% First read the data using:
%
% readTenFSAllupstateDataStandard.m
%
% This code assumes there are just two sets of configurations
% one with the 0.5nS GJ resistance, and one without any GJ (ref).
%
close all
nBinsHist = 501
uNumGaps = unique(numGaps);
clear numDiffs numSCCC edges
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%First we need to recover the connection matrix
%
for fileCtr = 1:length(savedSpikeTimes)
if(numGaps(fileCtr) == 0)
% No gap junctions
for cellCtr = 1:length(savedSpikeTimes{fileCtr})
selfSpikes{fileCtr}(cellCtr) = length(savedSpikeTimes{fileCtr}{cellCtr});
spikeTrig{fileCtr}(cellCtr) = 0;
end
continue;
end
coMat{fileCtr} = zeros([1 1]*length(savedSpikeTimes{fileCtr}));
% Reconstruct the connection matrix cMat
for gapCtr = 1:numGaps(fileCtr)
srcIdx = textscan(gapSource{fileCtr}{gapCtr}{1},'/fs[%d]');
destIdx = textscan(gapDest{fileCtr}{gapCtr}{1},'/fs[%d]');
% +1 since matlab indexing starts from 1, not 0
coMat{fileCtr}(srcIdx{1}+1,destIdx{1}+1) = ...
coMat{fileCtr}(srcIdx{1}+1,destIdx{1}+1) + 1;
%keyboard
end
% Each GJ only appears ones in the connection matrix
% This code makes it appear twice, dont use it for cross correlogram
% coMat{fileCtr} = coMat{fileCtr} + coMat{fileCtr}';
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
for iGap = 1:length(uNumGaps)
disp(sprintf('Processing %d gap junctions..',uNumGaps(iGap)))
iGJ = find(numGaps == uNumGaps(iGap));
if(length(unique(gapResistance(iGJ))) > 1)
disp('More than one GJ resistance used... not supported here')
keyboard
end
combCtr = 1;
if(uNumGaps(iGap) == 0)
for i=1:length(iGJ);
runIdx = iGJ(i);
for cellA = 1:length(savedSpikeTimes{runIdx})
% for cellB = (cellA + 1):length(savedSpikeTimes{runIdx})
% We run a subproportion of the combinations
randPB = randperm(length(savedSpikeTimes{runIdx}));
disp(sprintf('CellA = %d',cellA))
for cellB = randPB(1:10)
if(cellA == cellB)
% Dont match it against itself
continue
end
[numSCCC{iGap}(:,combCtr), ...
numDiffs{iGap}(:,combCtr), ...
edges{iGap}(:,combCtr)] = ...
makeSCCCplot(savedSpikeTimes, runIdx, cellA, ...
savedSpikeTimes, runIdx, cellB, ...
maxTime(runIdx), nBinsHist, 0);
% MODIFIKATION: Dela med maxtiden för att få frekvens
numDiffs{iGap}(:,combCtr) = numDiffs{iGap}(:,combCtr) ...
/ maxTime(runIdx);
combCtr = combCtr + 1;
end
end
end
continue
end
%%%%%%%%%%%%%%
for i = 1:length(iGJ)
runIdx = iGJ(i);
for cellA = 1:length(savedSpikeTimes{runIdx})
% for cellB = (cellA + 1):length(savedSpikeTimes{runIdx})
% We run a subproportion of the combinations
randPB = randperm(length(savedSpikeTimes{runIdx}));
disp(sprintf('CellA = %d',cellA))
for cellB = randPB(1:10)
if(cellA == cellB)
% Dont match it against itself
continue
end
[numSCCC{iGap}(:,combCtr), ...
numDiffs{iGap}(:,combCtr), ...
edges{iGap}(:,combCtr)] = ...
makeSCCCplot(savedSpikeTimes, runIdx, cellA, ...
savedSpikeTimes, runIdx, cellB, ...
maxTime(runIdx), nBinsHist, 0);
% MODIFIKATION: Dela med maxtiden för att få frekvens
numDiffs{iGap}(:,combCtr) = numDiffs{iGap}(:,combCtr) ...
/ maxTime(runIdx);
combCtr = combCtr + 1;
end
end
end
end
for i=1:length(numDiffs)
meanCC{i} = mean(numDiffs{i},2);
stdErrCC{i} = std(numDiffs{i},0,2)/sqrt(size(numDiffs{i},2)-1);
end
ccEdges = edges{i}(:,1);
% Plotta
figure, clf
clear pHand
for i=1:length(numDiffs)
pHand(i) = subplot(length(numDiffs),1,length(numDiffs)-i+1);
bar(ccEdges, meanCC{i},'histc')
xlabel('Time (s)')
% ylabel('Frequency (Hz)')
ylabel('Occurances (s^{-1})')
if(uNumGaps(i) > 0)
title('Gap junction coupled')
else
title('Uncoupled')
end
a = axis;
a(1) = min(ccEdges); a(2) = max(ccEdges);
axis(a);
end
linkprop(pHand,'Ylim');
saveas(pHand(1), ['FIGS/LARGE-allUpstateStandard-RAWcc-AllToAll.fig'], 'fig')
%%%%%%%%%%%%
figure
clear pHand pLeg
cm = colormap;
lineCol = interp1(linspace(0,1,size(cm,1)),cm,linspace(0,1,length(numDiffs)));
for i=1:length(numDiffs)
% pHand(i) = bar(1e3*ccEdges, meanCC{i},'histc'), hold on
pHand(i) = stairs(1e3*ccEdges, meanCC{i}, 'color',lineCol(i,:)); hold on
if(uNumGaps(i) > 0)
pLeg{i} = sprintf('%d gap junctions', uNumGaps(i)*2/numCells(1));
else
pLeg{i} = 'Uncoupled';
end
end
nGJ = uNumGaps*2/numCells(1);
a = axis;
a(1) = -50; a(2) = 50;
axis(a);
legend(pHand,pLeg)
box off
xlabel('Time (ms)')
%ylabel('Frequency (Hz)')
ylabel('Occurances (s^{-1})')
saveas(pHand(1), ['FIGS/LARGE-allUpstateStandard-RAWcc-AllInOneFINER-AllToAll.fig'], 'fig')
curPath = pwd;
cd(filePath)
save crossCorrDataAllToAll.mat nGJ ccEdges meanCC
cd(curPath)