'); end
    14. 

  14. 

  15. figures_folder='../figures';
    16. 

  16. 

  17.  if ~exist('subjsData','var')
    18. 

  18.      subjsData(1).sbdata=getSubjectData(1);
    19. 

  19.      subjsData(2).sbdata=getSubjectData(2);
    20. 

  20.  end
    21. 

  21. 

  22. if ~exist('poolstackvars','var')
    23. 

  23.     poolstackvars=getPoolStackVars(subjsData);
    24. 

  24. end
    25. 

  25. 

  26. twLabels={'preoffer1','offer1','delay1','offer2','delay2','refixate','choice-go','ch-hold'};
    27. 

  27. 

  28. nccs=arrayfun(@(sn) poolstackvars(sn).ncells, 1:8);
    29. 

  29. ntrs=arrayfun(@(sn) size(poolstackvars(sn).offer1sd,1),1:8);
    30. 

  30. 

  31. Nccs=sum(nccs);
    32. 

  32. Ntrs12=max(ntrs);
    33. 

  33. 

  34. pooloffer1sd=[]; poolofferLev=[]; poolofferRev=[]; pooloffer1ev=[]; pooloffer2ev=[]; pooloffer1rw=[]; pooloffer2rw=[]; 
    35. 

  35. for sn=1:8
    36. 

  36.     pooloffer1sd=cat(2, pooloffer1sd, repmat(cat(1,poolstackvars(sn).offer1sd,nan(Ntrs12-ntrs(sn),1)),[1 nccs(sn)]));
    37. 

  37.     poolofferLev=cat(2, poolofferLev, repmat(cat(1,poolstackvars(sn).offerLev,nan(Ntrs12-ntrs(sn),1)),[1 nccs(sn)]));
    38. 

  38.     poolofferRev=cat(2, poolofferRev, repmat(cat(1,poolstackvars(sn).offerRev,nan(Ntrs12-ntrs(sn),1)),[1 nccs(sn)]));
    39. 

  39.     pooloffer1ev=cat(2, pooloffer1ev, repmat(cat(1,poolstackvars(sn).offer1ev,nan(Ntrs12-ntrs(sn),1)),[1 nccs(sn)]));
    40. 

  40.     pooloffer2ev=cat(2, pooloffer2ev, repmat(cat(1,poolstackvars(sn).offer2ev,nan(Ntrs12-ntrs(sn),1)),[1 nccs(sn)]));
    41. 

  41.     pooloffer1rw=cat(2, pooloffer1rw, repmat(cat(1,poolstackvars(sn).offer1rw,nan(Ntrs12-ntrs(sn),1)),[1 nccs(sn)]));
    42. 

  42.     pooloffer2rw=cat(2, pooloffer2rw, repmat(cat(1,poolstackvars(sn).offer2rw,nan(Ntrs12-ntrs(sn),1)),[1 nccs(sn)]));
    43. 

  43. end
    44. 

  44. 

  45. if reload_eye_spk_data
    46. 

  46.     if ~exist('pooltweyepos','var')
    47. 

  47.         pooltweyepos=getTimewinsPoolEyePos();
    48. 

  48.     end
    49. 

  49.     if ~exist('pooltwspksq','var')
    50. 

  50.         pooltwspksq=getTimewinsPoolSpikeSeqs();
    51. 

  51.     end
    52. 

  52.     
    53. 

  53.     Ntps12=arrayfun(@(tw) size(pooltweyepos(tw).posX,3), 1:8);
    54. 

  54.     Ntps12(1)=400;
    55. 

  55.     
    56. 

  56.     pooleposxmat=cat(3,pooltweyepos(1).posX,pooltweyepos(2).posX,pooltweyepos(3).posX,pooltweyepos(4).posX,...
    57. 

  57.         pooltweyepos(5).posX,pooltweyepos(6).posX,pooltweyepos(7).posX,pooltweyepos(8).posX);
    58. 

  58.     poolspksqmat=cat(3,pooltwspksq(1).spkseqs,pooltwspksq(2).spkseqs,pooltwspksq(3).spkseqs,pooltwspksq(4).spkseqs,...
    59. 

  59.         pooltwspksq(5).spkseqs,pooltwspksq(6).spkseqs,pooltwspksq(7).spkseqs,pooltwspksq(8).spkseqs);
    60. 

  60.     poolcovhist=cat(2,pooltwspksq(1).covhist',pooltwspksq(2).covhist',pooltwspksq(3).covhist',pooltwspksq(4).covhist',...
    61. 

  61.         pooltwspksq(5).covhist',pooltwspksq(6).covhist',pooltwspksq(7).covhist',pooltwspksq(8).covhist');
    62. 

  62.     clearvars pooltwspksq pooltweyepos % to reduce memory usage keep pooled version
    63. 

  63.     
    64. 

  64.     fchg=find(poolcovhist>=.999); fchl=find(poolcovhist<.999); % use 99.9% coverage
    65. 

  65.     ntcv=[fchg(diff([fchg sum(Ntps12)])>1)' fchl([diff(fchl) sum(Ntps12)]>1)'];
    66. 

  66.     ntce=[[1; 401; ntcv(1:end-1,2)] [400; ntcv(:,1)]];
    67. 

  67.     vtps=ones(1,sum(Ntps12)); for jj=1:7; vtps(ntcv(jj,1):ntcv(jj,2))=nan; end
    68. 

  68.     
    69. 

  69.     %if sparsity==1 it means 1spike/ms that is 1000 spikes/s
    70. 

  70.     %nanmean(vectorise((nansum(poolspksqmat,3))./(nansum(poolspksqmat>=0,3))))*1000
    71. 

  71.     %nanstd(vectorise((nansum(poolspksqmat,3))./(nansum(poolspksqmat>=0,3))))*1000
    72. 

  72.     
    73. 

  73.     % smooth by movmean filtering, downsample to 20ms, 50Hz resolution
    74. 

  74.     Ntps_ds=ceil(sum(Ntps12)/Nlag);
    75. 

  75.     tmax_ds=nanmovmean(1:size(pooleposxmat,3),Nlag,Nlag);
    76. 

  76.     poolspksqmat_ds=nan(Ntrs12,Nccs,length(tmax_ds));
    77. 

  77.     pooleposxmat_ds=nan(Ntrs12,Nccs,length(tmax_ds));
    78. 

  78.     
    79. 

  79.     for cc=1:Nccs
    80. 

  80.         poolspksqmat_ds(:,cc,:)=nanmovmean(squeeze(poolspksqmat(:,cc,:))',Nlag,[0 Nspan])';
    81. 

  81.         pooleposxmat_ds(:,cc,:)=nanmovmean(squeeze(pooleposxmat(:,cc,:))',Nlag,Nlag)';
    82. 

  82.     end
    83. 

  83.     
    84. 

  84.     clearvars poolspksqmat pooleposxmat % to reduce memory usage keep downsampled version
    85. 

  85.     
    86. 

  86.     save('../data/downsampled_eye_spk_data.mat','Ntps_ds','tmax_ds','vtps','ntc*','fch*','Ntps12',...
    87. 

  87.         'poolcovhist','poolspksqmat_ds','pooleposxmat_ds','-v7.3');
    88. 

  88. else
    89. 

  89.     load('../data/downsampled_eye_spk_data.mat');
    90. 

  90. end
    91. 

  91. 

  92. poolcovhist_ds=nanmovmean(poolcovhist,Nlag,Nlag);
    93. 

  93. %fcgh_ds=find(poolcovhist_ds>=.8); fchl_ds=find(poolcovhist_ds<.8);
    94. 

  94. fcgh_ds=find(poolcovhist_ds>=.999); fchl_ds=find(poolcovhist_ds<.999);
    95. 

  95. ntcv_ds=[fcgh_ds(diff([fcgh_ds Ntps_ds])>1)' fchl_ds([diff(fchl_ds) Ntps_ds]>1)'];
    96. 

  96. vtps_ds=ones(1,Ntps_ds);  for jj=1:7; vtps_ds(ntcv_ds(jj,1):ntcv_ds(jj,2))=nan; end
    97. 

  97. ntce_ds=[[1 ceil(400/Nlag)+1 find(vtps_ds(2:end)+isnan(vtps_ds(1:end-1))==2)+1]' [ceil(400/Nlag) find(vtps_ds(1:end-1)+isnan(vtps_ds(2:end))==2)]'];
    98. 

  98. 

  99. % Apply movmean independently across time windows
    100. 

  100. % checktps_ds=zeros(1,length(poolcovhist_ds));
    101. 

  101. % for tw=1:8
    102. 

  102. %     tpvec=zeros(1,length(poolcovhist));
    103. 

  103. %     tpvec(ntce(tw,1):ntce(tw,2))=1;
    104. 

  104. %     tpvec_ds=zeros(1,length(poolcovhist_ds));
    105. 

  105. %     tpvec_ds(ntce_ds(tw,1):ntce_ds(tw,2))=1;
    106. 

  106. %     for cc=1:Nccs
    107. 

  107. %         nnspktemp=nanmovmean(squeeze(poolspksqmat(:,cc,tpvec==1))',Nlag,[0 Nspan])';
    108. 

  108. %         poolspksqmat_ds(:,cc,tpvec_ds==1)=nnspktemp(:,1:sum(tpvec_ds==1));
    109. 

  109. %         nnepxtemp=nanmovmean(squeeze(pooleposxmat(:,cc,tpvec==1))',Nlag,Nlag)';
    110. 

  110. %         pooleposxmat_ds(:,cc,tpvec_ds==1)=nnepxtemp(:,1:sum(tpvec_ds==1));
    111. 

  111. %     end
    112. 

  112. %     checktps_ds(tpvec_ds==1)=checktps_ds(tpvec_ds==1)+tw;
    113. 

  113. % end
    114. 

  114. 

  115. vtmax_ds=(tmax_ds.*vtps_ds); 
    116. 

  116. vtmax_ds(isnan(vtmax_ds))=[];
    117. 

  117. rtmax_ds=1:length(vtmax_ds);
    118. 

  118. rtmes_ds=arrayfun(@(jj) length(ntce_ds(jj,1):ntce_ds(jj,2)), 1:8);
    119. 

  119. 

  120. % baseline normalization
    121. 

  121. if strcmpi(normstr,'no')
    122. 

  122.     poolspksqmat_ds_bln=poolspksqmat_ds;
    123. 

  123.     %pooleposxmat_ds_bln=pooleposxmat_ds;
    124. 

  124. elseif strcmpi(normstr,'div')
    125. 

  125.     poolspksqmat_ds_bln=poolspksqmat_ds./repmat(nanmean(poolspksqmat_ds(:,:,1:floor(400/Nlag)),3)+eps,[1 1 Ntps_ds]);
    126. 

  126.     %pooleposxmat_ds_bln=pooleposxmat_ds./repmat(nanmean(pooleposxmat_ds(:,:,1:floor(400/Nlag)),3)+eps,[1 1 Ntps_ds]);
    127. 

  127. elseif strcmpi(normstr,'minus')
    128. 

  128.     poolspksqmat_ds_bln=poolspksqmat_ds-repmat(nanmean(poolspksqmat_ds(:,:,1:floor(400/Nlag)),3),[1 1 Ntps_ds]);
    129. 

  129.     %pooleposxmat_ds_bln=pooleposxmat_ds-repmat(nanmean(pooleposxmat_ds(:,:,1:floor(400/Nlag)),3),[1 1 Ntps_ds]);
    130. 

  130. end
    131. 

  131. 

  132. clearvars poolspksqmat_ds %pooleposxmat_ds % to reduce memory usage
    133. 

  133. 

  134. %% Regress EV vs Spiking
    135. 

  135. if recompute_mfit
    136. 

  136. lmELpv=nan(Nccs,Ntps_ds);   lmELpv_shf=nan(Nccs,Ntps_ds,Nshf);   lmERpv=nan(Nccs,Ntps_ds);   lmERpv_shf=nan(Nccs,Ntps_ds,Nshf);
    137. 

  137. lmELpvLL=nan(Nccs,Ntps_ds); lmELpvLL_shf=nan(Nccs,Ntps_ds,Nshf); lmERpvLL=nan(Nccs,Ntps_ds); lmERpvLL_shf=nan(Nccs,Ntps_ds,Nshf);
    138. 

  138. lmELpvLR=nan(Nccs,Ntps_ds); lmELpvLR_shf=nan(Nccs,Ntps_ds,Nshf); lmERpvLR=nan(Nccs,Ntps_ds); lmERpvLR_shf=nan(Nccs,Ntps_ds,Nshf);
    139. 

  139. lmELR2=nan(Nccs,Ntps_ds);   lmELR2_shf=nan(Nccs,Ntps_ds,Nshf);   lmERR2=nan(Nccs,Ntps_ds);   lmERR2_shf=nan(Nccs,Ntps_ds,Nshf);
    140. 

  140. lmELR2LL=nan(Nccs,Ntps_ds); lmELR2LL_shf=nan(Nccs,Ntps_ds,Nshf); lmERR2LL=nan(Nccs,Ntps_ds); lmERR2LL_shf=nan(Nccs,Ntps_ds,Nshf);
    141. 

  141. lmELR2LR=nan(Nccs,Ntps_ds); lmELR2LR_shf=nan(Nccs,Ntps_ds,Nshf); lmERR2LR=nan(Nccs,Ntps_ds); lmERR2LR_shf=nan(Nccs,Ntps_ds,Nshf);
    142. 

  142. lmELb0=nan(Nccs,Ntps_ds);   lmELb0_shf=nan(Nccs,Ntps_ds,Nshf);   lmERb0=nan(Nccs,Ntps_ds);   lmERb0_shf=nan(Nccs,Ntps_ds,Nshf);
    143. 

  143. lmELb0LL=nan(Nccs,Ntps_ds); lmELb0LL_shf=nan(Nccs,Ntps_ds,Nshf); lmERb0LL=nan(Nccs,Ntps_ds); lmERb0LL_shf=nan(Nccs,Ntps_ds,Nshf);
    144. 

  144. lmELb0LR=nan(Nccs,Ntps_ds); lmELb0LR_shf=nan(Nccs,Ntps_ds,Nshf); lmERb0LR=nan(Nccs,Ntps_ds); lmERb0LR_shf=nan(Nccs,Ntps_ds,Nshf);
    145. 

  145. lmELb1=nan(Nccs,Ntps_ds);   lmELb1_shf=nan(Nccs,Ntps_ds,Nshf);   lmERb1=nan(Nccs,Ntps_ds);   lmERb1_shf=nan(Nccs,Ntps_ds,Nshf);
    146. 

  146. lmELb1LL=nan(Nccs,Ntps_ds); lmELb1LL_shf=nan(Nccs,Ntps_ds,Nshf); lmERb1LL=nan(Nccs,Ntps_ds); lmERb1LL_shf=nan(Nccs,Ntps_ds,Nshf);
    147. 

  147. lmELb1LR=nan(Nccs,Ntps_ds); lmELb1LR_shf=nan(Nccs,Ntps_ds,Nshf); lmERb1LR=nan(Nccs,Ntps_ds); lmERb1LR_shf=nan(Nccs,Ntps_ds,Nshf);
    148. 

  148. lmntrsLL=nan(Nccs,Ntps_ds); lmntrsLR=nan(Nccs,Ntps_ds);
    149. 

  149. for cc=1:Nccs
    150. 

  150.     ccoff1ev=pooloffer1ev(:,cc);
    151. 

  151.     ccoff2ev=pooloffer2ev(:,cc);
    152. 

  152. %    ccoff1sd=pooloffer1sd(:,cc);
    153. 

  153.     ccspk=squeeze(poolspksqmat_ds_bln(:,cc,:));   % For linear fit
    154. 

  154. %    ccspk=squeeze(poolspksqmat_ds(:,cc,:));      % Force NO BL correction
    155. 

  155.     ccepx=squeeze(pooleposxmat_ds(:,cc,:));      % Force NO BL correction
    156. 

  156.     rmallnans=isnan(ccoff1ev);
    157. 

  157.     rmtrials=rmallnans;%(rmallnans | ccoff1rw~=1 | ccoff2rw~=1);
    158. 

  158. %    rmtrials=(rmallnans | ccoff1sd==1); % runs only first Left
    159. 

  159. %    rmtrials=(rmallnans | ccoff1sd==0); % runs only first Right
    160. 

  160.     ccspk(rmtrials,:)=[];
    161. 

  161.     ccepx(rmtrials,:)=[];
    162. 

  162.     ccoff1ev(rmtrials)=[];
    163. 

  163.     ccoff2ev(rmtrials)=[];    
    164. 

  164.     ccntrs=size(ccspk,1);
    165. 

  165.         
    166. 

  166.     parfor tt=1:Ntps_ds
    167. 

  167.     %for tt=1:Ntps_ds
    168. 

  168.         warning('off','all')
    169. 

  169.         if vtps_ds(tt)==1 % discards low trials times
    170. 

  170.             ctspk=squeeze(ccspk(:,tt));
    171. 

  171.             ctepx=squeeze(ccepx(:,tt));
    172. 

  172. 

  173.             if ~poissfitflag
    174. 

  174.                 ctlm1=fitlm(ccoff1ev,ctspk);
    175. 

  175.                 ctlm2=fitlm(ccoff2ev,ctspk);
    176. 

  176.             else
    177. 

  177.                 ctlm1=fitglm(ccoff1ev,ctspk,'linear','Distribution','poisson');
    178. 

  178.                 ctlm2=fitglm(ccoff2ev,ctspk,'linear','Distribution','poisson');
    179. 

  179.             end
    180. 

  180.             lmELpv(cc,tt)=ctlm1.Coefficients.pValue(2);
    181. 

  181.             lmERpv(cc,tt)=ctlm2.Coefficients.pValue(2);
    182. 

  182.             lmELR2(cc,tt)=ctlm1.Rsquared.Ordinary;
    183. 

  183.             lmERR2(cc,tt)=ctlm2.Rsquared.Ordinary;
    184. 

  184.             lmELb0(cc,tt)=ctlm1.Coefficients.Estimate(1);
    185. 

  185.             lmERb0(cc,tt)=ctlm2.Coefficients.Estimate(1);
    186. 

  186.             lmELb1(cc,tt)=ctlm1.Coefficients.Estimate(2);
    187. 

  187.             lmERb1(cc,tt)=ctlm2.Coefficients.Estimate(2);
    188. 

  188.             
    189. 

  189.             isLL=find(ctepx<0);
    190. 

  190.             niLL=length(isLL);
    191. 

  191.             if ~poissfitflag
    192. 

  192.                 ctlm1LL=fitlm(ccoff1ev(isLL),ctspk(isLL));
    193. 

  193.                 ctlm2LL=fitlm(ccoff2ev(isLL),ctspk(isLL));
    194. 

  194.             else
    195. 

  195.                 ctlm1LL=fitglm(ccoff1ev(isLL),ctspk(isLL),'linear','Distribution','poisson');
    196. 

  196.                 ctlm2LL=fitglm(ccoff2ev(isLL),ctspk(isLL),'linear','Distribution','poisson');
    197. 

  197.             end
    198. 

  198.             lmELpvLL(cc,tt)=ctlm1LL.Coefficients.pValue(2);
    199. 

  199.             lmERpvLL(cc,tt)=ctlm2LL.Coefficients.pValue(2);
    200. 

  200.             lmELR2LL(cc,tt)=ctlm1LL.Rsquared.Ordinary;
    201. 

  201.             lmERR2LL(cc,tt)=ctlm2LL.Rsquared.Ordinary;
    202. 

  202.             lmELb0LL(cc,tt)=ctlm1LL.Coefficients.Estimate(1);
    203. 

  203.             lmERb0LL(cc,tt)=ctlm2LL.Coefficients.Estimate(1);
    204. 

  204.             lmELb1LL(cc,tt)=ctlm1LL.Coefficients.Estimate(2);
    205. 

  205.             lmERb1LL(cc,tt)=ctlm2LL.Coefficients.Estimate(2);
    206. 

  206.             lmntrsLL(cc,tt)=niLL;
    207. 

  207.             
    208. 

  208.             isLR=find(ctepx>0);
    209. 

  209.             niLR=length(isLR);
    210. 

  210.             if ~poissfitflag
    211. 

  211.                 ctlm1LR=fitlm(ccoff1ev(isLR),ctspk(isLR));
    212. 

  212.                 ctlm2LR=fitlm(ccoff2ev(isLR),ctspk(isLR));
    213. 

  213.             else
    214. 

  214.                 ctlm1LR=fitglm(ccoff1ev(isLR),ctspk(isLR),'linear','Distribution','poisson');
    215. 

  215.                 ctlm2LR=fitglm(ccoff2ev(isLR),ctspk(isLR),'linear','Distribution','poisson');
    216. 

  216.             end
    217. 

  217.             lmELpvLR(cc,tt)=ctlm1LR.Coefficients.pValue(2);
    218. 

  218.             lmERpvLR(cc,tt)=ctlm2LR.Coefficients.pValue(2);
    219. 

  219.             lmELR2LR(cc,tt)=ctlm1LR.Rsquared.Ordinary;
    220. 

  220.             lmERR2LR(cc,tt)=ctlm2LR.Rsquared.Ordinary;
    221. 

  221.             lmELb0LR(cc,tt)=ctlm1LR.Coefficients.Estimate(1);
    222. 

  222.             lmERb0LR(cc,tt)=ctlm2LR.Coefficients.Estimate(1);
    223. 

  223.             lmELb1LR(cc,tt)=ctlm1LR.Coefficients.Estimate(2);
    224. 

  224.             lmERb1LR(cc,tt)=ctlm2LR.Coefficients.Estimate(2);
    225. 

  225.             lmntrsLR(cc,tt)=niLR;
    226. 

  226.             
    227. 

  227.             for shf=1:Nshf
    228. 

  228.                 i1shf=randperm(ccntrs);                                   %trial-shuffle
    229. 

  229.                 i2shf=randperm(ccntrs);                                   %trial-shuffle
    230. 

  230.                 isshf=randperm(ccntrs);                                   %trial-shuffle
    231. 

  231.                 if ~poissfitflag
    232. 

  232.                     ctlm1_shf=fitlm(ccoff1ev(i1shf),ctspk(isshf));            %trial-shuffle
    233. 

  233.                     ctlm2_shf=fitlm(ccoff2ev(i2shf),ctspk(isshf));            %trial-shuffle
    234. 

  234.                 else
    235. 

  235.                     ctlm1_shf=fitglm(ccoff1ev(i1shf),ctspk(isshf),'linear','Distribution','poisson');
    236. 

  236.                     ctlm2_shf=fitglm(ccoff2ev(i2shf),ctspk(isshf),'linear','Distribution','poisson');
    237. 

  237.                 end
    238. 

  238.                 %ctlm1_shf=fitlm(ccoff1ev,squeeze(ccspk_shf(shf,:,tt))); %time-shuffle
    239. 

  239.                 %ctlm2_shf=fitlm(ccoff2ev,squeeze(ccspk_shf(shf,:,tt))); %time-shuffle
    240. 

  240.                 lmELpv_shf(cc,tt,shf)=ctlm1_shf.Coefficients.pValue(2);
    241. 

  241.                 lmERpv_shf(cc,tt,shf)=ctlm2_shf.Coefficients.pValue(2);
    242. 

  242.                 lmELR2_shf(cc,tt,shf)=ctlm1_shf.Rsquared.Ordinary;
    243. 

  243.                 lmERR2_shf(cc,tt,shf)=ctlm2_shf.Rsquared.Ordinary;
    244. 

  244.                 lmELb0_shf(cc,tt,shf)=ctlm1_shf.Coefficients.Estimate(1);
    245. 

  245.                 lmERb0_shf(cc,tt,shf)=ctlm2_shf.Coefficients.Estimate(1);
    246. 

  246.                 lmELb1_shf(cc,tt,shf)=ctlm1_shf.Coefficients.Estimate(2);
    247. 

  247.                 lmERb1_shf(cc,tt,shf)=ctlm2_shf.Coefficients.Estimate(2);
    248. 

  248.                 
    249. 

  249.                 i1LLshf=isLL(randperm(niLL));                                        %trial-shuffle
    250. 

  250.                 i2LLshf=isLL(randperm(niLL));                                        %trial-shuffle
    251. 

  251.                 isLLshf=isLL(randperm(niLL));                                        %trial-shuffle 
    252. 

  252.                 if ~poissfitflag
    253. 

  253.                     ctlm1LL_shf=fitlm(ccoff1ev(i1LLshf),ctspk(isLLshf));                 %trial-shuffle
    254. 

  254.                     ctlm2LL_shf=fitlm(ccoff2ev(i2LLshf),ctspk(isLLshf));                 %trial-shuffle
    255. 

  255.                 else
    256. 

  256.                     ctlm1LL_shf=fitglm(ccoff1ev(i1LLshf),ctspk(isLLshf),'linear','Distribution','poisson');
    257. 

  257.                     ctlm2LL_shf=fitglm(ccoff2ev(i2LLshf),ctspk(isLLshf),'linear','Distribution','poisson');
    258. 

  258.                 end
    259. 

  259.                 %ctlm1LL_shf=fitlm(ccoff1ev(isLL),squeeze(ccspk_shf(shf,isLL,tt))); %time-shuffle
    260. 

  260.                 %ctlm2LL_shf=fitlm(ccoff2ev(isLL),squeeze(ccspk_shf(shf,isLL,tt))); %time-shuffle
    261. 

  261.                 lmELpvLL_shf(cc,tt,shf)=ctlm1LL_shf.Coefficients.pValue(2);
    262. 

  262.                 lmERpvLL_shf(cc,tt,shf)=ctlm2LL_shf.Coefficients.pValue(2);
    263. 

  263.                 lmELR2LL_shf(cc,tt,shf)=ctlm1LL_shf.Rsquared.Ordinary;
    264. 

  264.                 lmERR2LL_shf(cc,tt,shf)=ctlm2LL_shf.Rsquared.Ordinary;
    265. 

  265.                 lmELb0LL_shf(cc,tt,shf)=ctlm1LL_shf.Coefficients.Estimate(1);
    266. 

  266.                 lmERb0LL_shf(cc,tt,shf)=ctlm2LL_shf.Coefficients.Estimate(1);
    267. 

  267.                 lmELb1LL_shf(cc,tt,shf)=ctlm1LL_shf.Coefficients.Estimate(2);
    268. 

  268.                 lmERb1LL_shf(cc,tt,shf)=ctlm2LL_shf.Coefficients.Estimate(2);
    269. 

  269.                 
    270. 

  270.                 i1LRshf=isLR(randperm(niLR));                                        %trial-shuffle
    271. 

  271.                 i2LRshf=isLR(randperm(niLR));                                        %trial-shuffle
    272. 

  272.                 isLRshf=isLR(randperm(niLR));                                        %trial-shuffle
    273. 

  273.                 if ~poissfitflag
    274. 

  274.                     ctlm1LR_shf=fitlm(ccoff1ev(i1LRshf),ctspk(isLRshf));                 %trial-shuffle
    275. 

  275.                     ctlm2LR_shf=fitlm(ccoff2ev(i2LRshf),ctspk(isLRshf));                 %trial-shuffle
    276. 

  276.                 else
    277. 

  277.                     ctlm1LR_shf=fitglm(ccoff1ev(i1LRshf),ctspk(isLRshf),'linear','Distribution','poisson');
    278. 

  278.                     ctlm2LR_shf=fitglm(ccoff2ev(i2LRshf),ctspk(isLRshf),'linear','Distribution','poisson');
    279. 

  279.                 end
    280. 

  280.                 %ctlm1LR_shf=fitlm(ccoff1ev(isLR),squeeze(ccspk_shf(shf,isLR,tt))); %time-shuffle
    281. 

  281.                 %ctlm2LR_shf=fitlm(ccoff2ev(isLR),squeeze(ccspk_shf(shf,isLR,tt))); %time-shuffle
    282. 

  282.                 lmELpvLR_shf(cc,tt,shf)=ctlm1LR_shf.Coefficients.pValue(2);
    283. 

  283.                 lmERpvLR_shf(cc,tt,shf)=ctlm2LR_shf.Coefficients.pValue(2);
    284. 

  284.                 lmELR2LR_shf(cc,tt,shf)=ctlm1LR_shf.Rsquared.Ordinary;
    285. 

  285.                 lmERR2LR_shf(cc,tt,shf)=ctlm2LR_shf.Rsquared.Ordinary;
    286. 

  286.                 lmELb0LR_shf(cc,tt,shf)=ctlm1LR_shf.Coefficients.Estimate(1);
    287. 

  287.                 lmERb0LR_shf(cc,tt,shf)=ctlm2LR_shf.Coefficients.Estimate(1);
    288. 

  288.                 lmELb1LR_shf(cc,tt,shf)=ctlm1LR_shf.Coefficients.Estimate(2);
    289. 

  289.                 lmERb1LR_shf(cc,tt,shf)=ctlm2LR_shf.Coefficients.Estimate(2);
    290. 

  290.             end
    291. 

  291.         end
    292. 

  292.         warning('on','all')
    293. 

  293.     end
    294. 

  294.     disp([sprintf('%s',datetime('now','Format','HH:mm')) ' - done: ' num2str(cc) '/' num2str(Nccs) ', ' num2str(cc/Nccs.*100) '%']);
    295. 

  295. end
    296. 

  296.     save(['fitlmstats_span_' num2str(Nspan) 'ms_lag_' num2str(Nlag) 'ms_' date '.mat'],'lmE*','lmntr*');
    297. 

  297. else
    298. 

  298.     load(['fitlmstats_span_' num2str(Nspan) 'ms_lag_' num2str(Nlag) 'ms_16-Feb-2023.mat']);
    299. 

  299. end
    300. 

  300. 

  301. 

  302. %% Plot colors
    303. 

  303. o1col=[55 188 52]/255;
    304. 

  304. o2col=[55 131 200]/255;
    305. 

  305. o3col=[121 121 121]/255;
    306. 

  306. 

  307. o1LLcol=[50 148 48]/255;
    308. 

  308. o2LLcol=[55 97 135]/255;
    309. 

  309. o3LLcol=[43 43 43]/255;
    310. 

  310. 

  311. o1LRcol=[135 215 133]/255;
    312. 

  312. o2LRcol=[144 187 226]/255;
    313. 

  313. o3LRcol=[168 168 168]/255;
    314. 

  314. 

  315. %% Fig 3B - Time-resolved fraction of significant cells
    316. 

  316. for ss=1:3
    317. 

  317. if ss==1; cc2p=1:sum(nccs(1:4)); elseif ss==2; cc2p=(sum(nccs(1:4))+1):Nccs; else; cc2p=1:Nccs; end
    318. 

  318. hfig=figure('units','normalized','position',[0 0 1 1]);
    319. 

  319. subplot(3,1,1); hold on;
    320. 

  320. plotcmapdots([o1col; o2col]);
    321. 

  321. runlength(mean(lmELpv(cc2p,vtps_ds==1)<0.05,1),squeeze(mean(lmELpv_shf(cc2p,vtps_ds==1,:)<0.05,1)),1,rtmax_ds,o1col,.005); 
    322. 

  322. runlength(mean(lmERpv(cc2p,vtps_ds==1)<0.05,1),squeeze(mean(lmERpv_shf(cc2p,vtps_ds==1,:)<0.05,1)),1,rtmax_ds,o2col,.010); 
    323. 

  323. for jj=1:8; plot([1 1].*sum(rtmes_ds(1:jj)),[0 0.2],'k:'); text(sum(rtmes_ds(1:jj-1)),.2,twLabels{jj}); end
    324. 

  324. hl=legend({'E(L)','E(R)'}); ylim([0 0.2]); box(hl,'on');
    325. 

  325. 

  326. subplot(3,1,2);
    327. 

  327. plotcmapdots([o1LLcol; o1LRcol]);
    328. 

  328. runlength(mean(lmELpvLL(cc2p,vtps_ds==1)<0.05,1),squeeze(mean(lmELpvLL_shf(cc2p,vtps_ds==1,:)<0.05,1)),1,rtmax_ds,o1LLcol,.005); 
    329. 

  329. runlength(mean(lmELpvLR(cc2p,vtps_ds==1)<0.05,1),squeeze(mean(lmELpvLR_shf(cc2p,vtps_ds==1,:)<0.05,1)),1,rtmax_ds,o1LRcol,.010); 
    330. 

  330. for jj=1:8; plot([1 1].*sum(rtmes_ds(1:jj)),[0 0.2],'k:'); text(sum(rtmes_ds(1:jj-1)),.2,twLabels{jj}); end
    331. 

  331. hl=legend({'E(L), Look L','E(L), Look R'}); box(hl,'on'); ylim([0 0.2]);
    332. 

  332. 

  333. subplot(3,1,3);
    334. 

  334. plotcmapdots([o2LLcol; o2LRcol]);
    335. 

  335. runlength(mean(lmERpvLL(cc2p,vtps_ds==1)<0.05,1),squeeze(mean(lmERpvLL_shf(cc2p,vtps_ds==1,:)<0.05,1)),1,rtmax_ds,o2LLcol,.005); 
    336. 

  336. runlength(mean(lmERpvLR(cc2p,vtps_ds==1)<0.05,1),squeeze(mean(lmERpvLR_shf(cc2p,vtps_ds==1,:)<0.05,1)),1,rtmax_ds,o2LRcol,.010); 
    337. 

  337. for jj=1:8; plot([1 1].*sum(rtmes_ds(1:jj)),[0 0.2],'k:'); text(sum(rtmes_ds(1:jj-1)),.2,twLabels{jj}); end
    338. 

  338. hl=legend({'E(R), Look L','E(R), Look R'}); box(hl,'on'); ylim([0 0.2]);
    339. 

  339. 

  340. if ss<3; supertitle(['Subject ' num2str(ss)]); else; supertitle('Both Subjects'); end
    341. 

  341. saveas(hfig,[figures_folder '/perc_sig_cells_pv_s' num2str(ss) '.png']);
    342. 

  342. saveas(hfig,[figures_folder '/perc_sig_cells_pv_s' num2str(ss) '.svg']);
    343. 

  343. 

  344. end
    345. 

  345. 

  346. %% Fig 3C - Time-averaged fractions of significant cells
    347. 

  347. for ss=1:3
    348. 

  348. if ss==1; cc2p=1:sum(nccs(1:4)); elseif ss==2; cc2p=(sum(nccs(1:4))+1):Nccs; else; cc2p=1:Nccs; end
    349. 

  349. hfig=figure('units','normalized','position',[0 0 1 1]);
    350. 

  350. for tw=1:8
    351. 

  351. subplot(3,1,1); plotcmapdots([o1col; o2col]); ylim([0 .15]);
    352. 

  352.     nnm1=nanmean(lmELpv_shf(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,1); 
    353. 

  353.     nnm2=nanmean(lmERpv_shf(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,1);
    354. 

  354.     prc051=prctile(nnm1,05,3); prc951=prctile(nnm1,95,3);
    355. 

  355.     prc052=prctile(nnm2,05,3); prc952=prctile(nnm2,95,3);
    356. 

  356.     alpha1=0.05+(mean(nanmean(lmELpv(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,2))>mean(prc951)).*.95;
    357. 

  357.     alpha2=0.05+(mean(nanmean(lmERpv(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,2))>mean(prc952)).*.95; 
    358. 

  358.     barmsem(tw-.125,nanmean(lmELpv(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),o1col,.1,'none',1,alpha1);
    359. 

  359.     barmsem(tw+.125,nanmean(lmERpv(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),o2col,.1,'none',1,alpha2); 
    360. 

  360.     plot(tw-.125+[-.1 .1],[1 1].*mean(prc051,2),'k:'); plot(tw-.125+[-.1 .1],[1 1].*mean(prc951,2),'k:');
    361. 

  361.     plot(tw+.125+[-.1 .1],[1 1].*mean(prc052,2),'k:'); plot(tw+.125+[-.1 .1],[1 1].*mean(prc952,2),'k:');
    362. 

  362.     text(tw-.1,0.14,getpstars(signrank(nanmean(lmELpv(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),...
    363. 

  363.                                        nanmean(lmERpv(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2))));
    364. 

  364.         
    365. 

  365. subplot(3,1,2); plotcmapdots([o1LLcol; o1LRcol]); ylim([0 .15]);
    366. 

  366.     nnm1=nanmean(lmELpvLL_shf(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05); 
    367. 

  367.     nnm2=nanmean(lmELpvLR_shf(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05);
    368. 

  368.     prc051=prctile(nnm1,05,3); prc951=prctile(nnm1,95,3);
    369. 

  369.     prc052=prctile(nnm2,05,3); prc952=prctile(nnm2,95,3);
    370. 

  370.     alpha1=0.05+(mean(nanmean(lmELpvLL(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,2))>mean(prc951)).*.95;
    371. 

  371.     alpha2=0.05+(mean(nanmean(lmELpvLR(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,2))>mean(prc952)).*.95;  
    372. 

  372.     barmsem(tw-.125,nanmean(lmELpvLL(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),o1LLcol,.1,'none',1,alpha1);
    373. 

  373.     barmsem(tw+.125,nanmean(lmELpvLR(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),o1LRcol,.1,'none',1,alpha2);    
    374. 

  374.     plot(tw-.125+[-.1 .1],[1 1].*mean(prc051,2),'k:'); plot(tw-.125+[-.1 .1],[1 1].*mean(prc951,2),'k:');
    375. 

  375.     plot(tw+.125+[-.1 .1],[1 1].*mean(prc052,2),'k:'); plot(tw+.125+[-.1 .1],[1 1].*mean(prc952,2),'k:');
    376. 

  376.     text(tw-.1,0.14,getpstars(signrank(nanmean(lmELpvLL(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),...
    377. 

  377.                                        nanmean(lmELpvLR(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2))));
    378. 

  378.     
    379. 

  379. subplot(3,1,3); plotcmapdots([o2LLcol; o2LRcol]); ylim([0 .15]);
    380. 

  380.     nnm1=nanmean(lmERpvLL_shf(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05); 
    381. 

  381.     nnm2=nanmean(lmERpvLR_shf(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05);
    382. 

  382.     prc051=prctile(nnm1,05,3); prc951=prctile(nnm1,95,3);
    383. 

  383.     prc052=prctile(nnm2,05,3); prc952=prctile(nnm2,95,3);
    384. 

  384.     alpha1=0.05+(mean(nanmean(lmERpvLL(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,2))>mean(prc951)).*.95;
    385. 

  385.     alpha2=0.05+(mean(nanmean(lmERpvLR(cc2p,ntce_ds(tw,1):ntce_ds(tw,2),:)<0.05,2))>mean(prc952)).*.95;  
    386. 

  386.     barmsem(tw-.125,nanmean(lmERpvLL(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),o2LLcol,.1,'none',1,alpha1);
    387. 

  387.     barmsem(tw+.125,nanmean(lmERpvLR(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),o2LRcol,.1,'none',1,alpha2);    
    388. 

  388.     plot(tw-.125+[-.1 .1],[1 1].*mean(prc051,2),'k:'); plot(tw-.125+[-.1 .1],[1 1].*mean(prc951,2),'k:');
    389. 

  389.     plot(tw+.125+[-.1 .1],[1 1].*mean(prc052,2),'k:'); plot(tw+.125+[-.1 .1],[1 1].*mean(prc952,2),'k:');
    390. 

  390.     text(tw-.1,0.14,getpstars(signrank(nanmean(lmERpvLL(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2),...
    391. 

  391.                                        nanmean(lmERpvLR(cc2p,ntce_ds(tw,1):ntce_ds(tw,2))<0.05,2))));
    392. 

  392. 

  393. end
    394. 

  394. if ss<3; supertitle(['Subject ' num2str(ss)]); else supertitle('Both subjects'); end
    395. 

  395. saveas(hfig,[figures_folder '/timewins_sig_in_time_pv_subj' num2str(ss) '.png']);
    396. 

  396. saveas(hfig,[figures_folder '/timewins_sig_in_time_pv_subj' num2str(ss) '.svg']);
    397. 

  397. end
    398. 

  398. 

  399. 

  400. %% Supp. Fig. 8A - R2 for the linear regression
    401. 

  401. 

  402. cc2p=1:Nccs;
    403. 

  403. hfig=figure('units','normalized','position',[0 0 1 1]);
    404. 

  404. subplot(3,1,1); plotcmapdots([o1col; o2col]);
    405. 

  405. runlength(nanmean(lmELR2(cc2p,vtps_ds==1),1),squeeze(nanmean(lmELR2_shf(cc2p,vtps_ds==1,:),1)),1,rtmax_ds*10,o1col,.0002); 
    406. 

  406. runlength(nanmean(lmERR2(cc2p,vtps_ds==1),1),squeeze(nanmean(lmERR2_shf(cc2p,vtps_ds==1,:),1)),1,rtmax_ds*10,o2col,.0004); 
    407. 

  407. for jj=1:8; plot([1 1].*sum(rtmes_ds(1:jj))*10,[0 0.01],'k:'); text(sum(rtmes_ds(1:jj-1))*10,.005,twLabels{jj}); end
    408. 

  408. hl=legend({'E(L)','E(R)'}); box(hl,'on'); ylim([0 0.005]);
    409. 

  409. 

  410. subplot(3,1,2); plotcmapdots([o1LLcol; o1LRcol]);
    411. 

  411. runlength(nanmean(lmELR2LR(cc2p,vtps_ds==1),1),squeeze(nanmean(lmELR2LR_shf(cc2p,vtps_ds==1,:),1)),1,rtmax_ds*10,o1LRcol,.0002); 
    412. 

  412. runlength(nanmean(lmELR2LL(cc2p,vtps_ds==1),1),squeeze(nanmean(lmELR2LL_shf(cc2p,vtps_ds==1,:),1)),1,rtmax_ds*10,o1LLcol,.0004); 
    413. 

  413. for jj=1:8; plot([1 1].*sum(rtmes_ds(1:jj))*10,[0 0.02],'k:'); text(sum(rtmes_ds(1:jj-1))*10,.02,twLabels{jj}); end
    414. 

  414. hl=legend({'E(L), Look L','E(L), Look R'}); box(hl,'on'); ylim([0 0.025]);
    415. 

  415. 

  416. subplot(3,1,3); plotcmapdots([o2LLcol; o2LRcol]); 
    417. 

  417. runlength(nanmean(lmERR2LR(cc2p,vtps_ds==1),1),squeeze(nanmean(lmERR2LR_shf(cc2p,vtps_ds==1,:),1)),1,rtmax_ds*10,o2LRcol,.0002); 
    418. 

  418. runlength(nanmean(lmERR2LL(cc2p,vtps_ds==1),1),squeeze(nanmean(lmERR2LL_shf(cc2p,vtps_ds==1,:),1)),1,rtmax_ds*10,o2LLcol,.0004); 
    419. 

  419. for jj=1:8; plot([1 1].*sum(rtmes_ds(1:jj))*10,[0 0.02],'k:'); text(sum(rtmes_ds(1:jj-1))*10,.02,twLabels{jj}); end
    420. 

  420. hl=legend({'E(R), Look L','E(R), Look R'}); box(hl,'on'); ylim([0 0.025]);
    421. 

  421. xlabel('task time (ms)');
    422. 

  422. 

  423. saveas(hfig,[figures_folder '/R2_vs_R2shf_ELER_sig_in_time.png']);
    424. 

  424. saveas(hfig,[figures_folder '/R2_vs_R2shf_ELER_sig_in_time.svg']);
    425.