-
Notifications
You must be signed in to change notification settings - Fork 2
/
kurtosis_fit.m
135 lines (117 loc) · 4.16 KB
/
kurtosis_fit.m
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
function [S,Dapp,Kapp,SSE,rsquare] = kurtosis_fit(selection,bvec,allb)
%%%%%%%%
% This program calculates S, Dapp, Kapp, SSE and rsquare for each voxel in the
% input matrix "selection". The program uses the kurtosis aproach from
% the article. Fit model from http://doi.org/10.1002/mrm.20508
%
% Input:
% Selection = n*m matrix, where the first dimension includes the data from
% the different voxels and the second dimension is the data as function of
% bvalues.
%
% bvec = a vector containing the b-values of each data point. Must be m
% long
%
% allb = 1 or 0; 1 means all b-values are taken along seperately in the
% fit, whereas 0 means b-value data is grouped and weighted according to
% the number of acquisitions per b-value. This is only important for data
% where multiple acquisitions occured per b-value (i.e. DTI data)
%
%
% Output (m long vectors, repressenting the voxel values):
% S = signal at b=0 s/mm2 (fitted)
%
% Dapp = apparent diffusion coefficient distribution maxima
%
% Kapp = apparant diffusion kurtosis
%
% SSE = sum square due to error
%
% rsquare = adjusted R-squared
%
% We advice not to take along all data (i.e. let data be a o*p*q*m
% matrix which repressents a 3D o*p*q voxel space with a 4th b-value
% dimension (m);
% alldata=reshape(data,size(data,1)*size(data,2)*size(data,3),size(data,4)),
% but to mask your data before
% using IVIM fixed (i.e. selection=alldata(mask)).
%%
%
% Code is written by Oliver Gurney-Champion
%
%%
%%%%%%%%%
% fit constraints [initial guess, min, max]
Kappcon=[0, 0.0005, 10];
Dappcon=[0.0014, 0, 0.014];
%% here the data is sorted in blocks of b-values. If allb=0, the average signal intensity per b-value is taken for repeated measures in that b-value in order to speed fitting.
fail=0;
if allb==1
[bvec, order]=sort(bvec);
selection=selection(:,order);
selection=transpose(selection);
else
a=unique(bvec);
weights=zeros(size(a,2),1);
for ii=1:size(weights,1)
weights(ii)=sum(bvec==a(ii));
end
weights=round(weights/min(weights));
bvec=a;
selection=transpose(selection);
qq=1;
for ii=1:size(bvec,2)
for kk=1:weights(ii)
bvec2(qq)=bvec(ii);
selection2(qq,:)=selection(ii,:);
qq=qq+1;
end
end
%% updating data en b-vector in case data is averaged
bvec=bvec2;
selection=selection2;
clear selection2 bvec2
end
%% initiating parameters
ssel=size(selection);
S=zeros(ssel(2),1);
Dapp=zeros(ssel(2),1);
Kapp=zeros(ssel(2),1);
SSE=zeros(ssel(2),1);
rsquare=zeros(ssel(2),1);
bvecbu=transpose(bvec);
%% looping over voxels. Can be parfor loop in case of 1 patient. I use parfor over the patients to minimize overhead.
for k=1:ssel(2)
try
bvec=bvecbu;
data1=selection(:,k);
% when data is missing (0), through away in fit. Data can be missing due to registration of data at edge of FOV for specific b-values. Furthermore, data can be masked for bad slices effected by heartbeats. A masking method was described in http://doi.org/10.1097/RLI.0000000000000225
bvec(data1==0)=[];
data1(data1==0)=[];
% fitoptions
kurts=fitoptions('Method','NonlinearLeastSquares','robust','on','Startpoint',[Dappcon(1) Kappcon(1) data1(1)],'Lower',[Dappcon(2) Kappcon(2) 0],'Upper',[Dappcon(3) Kappcon(3) 100000],'MaxIter',1000);
% fit model from http://doi.org/10.1002/mrm.20508
modelkurt=fittype('a*exp(-x*D+x^2*D^2*K/6)','options',kurts);
% fit
[c21, gof]=fit(bvec,data1,modelkurt);
Dapp(k)=c21.D;
S(k)=c21.a;
Kapp(k)=c21.K;
SSE(k)=gof.sse;
rsquare(k)=gof.adjrsquare;
catch err
% in case an error occured, give negative number and add 1 to fail
err.message
Dapp(k)=-0.00001;
S(k)=-0.00001;
Kapp(k)=-0.00001;
SSE(k)=-0.00001;
rsquare(k)=-0.00001;
fail=fail+1;
end
end
% when voxels are rejected (i.e. 0), then the fit will fail due to too many
% variables compared to data. This will tell you how often that occured.
sprintf('%d pixels failed due to too much rejection',fail)
end