perfusion fmri brain function and fmri course may 16, 2004 thomas liu center for functional mri...
TRANSCRIPT
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Perfusion fMRIBrain Function and fMRI Course
May 16, 2004
Thomas Liu
Center for Functional MRI
University of California, San Diego
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Outline
• Cerebral Blood Flow (CBF)
• Arterial Spin Labeling (ASL) Techniques
• Data Processing
• Applications of ASL
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Cerebral Blood Flow (CBF)CBF = Perfusion = Rate of delivery of arterial blood to a capillary bed in tissue.
Units: (ml of Blood)
(100 grams of tissue)(minute)
Typical value is 60 ml/(100g-min) or 60 ml/(100 ml-min) = 0.01 s-1, assuming average density of brain equals 1 gm/ml
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Courtesy Courtesy of Rick Buxton
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Time
High CBF
Low CBF
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Why measure CBF?
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are needed to see this picture.
From C. Iadecola 2004
CBF is fundamental physiological quantity. Closely related to brain function.
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Hemodynamics depends on baseline CBF
From Cohen et al, JCBFM 2002
Caffeine Response
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Arterial Spin Labeling
•Magnetically tag inflowing arterial blood
•Wait for tagged blood to flow into imaging slice
•Acquire image of tissue+tagged blood
•Apply control pulse that doesn’t tag blood
•Acquire control image of tissue
•Control image-tag image = blood image
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Methods for Tagging Arterial Blood•Spatially Selective ASL (SS-ASL) methods tag arterial blood in a region that is proximal to the imaging region of interest.
• Continuous ASL (CASL) -- continuously tags blood as it passes through a thin tagging plane
• Pulsed ASL (PASL) -- tags blood in a large slab proximal to imaging slice.
•Velocity Selective ASL (VS-ASL) tags arterial blood based on its velocity, and takes advantage of the fact that blood decelerates as it enters the capillaries and accelerates as it enters the veins.
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Arterial Spin Labeling (ASL)Arterial Spin Labeling (ASL)
Tag by Magnetic Inversion
Wait
Acquire image
Control
Wait
Acquire image
1:
2:
Control - Tag CBFCourtesy of Wen-Ming Luh
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Arterial Spin Labeling (ASL)Arterial Spin Labeling (ASL)
• water protons as freely diffusible tracers
imaging slice
alternativeinversion
Mz(blood)
M
control
tag
t
Courtesy of Wen-Ming Luh
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tagging region ~ 10 cmTag duration ~ 15 ms
Pulsed ASLPulsed ASL
tagging planeTag duration ~ 2000 ms
Continuous ASLContinuous ASL
Adapted from Wen-Ming Luh
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Continuous ASL
ImagingPlane
Tag ConventionalControl
AmplitudeModulated
Control
InversionPlanes
B0Blood
Magnetization
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imaging slice
presaturation slice
tag
control
off-resonance IR pulse
EPISTAR PICOREFAIR
Conventional Pulsed ASLConventional Pulsed ASL
Courtesy of Wen-Ming Luh
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Multislice CASL and PICORE
CASL
PICOREQUIPSS II
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CASL vs. PASL• Inherent SNR for CASL is higher, but SNR/time is
roughly the same.• Temporal resolution for PASL slightly better (2 s TR vs.
3 s TR).• PASL amenable to use of a presaturation pulse for
simultaneous CBF/BOLD.• CASL may be better for lower slices when using a head
coil for transmit. • Both have non-quantitative variants that are useful for
mapping.• CASL has higher SAR requirements.
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ASL Signal Equation
∆M= CBF · Aeff
Aeff is the effective area of the arterial bolus.It depends on both physiology and pulsesequence parameters.
Goal: Make Aeff a well-controlled parameterthat is robust to assumptions about physiological parameters.
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Major Sources of Error for ASL
• Transit Delays
• Bolus Width in PASL
• Relaxation Effects - different relaxation rates for blood and tissue, time of exchange.
• Intravascular signal -- blood destined to perfuse more distal slices.
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Transit Delays
~ 1 cm∆t < 700ms
~ 3 cm∆t < 1000ms
CASL PASL
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Controlling for Transit Delays in CASL
A B A B
Tagging Plane
Voxels A and B have the same CBF, but voxel B will appear to have lower CBF if the measurement ismade too early.
time
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Arterial Bolus Width
PASL
CASL
Baseline
Global flowincrease
Baseline
Global flowincrease
Temporal Width of bolus determined bythe pulse sequence
Temporal Width of bolus determined byarterial velocityand size of taggingslab. Underestimatesglobal flow changes.
time
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Defining Bolus Width in PASL (QUIPSS II)
Tag thespins
Saturatespins stillin the slab
TI1 TI1
Bolus temporalwidth = TI1
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Controlling for Transit Delays in PASL
A B A B
Tagging Slab
TI1
TI2 > ∆t + TI1
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Velocity Selective ASL•Velocity selective radio-frequency pulse trains were introduced by Norris and Schwarzbauer in 1999.
•Velocity Selective ASL (VS-ASL) uses a velocity selective pulse train to tag blood that is flowing faster than a desired cut-off velocity (Wong et al. 2002).
•A typical cut-off velocity is 1 cm/s which corresponds to arterioles of about 50 µm.
•Greatly reduces the problem of transit delays.
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Velocity Distribution
Velocity (cm/s)
0.1 1 10
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Ideal Velocity Selective ASL
Velocity (cm/s)
0.1 1 10
Mz
1
0 Tag
Control
PhysiologicalMotion
Image
{
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Spatial Localization
VENC of 0.5-2cm/s dephases spins in 20-50um arterioles
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Initial Implementation (2002)
SPIRAL READOUT
90x 180y -90x
Mz
1
-1
0Velocity
Tag Time
•Plug flow•Laminar flow
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Results - Tag Time Dependence
Tag Time (ms): 700 800 1100 1300
NonQuantitative
Quantitative
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Results - VENC Dependence
VENC (cm/s): 0.5 1.0 2.0
ApproximateVessel Size (um): 20 30 50
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Results - Multislice VS-ASL
NonQuantitative
Quantitative
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Future Development of VS-ASL
• Better velocity selective pulses should improve motion insensitivity and quantitation of CBF (Wong, ISMRM, 2003)
Velocity Profile of Initial Implementation
Velocity Profile of Hyperecho based sequencewith adiabatic pulses
• Investigation of directional dependence (see Abstract 719)• Suppression of flow in CSF (See Abstract 711)
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ASL Data Processing
• CBF = Control - Tag• A CBF time series is formed from a running
subtraction of Control and Tag images.• BOLD weighting of CBF signal can be
minimized with short echo time acquisitions (e.g. spiral or partial Fourier) or spin-echo acquisitions.
• Use of subtraction makes CBF signal insensitive to low-frequency drifts.
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Pairwise subtraction example
Control Tag
+1 -1 +1
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Surround subtraction
Control Tag ControlTag
ControlTagControl
+1/2 -1
Perfusion Time Series
TA = 1 to 4 seconds
+1/2 -1/2 1 -1/2
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ASL Data Processing
• BOLD = average of Control + Tag images• BOLD time series is formed from the running
average of Control and Tag images. • If a presaturation pulse is used, flow
weighting of BOLD signal is minimized.• See Abstract 368 for a general model.
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PERFUSIONUNREGISTERED
BOLDUNREGISTERED
BOLDREGISTERED
Simultaneous Flow and BOLD
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Simultaneous Flow and BOLD with PASL
Anatomy
Flowchange
BOLDchange
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Event-related Perfusion fMRIEvent-related Perfusion fMRIStimulus
Periodic
Random
TA = 2 to 4 s
ASL Measurement
TS = 1 second
ControlTag
Goal: Estimate the Hemodynamic Response
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Event-related ASL
• ASL time series = tag time series interleaved with control time series
• Tag and control time series are analyzed separately.
• Tag and control time series are acquired at a reduced sampling rate, i.e. they are downsampled.
• Can analyze with a general linear model (GLM) with downsampling matrices to reflect the fact that tag and control are interleaved.
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GLM for ASL Experiments
ytag = DtagXhtag + Sbtag + n
ycon = DconXhcon + Sbcon + n
hperf = hcon - htag^ ^ ^
hBOLD = hcon + htag^ ^ ^
DownsamplingMatrices
Estimates
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Results
Direct
Running Subtraction
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0 50 100 150 200 250
999.8
1000
1000.2
1000.4
1000.6
1000.8
1001
0 50 100 150 200 250
999.5
1000
1000.5
1001
1001.5
1002
0 5 10 15 20
0
0.1
0.2
0.3
0.4
0.5
0.6
Seconds0 5 10 15 20
0
0.1
0.2
0.3
0.4
0.5
0.6
Seconds
Periodic Random
Control
Tag
Ideal
Direct Estimate
Running SubtractionEstimate
Motion Sensitivity
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Non-quantitative ASL
• ASL signal reflects delivery of blood to capillary beds, so it is more localized than BOLD.
• Quantitative ASL has lower temporal resolution and lower CNR when compared to BOLD.
• If quantitation of CBF is not necessary, then non-quantitative ASL can be used achieve better temporal resolution and higher CNR.
• Techniques:• Turbo-ASL• Close-tag CASL• SSPL
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Turbo ASLTag TagControl
Tag Image
Control Image
Tag Control
Control Image
Tag Image
Tag Image
Control Image
TI
TI
TR ~ 2s
TR ~ 1s
Conventional ASL, TR > TI
Turbo ASL, TR < TI
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Finger Tapping
TurboPICORE
PICORE
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Finger Tapping
Turbo PICORE|r|>0.3
(twice as manypoints)
PICORE|r|>0.42
(same significance)
PICORE|r|>0.36
(same # of pixels)
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Amplifying Transit Delays Effects in CASL
Tagging Plane
time
Baseline Signal
Activation Signal
Baseline Signal
Activation Signal
Acquiring the signal at an earlier TI amplifies the difference between the activated state and the baseline state.
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Close Tag CASL• CASL with tagging plane
1cm from imaging slice• Control is CASL tag on
opposite side of slice• Tag duration 700ms• Delay to image 200ms• TR 1000ms• Single shot spiral
acquisition• 3.75mm in plane• 8mm slice• ROI chosen by cc>0.4 for
ASL
Single pixel
ROI average
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Close Tag CASL
Subject 1
Subject 2
Subject 3
Anatomy CASL BOLD
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Single Shot Perfusion Labeling (SSPL)
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From JA Duyn et al, MRM 2001
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Single Shot Perfusion Labeling (SSPL)
From JA Duyn et al, MRM 2001
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ASL Applications• Quantitative ASL
• Reliable measurement of CBF across subjects, brain regions, experimental conditions, disease states, and time.
• Simultaneous CBF/BOLD measurements to study the physiology of the fMRI response.
• Non-Quantitative ASL• Mapping regions of activation with better
localization to the sites of neural activity.
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Courtesy of Kamil Uludag
time [s]
100 200 300 400 500 600
[%]BOLD
-4
-2
0
2
4
[%]CBF
-60
-40
-20
0
20
40
60
BOLD
CBFPICOREQUIPSS II
CBF and BOLD with Eyes Open/Closed
CLOSED OPEN
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ASL with very low task frequencies - WANG et al., MRM 2003
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ASL Mapping of Cortical Columns in Cat Visual CortexDuong et al, PNAS, 2001. FAIR sequence, TI = 1500 ms, TR 3000 ms Talagala et al. Abstract 717
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Memory Encoding
0 50 100 150 200 250-20
-10
0
10
20
30
40
50
60
70
80
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QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.
QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.
QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture. QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.
Novel Images
Familiar Images
PICOREQUIPSS II ROI in RightPosteriorHippocampus
BOLD
Stroop Task
Perfusion
Mildner et al Abstract 1012
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Whole Brain fMRI ASL
Duhamel and Alsop Abstract 518
Motor Task
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Overview of BOLD MechanismsNeuronalActivity
CBF (t)
BalloonModel
CBV (t) BOLD (t)
O2 LimitationModel
KineticModel
MRI SignalModel
CMRO2 (t)HbO2 (t)
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Post-Stimulus Undershoot
Finger tapping (6 subjects) Balloon Model
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Conclusions
• ASL provides a non-invasive means of measuring CBF.
• Transit Delays must be addressed properly in order to obtain quantitative CBF with CASL and PASL.
• Velocity Selective ASL is a promising technique for dealing with long transit delays, e.g. in stroke.
• Non-quantitative ASL techniques such as Turbo-ASL and Close tag CASL have good temporal resolution and high CNR. They have the potential to provide better spatial mapping than BOLD.
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Acknowledgements
Eric WongRick BuxtonWen-Ming LuhKamil Uludag