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Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 1
OutlineOutline•• MR Basic PrinciplesMR Basic Principles
•• SpinSpin•• HardwareHardware•• SequencesSequences
•• Basics of BOLD fMRIBasics of BOLD fMRI•• Susceptibility and BOLD fMRISusceptibility and BOLD fMRI•• A few tradeA few trade--offsoffs
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 2
Basics of BOLD fMRIBasics of BOLD fMRI
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 3
The MR roomThe MR room
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 4
Scanner InternalsScanner Internals
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 5
Macroscopic: Brain SystemsMacroscopic: Brain Systems
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 6
Microscopic: Neuronal FunctionMicroscopic: Neuronal Function
Action Potentials & Neurotransmitter TraffickingAction Potentials & Neurotransmitter Trafficking
2
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 7
Hemodynamic Measure of Brain Function (1881)Hemodynamic Measure of Brain Function (1881)
ArmArm
BrainBrain
Angelo Angelo MossoMosso
Pressure TracesPressure Traces ““BertinoBertino”” Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 8
Artery Vein
Arterioles Venules
1 - 3 cm
Capillary Bed
Neurons
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 9
Blood Oxygen Level Dependent (BOLD)Blood Oxygen Level Dependent (BOLD)
•• Neural activity Neural activity increasesincreases•• Blood flow Blood flow increasesincreases ((““reactive hyperemiareactive hyperemia””))•• DeoxyhemoglobinDeoxyhemoglobin concentration concentration decreasesdecreases•• Magnetic field homogeneity Magnetic field homogeneity increasesincreases•• Gradient echo EPI signal Gradient echo EPI signal increasesincreases
venulesvenulesarteriolesarterioles
BaselineBaseline
capillarycapillarybedbed
time
MxySignal
Mo sinθ T2* task
T2* control
TEoptimum
StaskScontrol
ΔS
time
MxySignal
Mo sinθ T2* task
T2* control
TEoptimum
StaskScontrol
ΔS
““ActivatedActivated””
venulesvenulesarteriolesarterioles
NeuronalNeuronalFiringFiring
capillarycapillarybedbed
HbOHbO22DeoxyDeoxy--HbHb
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 10
Hemodynamic Response PropertiesHemodynamic Response Properties•• Magnitude of signal changes is quite small Magnitude of signal changes is quite small
•• 0.5 to 3% at 1.5 T (or smaller)0.5 to 3% at 1.5 T (or smaller)•• Too small to see in individual imagesToo small to see in individual images•• Always considering differences or timeAlways considering differences or time--course changes course changes
in image intensityin image intensity
•• Response is delayed and quite slow (~10 seconds)Response is delayed and quite slow (~10 seconds)•• Extracting temporal information is tricky, but possibleExtracting temporal information is tricky, but possible•• Even short events have a rather long responseEven short events have a rather long response
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 11
Blood Oxygen Level Dependent Blood Oxygen Level Dependent (BOLD) Contrast Activation(BOLD) Contrast Activation
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 12
TimeTime--Course Response in fMRICourse Response in fMRI•• Brief neuronal events can Brief neuronal events can
elicit a (positive) blood elicit a (positive) blood flow and oxygenation flow and oxygenation response.response.
•• Reponses to events as Reponses to events as brief as 50 ms have been brief as 50 ms have been recorded.recorded.
Functional MRI response to a Functional MRI response to a visual stimulus of duration 2svisual stimulus of duration 2s
Start of Start of EventEvent
SlowerSlowerNegativeNegativeResponseResponse
Rise andRise andFall in ~10 sFall in ~10 s
3
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 13
Response to periodic flashes of lightResponse to periodic flashes of light
Processed ImageProcessed Image Anatomic ImageAnatomic Image
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 14
Typical Functional Image VolumeTypical Functional Image Volume
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 15
fMRI Experiment Stages: PrepfMRI Experiment Stages: Prep1) Prepare subject
• Consent form• Safety screening• Instructions
2) Shimming• putting body in magnetic field makes it non-uniform• adjust 3 orthogonal weak magnets to make magnetic field as homogenous as
possible3) Sagittals
Take images along the midline to use to plan slices
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 16
Slice Thicknesse.g., 6 mm
Number of Slicese.g., 10
SAGITTAL SLICE IN-PLANE SLICE
Field of View (FOV)e.g., 19.2 cm
VOXEL(Volumetric Pixel)
3 mm
3 mm6 mm
Slice TerminologySlice Terminology
Matrix Sizee.g., 64 x 64
In-plane resolutione.g., 192 mm / 64
= 3 mm
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 17
fMRI Experiment Stages: fMRI Experiment Stages: FunctionalsFunctionals5) Take functional (T2*) images
• images are indirectly related to neural activity• usually low resolution images (3x3x5 mm)• all slices at one time = a volume (sometimes also called an image)• sample many volumes (time points) (e.g., 1 volume every 2 seconds for 150
volumes = 300 sec = 5 minutes)• 4D data: 3 spatial, 1 temporal
first volume(2 sec to acquire)
…
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 18
MRI vs. fMRI
↑ neural activity ↑ blood oxygen ↑ fMRI signal
MRI fMRI
one image
many images(e.g., every 2 sec for 5 mins)
high resolution(1 mm)
low resolution(~3 mm but can be better)
fMRIBlood Oxygenation Level Dependent (BOLD) signal
indirect measure of neural activity
…
4
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 19
Detection/Detection/EstimationEstimation
fMRI process chain
RegistrationRegistrationFunctional ImagesFunctional Images
Threshold/Threshold/OverlayOverlay
Phase FixPhase Fix
TimeTime 11 22 33 …… 750 750 (secs)(secs)
11 2233
0s0s .66s.66s.33s.33s
11 22
= +y Xβ e
NormalizationNormalization
11 22
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 20
Statistical Mapsuperimposed on
anatomical MRI image
~2s
Functional images
Time
Condition 1
Condition 2 ...
~ 5 min
Time
fMRISignal
(% change)
ROI Time Course
Condition
Activation StatisticsActivation Statistics
Region of interest (ROI)
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 21
% s
igna
l cha
nge
images
Stimulation protocols in fMRI
baseline rest
stimulationhaemodynamic
response function
time courseof activation
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 22
Statistical Maps & Time CoursesStatistical Maps & Time Courses
Use stat maps to pick regions
Then extract the time course
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 23
2D 2D 3D3D
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 24
Design Jargon: RunsDesign Jargon: Runs
run (or scan): one continuous period of fMRI scanning (~5-7 min) session: all of the scans collected from one subject in one day
experiment: a set of conditions you want to compare to each othercondition: one set of stimuli or one task
4 stimulus conditions+ 1 baseline condition (fixation)
A session consists of one or more experiments.Each experiment consists of several (e.g., 1-8) runsMore runs/expt are needed when SNR is low or the effect is weak.Thus each session consists of numerous (e.g., 5-20) runs (e.g., 0.5 – 3 hours)
5
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 25
Design Jargon: Paradigm or ProtocolDesign Jargon: Paradigm or Protocol
paradigm (or protocol): the set of conditions and their order used in a particular run
Time
volume #1(time = 0)
volume #105(time = 105 vol x 2 sec/vol = 210 sec = 3:30)
runepoch: one instance of a condition
first “objects right” epochsecond “objects right” epoch
epoch 8 vol x 2 sec/vol = 16 sec
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 26
Susceptibility in MRSusceptibility in MR
The good.The good.
The bad.The bad.
The ugly.The ugly.
All susceptibility effects increase with Bo field
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 27
Susceptibility in Temporal LobesSusceptibility in Temporal Lobes
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 28
What is the source of susceptibility?
The magnet has a spatially uniform field but your head is magnetic…
1) deoxyHeme is paramagnetic
2) Water is diamagnetic (χ = -10-5)
3) Air is paramagnetic (χ = 4x10-6)
Pattern of B field outside magnetic object in a uniform
field…
Bo
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 29
Bo
Ping-pong ball in H20:Field maps (ΔTE = 5ms), black lines spaced by 0.024G (0.8ppm at 3T)
1.5T 3T
Susceptibility effects occur near magnetically Susceptibility effects occur near magnetically disdis--similar materialssimilar materials
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 30
Bo map in head: it’s the air tissue interface…
Sagittal Bo field maps at 3T
6
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 31
Other Sources of Susceptibility You Should Other Sources of Susceptibility You Should Be Aware ofBe Aware of……
Those fillings might be a problem…Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 32
Local susceptibility gradients:2 effects
• Local dephasing of the signal (signal loss) within a voxel, mainly from thru-plane gradients
• Local geometric distortions, (voxel location improperly reconstructed) mainly from local in-plane gradients (in PE direction).
Sagittal Bo field map at 3T
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 33
Bandwidth is asymmetric in EPI(Distortion is 100x more in phase direction)
The phase error (and thus distortions) are in the phase encode direction.
ϕ = Δυ τ
kx
ky
δt=0.005ms
δt=0.5ms
υ1υ2
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 34
Susceptibility in EPI can give either a Susceptibility in EPI can give either a compression or expansioncompression or expansion
Altering the direction kspace is traversed causes either local compression or expansion.
choose your poison…
3T whole body gradients
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 35
Susceptibility Causes Image DistortionSusceptibility Causes Image Distortion
Field near sinus
z
Echoplanar Image, Δθ α encode time α 1/BW
Encode time = 34, 26, 22, 17ms 3T head gradients
Use shortest possible encoding
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 36
With fast gradients, add parallel imagingWith fast gradients, add parallel imaging
Acquisition: SMA
SH
SENSE
Reconstruction:
Folded datasets+
Coil sensitivity maps
Reduced k-space sampling
{
Folded images ineach receiver channel
FOVk π2
=Δ
7
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 37
3T MAGNETOM Allegra 3T MAGNETOM Allegra ss EPI PATss EPI PAT
MAGNETOM Allegra. Courtesy Bruker Medical and USA Instruments.4 channel tx/rx array coil
Single shotTE = 30 ms
with PAT x2192x128
with PAT x2128x128
with PAT x264x64
Conventional64x64
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 38
•• Good shimming (first & second order)Good shimming (first & second order)•• Thinner slices (Drawback: Takes more to cover the brain)Thinner slices (Drawback: Takes more to cover the brain)•• Shorter TE (Drawback: BOLD contrast is optimized for TE = T2*locShorter TE (Drawback: BOLD contrast is optimized for TE = T2*local)al)•• ““ZZ--shimmingshimming”” Repeat measurement several times with an applied z Repeat measurement several times with an applied z
gradients that rewind the gradients that rewind the dephasingdephasing, Pick the right gradient afterward on a , Pick the right gradient afterward on a pixel by pixel basis. (Drawback: multi shot or longer encode). pixel by pixel basis. (Drawback: multi shot or longer encode). Yang et al. Yang et al. MRM 39 p402, 1998.MRM 39 p402, 1998.
•• Use special RF pulse with builtUse special RF pulse with built--in in prephasingprephasing in just the right places. in just the right places. (Drawback: long RF pulse, pre(Drawback: long RF pulse, pre--phasing differs from person to person) phasing differs from person to person) Glover et al. Proceed. ISMRM p298, 1998.Glover et al. Proceed. ISMRM p298, 1998.
•• The The ““mouth shimmouth shim”” paramagnetic material in roof of mouth. paramagnetic material in roof of mouth. Wilson, Wilson, JenkinsonJenkinson, , JezzardJezzard, Proceed. ISMRM p205, 2002., Proceed. ISMRM p205, 2002.
•• Distortion correction based on a measured field map (drawback: cDistortion correction based on a measured field map (drawback: cannot annot recover signal dropout or fully correct recover signal dropout or fully correct ““overlappingoverlapping”” intensities)intensities)
•• MultiMulti--shot imaging methods (drawback: more motion sensitive)shot imaging methods (drawback: more motion sensitive)•• Fancy pulse sequences (best to have local physicist): 180 degreeFancy pulse sequences (best to have local physicist): 180 degree
refocusing pulses to reverse distortion (GRASE)/Multiple refocusrefocusing pulses to reverse distortion (GRASE)/Multiple refocusing ing pulsespulses…… singlesingle--shot FSE, Ushot FSE, U--FlareFlare
What can you do?What can you do?
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 39
SingleSingle--shot Gradient Echo EPIshot Gradient Echo EPI•• Parameters you can chooseParameters you can choose
•• TRTR•• Slice thickness/gapSlice thickness/gap•• Number of slices/slice acquisition orderNumber of slices/slice acquisition order•• TETE•• BandwidthBandwidth•• Matrix sizeMatrix size•• Field of viewField of view•• Flip angleFlip angle
•• All of these parameters can be appropriately All of these parameters can be appropriately applied over a wide range of valuesapplied over a wide range of values
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 40
TR (repetition time)TR (repetition time)•• Determines how much magnetization is allowed to Determines how much magnetization is allowed to
recover before it is knocked over again by the next rf recover before it is knocked over again by the next rf pulsepulse
•• From a pure signal strength perspective, waiting for From a pure signal strength perspective, waiting for very long very long TRTR’’ss (5 seconds +) allows for maximal (5 seconds +) allows for maximal signalsignal--toto--noise (SNR)noise (SNR)
•• Noise is MR dominated by physiologic noise (not Noise is MR dominated by physiologic noise (not thermal noise)thermal noise)
•• Requires many images in both conditions to reliably Requires many images in both conditions to reliably distinguish activation (which requires shorter distinguish activation (which requires shorter TRTR’’ss))
•• fMRI can be performed as fast as TR=100msfMRI can be performed as fast as TR=100ms•• Bottom line: use as short a TR as you canBottom line: use as short a TR as you can
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 41
Flip AngleFlip Angle•• A given flip angle will maximize the SNR (Ernst A given flip angle will maximize the SNR (Ernst
Angle)Angle)……at long at long TRTR’’ss (> 3s) this is 90 degrees(> 3s) this is 90 degrees•• This angle is dependent upon the TRThis angle is dependent upon the TR•• Incorrect angles may sensitize your BOLD scans to inIncorrect angles may sensitize your BOLD scans to in--
flow artifacts (bad) flow artifacts (bad) [Lu et al, NeuroImage 17, 943[Lu et al, NeuroImage 17, 943––955 (2002)]955 (2002)]
•• Bottom line: For TR of 1Bottom line: For TR of 1--2s, a flip angle of around 602s, a flip angle of around 60--70 degrees is optimal70 degrees is optimal
( )( )11cos exp /TR Tθ −=
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 42
Number of slicesNumber of slices•• Separate slices in EPI are typically squeezed into a TR Separate slices in EPI are typically squeezed into a TR
intervalinterval•• Many factors influence # of slices that fit in a TRMany factors influence # of slices that fit in a TR
•• Length of TRLength of TR•• TE (determines center of blue box)TE (determines center of blue box)•• Matrix size (determines length of blue box)Matrix size (determines length of blue box)•• Bandwidth (determines length of blue box)Bandwidth (determines length of blue box)
•• Bottom line: collect as many slices as you canBottom line: collect as many slices as you can
8
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 43
So farSo far•• Long TR maximized SNRLong TR maximized SNR•• Short TR maximizes fMRI statsShort TR maximizes fMRI stats•• Long TR provides many slicesLong TR provides many slices•• Short TR provides few slicesShort TR provides few slices
•• The above suggests imaging only brain regions of The above suggests imaging only brain regions of interest (to minimize slices)interest (to minimize slices)
•• But processing decisions also play a roleBut processing decisions also play a role•• Whole brain data is much easier to spatially normalizeWhole brain data is much easier to spatially normalize•• Motion correction works best with thin slicesMotion correction works best with thin slices•• In general In general TRTR’’ss between 1s and 2s are not too badbetween 1s and 2s are not too bad
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 44
Slice ThicknessSlice Thickness•• SNR in MRI is proportional to voxel volume (thinner SNR in MRI is proportional to voxel volume (thinner
slices slices --> less SNR)> less SNR)•• Thinner slices reduces partial volume effectsThinner slices reduces partial volume effects•• Thinner slices reduces throughThinner slices reduces through--plan plan dephasingdephasing•• What is the size of the structure of interest?What is the size of the structure of interest?•• Isotropic voxel size is preferredIsotropic voxel size is preferred
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 45
TE (echo time)TE (echo time)•• Optimum TE is shorter at high field (say 30ms at 3T Optimum TE is shorter at high field (say 30ms at 3T
versus 50ms at 1.5T)versus 50ms at 1.5T)•• Shorter TE reduces signal loss due to field Shorter TE reduces signal loss due to field
inhomogeneities, but also reduces BOLD effect inhomogeneities, but also reduces BOLD effect
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 46
BandwidthBandwidth•• Rate at which points are sampled (the echoes are Rate at which points are sampled (the echoes are
digitized)digitized)•• High bandwidth implies a high sampling rateHigh bandwidth implies a high sampling rate
•• Sampling of the order of 128 kHzSampling of the order of 128 kHz•• 128kHz/64matrix = 2000Hz/pixel128kHz/64matrix = 2000Hz/pixel
•• Noise is proportional to sampling rateNoise is proportional to sampling rate•• High bandwidth means faster data acquisition (and High bandwidth means faster data acquisition (and
more slices can be acquired, with less T2 blurring)more slices can be acquired, with less T2 blurring)
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 47
Matrix SizeMatrix Size•• Matrix size impact everythingMatrix size impact everything
•• Increasing matrix size decreases voxel size and thus SNRIncreasing matrix size decreases voxel size and thus SNR•• Increasing matrix and FOV maintains constant voxel size, but Increasing matrix and FOV maintains constant voxel size, but
increases N and therefore increases SNRincreases N and therefore increases SNR•• IntravoxelIntravoxel dephasingdephasing reduced somewhat with smaller voxels reduced somewhat with smaller voxels
(bigger matrix)(bigger matrix)
Spring 2007 fMRI Analysis CourseSpring 2007 fMRI Analysis Course 48
Field of View (FOV)Field of View (FOV)•• Voxel size determined by field of view and matrix sizeVoxel size determined by field of view and matrix size
•• FOV=200mm/64 matrix = 3.125mm voxel dimensionFOV=200mm/64 matrix = 3.125mm voxel dimension
•• Recall SNR proportional to voxel volumeRecall SNR proportional to voxel volume
x
x
FOVxN
Δ = y
y
FOVy
NΔ =
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