Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

In one of my GUIs I load DICOM images. Sometimes they are just a volume and another dimension and when I load them in Matlab everything ends up where I want it.

handles.inf = dicominfo([filepath filename]);
handles.dat = dicomread(handles.inf);

ans = 128 128 128 512

For an 128 by 128 by 128 volume at 512 timepoints for example (actually the third dimension would not even be 128, the third dimension is stacks, of which I dont know what it is). However sometimes There are more dimensions in the dicom, but the reader just puts all of them in the fourth dimension.

handles.inf = dicominfo([filepath filename]);
handles.dat = dicomread(handles.inf);

ans = 128 128 1  4082

For a single 128 by 128 slice with 512 timepoints, two echoes and magnitude, phase, real and imaginary data for example.

It is then very hard to unscramble them. Manually I can do this for every dicom I load but when in a GUI I would want to have a general approach that just creates a dimension in the array for each dimension in the dicom.

This is especially important not just for data-analysis, but also to transform the coordinates from image space to patient space. My own approach was to look at the header, but theres no guarantee that certain entries will work, and the order in which they are applied I cant find. The header entries I found so far:

inf.Columns;% inf.height; % inf.NumberOfKSpaceTrajectories;
inf.MRSeriesReconstructionNumber % not sure about this one

reshapeddat = reshape(dat, [all dimension sizes from header here]);

Im not sure how to check if Ive got all variables and what the right order for the reshape. Anybody knows of a sure-fire way to get all dimension sizes from the DICOM header and the order in which they are stacked?

share|improve this question
The dicomread documentation says: "For single-frame grayscale images, X is an M-by-N array. For single-frame true-color images, X is an M-by-N-by-3 array. Multiframe images are always 4-D arrays." It appears the third dimension is either 1 or 3, and possibly never refers to the number of slices in a volume; I guess slices always end up in the fourth dimension. But if you can determine the number of slices and/or the number of timepoints from the header, reshape should be the way to go. –  A. Donda Feb 13 '14 at 16:43
Ah yes, I think reshape is the way to go too. However it then is the problem to get all non-singleton dimensions from the header and then get them in the right order. Got an idea how to do that? –  Leo Feb 13 '14 at 16:56
Well, you can get the dimensions of the frame, m and n, from the first two dimensions of the output, and I'd guess the number of slices from inf.MRSeriesNrOfSlices. Then use reshape(dat, m, n, inf.MRSeriesNrOfSlices, []) –  A. Donda Feb 13 '14 at 17:00
In case this happens to be the answer, I'll post it as such. But I don't have any DICOM files to check... ;-) –  A. Donda Feb 13 '14 at 17:03
Alas, thats not the answer. That would be the answer if there would be only one extra dimension with the three spatial ones. But I always have datasets with more dimensions than that, but not always the same number of dimensions. So thats why I would need a general solution instead of a case specific one. –  Leo Feb 14 '14 at 7:44

1 Answer 1

up vote 0 down vote accepted

Ok so I now manually go by all possible dimensions. When a stack also contains reconstructed data which has less dimensions than the rest, remove those first.

This is how I check the dimensions:

info = dicominfo(filename);
datorig = dicomread(filename);

%dimension sizes per frame
nrX = double(info.Rows);              %similar nX;% info.width;% info.MRAcquisitionFrequencyEncodingSteps;% info.MRAcquisitionPhaseEncodingStepsInPlane
nrY = double(info.Columns);           %similar nY;% info.height;% info.NumberOfKSpaceTrajectories;

%dimensions between frames
nrEcho = double(info.MRSeriesNrOfEchoes);
nrDyn = double(info.MRSeriesNrOfDynamicScans);
nrPhase = double(info.MRSeriesNrOfPhases);
nrSlice = double(info.MRSeriesNrOfSlices);           %no per frame struct entry, calculate from offset.

%nr of frames
nrFrame = double(info.NumberOfFrames);

nrSeq = 1;                                   % nSeq not sure how to interpret this, wheres the per frame struct entry?
nrBval = double(info.MRSeriesNrOfDiffBValues);        % nB
nrGrad = double(info.MRSeriesNrOfDiffGradOrients);    % info.MRSeriesNrOfPhaseContrastDirctns;%similar nGrad?
nrASL = 1;                                   % info.MRSeriesNrOfLabelTypes;%per frame struct entry?

imtype = cell(1, nrFrame);
for ii = 1:nrFrame
    %imtype(ii) = eval(sprintf('info.PerFrameFunctionalGroupsSequence.Item_%d.PrivatePerFrameSq.Item_1.MRImageTypeMR', ii));
    imtype{ii} = num2str(eval(sprintf('info.PerFrameFunctionalGroupsSequence.Item_%d.PrivatePerFrameSq.Item_1.MRImageTypeMR', ii)));

imType = unique(imtype, 'stable');
nrType = length(imType);

This is how I reformat the dimensions:

%% count length of same dimension positions from start
if nrEcho > 1
    for ii = 1:nrFrame
        imecno(ii) = eval(sprintf('inf.PerFrameFunctionalGroupsSequence.Item_%d.PrivatePerFrameSq.Item_1.EchoNumber', ii));
    lenEcho = find(imecno ~= imecno(1), 1, 'first') - 1;
    lenEcho = nrFrame;

if nrDyn > 1
    for ii = 1:nrFrame
        imdynno(ii) = eval(sprintf('inf.PerFrameFunctionalGroupsSequence.Item_%d.PrivatePerFrameSq.Item_1.TemporalPositionIdentifier', ii));
    lenDyn = find(imdynno ~= imdynno(1), 1, 'first') - 1;
    lenDyn = nrFrame;

if nrPhase > 1
    for ii = 1:nrFrame
        imphno(ii) = eval(sprintf('inf.PerFrameFunctionalGroupsSequence.Item_%d.PrivatePerFrameSq.Item_1.MRImagePhaseNumber', ii));
    lenPhase = find(imphno~=imphno(1), 1, 'first') - 1;
    lenPhase = nrFrame;

if nrType > 1
    q = 1;
    imtyno(1, 1) = q;
    for ii = 2:nrFrame        
        if imtype{:, ii-1} ~= imtype{:, (ii)}
            q = q+1;
        imtyno(1, ii) = q;
        %for jj = 1:nrType
            %if imtype{:,ii} == imType{:,jj} 
            %    imtyno(1, ii) = jj;
    if q ~= nrType
        nrType = q;
    lenType = find(imtyno ~= imtyno(1), 1, 'first') - 1;
    lenType = nrFrame;

% slices are not numbered per frame, so get this indirectly from location
% currently not sure if working for all angulations
for ii = 1:nrFrame
    imslice(:,ii) =  -eval(['inf.PerFrameFunctionalGroupsSequence.Item_',sprintf('%d', ii),'.PlanePositionSequence.Item_1.ImagePositionPatient']);

% stdsl = std(imslice,[],2); --> Assumption
% dirsl = max(find(stdsl == max(stdsl)));
imslices = unique(imslice', 'rows')';
if nrSlice > 1
    for ii = 1:nrFrame
        for jj = 1:nrSlice
            if imslice(:,ii) == imslices(:,nrSlice - (jj-1)); %dirsl or :?
                imslno(1, ii) = jj;
    lenSlice = find(imslno~=imslno(1), 1, 'first')-1;
    lenSlice = nrFrame;

if nrBval > 1
    for ii = 1:nrFrame
        imbno(ii) = eval(sprintf('inf.PerFrameFunctionalGroupsSequence.Item_%d.PrivatePerFrameSq.Item_1.MRImageDiffBValueNumber', ii));
    lenBval = find(imbno~=imbno(1), 1, 'first') - 1;
    lenBval = nrFrame;

if nrGrad > 1
    for ii = 1:nrFrame
        imgradno(ii) = eval(sprintf('inf.PerFrameFunctionalGroupsSequence.Item_%d.PrivatePerFrameSq.Item_1.MRImageGradientOrientationNumber', ii));
    lenGrad = find(imgradno~=imgradno(1), 1, 'first')-1;
    lenGrad = inf.NumberOfFrames;

lenSeq = nrFrame; % dont know how to get this information per frame, in my case always one
lenASL = nrFrame; % dont know how to get this information per frame, in my case always one

%this would have been the goal format
goaldim = [nrSlice nrEcho nrDyn nrPhase nrType nrSeq nrBval nrGrad nrASL];             % what we want
goallen = [lenSlice lenEcho lenDyn lenPhase lenType lenSeq lenBval lenGrad lenASL];    % what they are

[~, permIX] = sort(goallen);

dicomdim = zeros(1, 9);
for ii = 1:9
    dicomdim(1, ii) = goaldim(permIX(ii));

dicomdim = [nrX nrY dicomdim];
%for any possible zero dimensions from header use a 1 instead
dicomdim(find(dicomdim == 0)) = 1;

newdat = reshape(dat, dicomdim);

newdim = size(newdat);
newnonzero = length(newdim(3:end));
goalnonzero = permIX(1:newnonzero);
[dummyy, goalIX] = sort(goalnonzero);
goalIX = [1 2 goalIX+2]; 
newdat = permute(newdat, goalIX);
newdat = reshape(newdat, [nrX nrY goaldim]);

When Ive used this as a function for a longer period and debugged it a bit I might post in on the file exchange of mathworks.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.