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Contrasts (a revision of t and F contrasts by a very dummyish Martha) & Basis Functions (by a much less dummyish Iroise!)

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Presentation on theme: "Contrasts (a revision of t and F contrasts by a very dummyish Martha) & Basis Functions (by a much less dummyish Iroise!)"— Presentation transcript:

1 Contrasts (a revision of t and F contrasts by a very dummyish Martha) & Basis Functions (by a much less dummyish Iroise!)

2 Outline Contrasts –What do contrasts do? –t contrasts (with SPM example) –F contrasts Basis Functions –What’s a basis? –Basis functions in SPM –Example of contrasts with basis functions

3 What do contrasts do? GLM characterises relationships between our experimental manipulations and the observed data - multiple effects all within the same design matrix. So to focus in on a particular characteristic, condition, or regressor we use contrasts… t-tests: tell us whether there is a significant increase or decrease in the contrast specified F-tests: tell us whether there is a significant difference between the conditions in the contrast (the effect of a group of regressors)

4 A new example! See 2003 and 2004 presentations for the first (very good) example from Chapter 8 HBF. This is for a change… Two event related conditions The subject presses a button with either their left or right hand depending on a visual instruction We are interested in finding the brain regions that respond more to left than right motor movement

5 t contrasts To find the brain regions corresponding more to left than right motor responses we use the contrast: T = [1 -1 0] Left Right Mean

6 t contrasts A one dimensional contrast T = contrast of estimated parameters variance estimate T = s 2 c’(X’X) + c c’b So, for a contrast in our model of 1 -1 0: T = (ß1x1 + ß2x-1 + ß3x 0) Estimated variance

7 Left motor responses... This shows activation of the contralateral motor cortex, ipsilateral cerebellum etc

8 So how do I do that in SPM?

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14 t contrasts To find the brain regions corresponding more to trials than time between trials (which would presumably give visual areas?) you could either: 1) create a new model with one regressor for responses (right and left) [1 0] 2) or do a conjunction of [1 0 0] and [0 1 0] on the existing model to look for common areas of activation

15 F contrasts T contrasts are directional To test for the overall difference (positive or negative) between left and right responses compared to baseline we use: [ 1 0 0 0 1 0 ] Left Right Mean

16 F-test To test a hypothesis about general effects, independent of the direction of the contrast A collection of t contrasts that you want to test together F = error variance estimate additional variance accounted for by tested effects

17 Areas involved in pressing (left or right) either more or less active in pressing vs not pressing (as non-directional)

18 A more complex example 2 x 3 model with words presented visually (V) or aurally (A), and belonging to three different categories (C1, C2, C3) VC1 VC2 VC3 AC1 AC2 AC3

19 To test for the main effect of modality we use the contrast [ 1 0 0 -1 0 0 0 0 1 0 0 -1 0 0 0 0 1 0 0 -1 0 ] VC1 VC2 VC3 AC1 AC2 AC3

20 To test for the main effect of category we use the contrast [ 1 -1 0 1 -1 0 0 0 1 -1 0 1 -1 0 ] VC1 VC2 VC3 AC1 AC2 AC3

21 To test for the interaction we use the contrast [ 1 -1 0 -1 1 0 0 0 1 -1 0 -1 1 0 ] VC1 VC2 VC3 AC1 AC2 AC3

22 Basis Functions

23 What’s a basis ? Can be used to describe any point in space. e.g. the common Euclidian basis (x, y, z) forms a basis according to which you can describe a point by its coordinate on each axis. x y 4 2 i j i v = 4 i + 2 j More precisely, the vector going from the origin to that point is equal to a weighted sum of the units vectors of the axes.

24 A basis is orthonormal when its elements are perpendicular and linearly independent, and its units vectors have the same norm (length) e.g. Euclidian basis. In a 2D plane, the basis on the left is orthonormal, the one on the right isn’t.

25 In fMRI instead of describing a point you want to describe a curve or function (% signal change in function of time) by decomposing it in simpler functions. If you use only one function you have a limited power to describe the % signal change variations, so it’s better to use a number of functions, which constitutes a set of basis functions. That’s why SPM offers different sets of basis functions to model the % signal change variations. Fourier analysis: the complex wave at the top can be decomposed into the sum of the three simpler waves shown below. f(t)=h1(t)+h2(t)+h3(t) f(t) h1(t) h2(t) h3(t) Basis functions

26 Linear combination of the basis functions can capture any shape of response up to a specified timescale. Finite Impulse Response (FIR)Fourier The most general are the finite impulse response (A) and Fourier (B) basis sets, which make minimal assumptions about the shape of the response. Basis functions offered by SPM

27 One popular choice is the gamma function, which has been shown to provide a reasonably good fit to the impulse response, although it lacks an undershoot. The set used in SPM is more parsimonious in that fewer functions are required to capture the typical range of impulse responses than are required by the Fourier or FIR sets, reducing the degrees of freedom used in the design matrix and allowing more powerful statistical tests. Gamma function More parsimonious basis sets make various assumptions about the shape of the HRF.

28 Canonical haemodynamic response function (HRF) Typical BOLD response to an impulse stimulation. The response peaks approximately 5 sec after stimulation, and is followed by an undershoot that lasts approximately 30 sec (at high magnetic files, an initial undershoot can sometimes be observed).

29 Neural signal convolved with a canonical HRF to produce the predicted BOLD signal. In blue sustained neural activity (epoch) modelled by a boxcar. In green series of rapid events every 2 sec. The predicted BOLD response in similar.

30 Fits of a boxcar epoch model with (red) and without (black) convolution by a canonical HRF, together with the data.

31 Residuals after fits of models with and without HRF convolution. Large systematic errors for model without HRF convolution (black) at onset of each block.

32 Limits of HRF - General shape of the BOLD impulse response similar across early sensory regions, such as V1 and S1. - Variability across higher cortical regions regions, presumably due mainly to variations in the vasculature of different regions. - Considerable variability across people. These types of variability can be accommodated by expanding the HRF in terms of temporal basis functions.

33 Canonical HRF and its derivatives Canonical HRF Temporal derivative Dispersion derivative The canonical HRF is a “typical” BOLD impulse response characterised by two gamma functions, one modelling the peak and one modelling the undershoot. To allow variations about the canonical form, the partial derivatives of the canonical HRF with respect to, for example, its peak delay and dispersion parameters can be added as further basis functions. The temporal derivative can capture differences in the latency of the peak response. The dispersion derivative can capture differences in the duration of the peak response.

34 Contrast Design Matrix for analysing two event- related conditions (left or right motor responses) versus an implicit baseline. [1 -1 0] [1 0 0 0 1 0] SPM-F image corresponding to the overall difference (positive or negative) from the left and right responses. SPM-t image corresponding to the overall difference between the left and right responses. Left Right Mean

35 In the previous design matrix, the onset times where convolved with the canonical haemodynamic response function (HRF) to form the two regressors on the left. Design matrix with canonical HRF only.

36 Design matrix with canonical HRF + 2 derivatives. This is the same model as before, but 3 regressors are used to model each condition. The three basis functions are the canonical HRF and its derivatives with respect to time and dispersion. Left RightMean

37 First, test for all regressors modelling this response using a F contrast. This contrast tests for each line against the null hypothesis that the parameter is zero. Because the parameters are tested against zero, one would have to reconstruct the fitted data and check the positive or negative aspects of the response. [0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0] For this new model, how do we test the effects of, for instance, the right motor response ?

38 This shows the F-contrast used to test the overall difference (across basis functions) between the left and right responses. Multiplying the coefficients by -1 doesn’t change anything. [1 0 0 -1 0 0 0 0 1 0 0 -1 0 0 0 0 1 0 0 -1 0] SPM-F image corresponding to the overall difference between the left and right responses. Very similar to the one obtained earlier. How do we test for overall difference bw right and left responses ? To see if the tested difference is “positive” or “negative” (if this makes sense because the modeled difference could be partly positive and partly negative) one has to look again at the fitted signal.

39 These plots show the haemodynamic response at a single voxel (the maxima of the previous SPM-F map). The let plot shows the HRF as estimated using the simple model and demonstrates a certain lack of fit. This lack of fit is corrected, on the right, using the more flexible model with basis functions. Comparison of the fitted response

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