Frequently
Asked Questions |
||
| 1. Why perfusion fMRI? What experimental designs are suitable for perfusion fMRI? | ||
| 3. There seem to be a variety of ASL techniques out there. Which one provides the best sensitivity for functional neuroimaging studies? | ||
| 4. It is unclear how perfusion parameters are selected. What is the best way to optimize the signal to noise ratio while minimizing artifacts? Are there any trade-off or implications of the choice of the parameters? | ||
| 5. How do I generate the perfusion data from the raw image series? What is the difference between the preprocessing of perfusion and BOLD data? | ||
| 6. What is the difference between the statistical analysis of perfusion and BOLD data? | ||
| 7. Is it necessary to calculate the quantitative perfusion image series for data analysis? | ||
| 8. How can perfusion fMRI improve studies of brain areas with high susceptibility from magnetic field inhomogeneities (e.g., orbital frontal cortex)? | ||
| 1. Why perfusion fMRI? What experimental designs are suitable for perfusion fMRI? | ||
Several recent studies indicate that arterial
spin labeling (ASL) perfusion contrast may offer certain advantages
over the widely adopted BOLD method. These include: improved sensitivity
for slow changes in neural activity, reduced inter-subject variability,
more specific functional localization and generally reduced susceptibility
effects. Studies of slowly developing processes (e.g., mood changes
or procedural learning) as well as studies that require comparison
of widely-spaced observations (e.g., drug effects) are particularly
suitable for perfusion fMRI due to its stability over long time scales.
BOLD fMRI, on the other hand, suffers power loss at low task frequencies
due to drifts in the baseline. Perfusion contrast is also appealing
for visualizing brain activity in regions with high static susceptibility,
such as the limbic system, orbitofrontal and inferior temporal regions.
Finally, clinical neuroscience studies can benefit from quantitative
perfusion measurement as it provides baseline information which may
be useful in interpreting different neuroimaging results seen in patient
and control groups. Because perfusion fMRI time-series do not possess
temporal autocorrelation in time, these data can also be analyzed using
virtually any parametric or nonparametric data analysis method, an
option not available for BOLD data. |
||
| 2. What are the drawbacks of perfusion fMRI? Why isn’t everyone using it? | ||
In addition to the simple novelty of the method,
and its unavailability at most centers, there are some specific limitations
of perfusion fMRI. Chief among these is the reduced magnitude of the
signal change for perfusion as compared to BOLD. Thus, for experimental
designs that seek to detect changes in neural activity within a subject
that are evoked faster than every 30 seconds (e.g., most event-related
designs), BOLD remains the superior choice. Next, the image coverage
in ASL methods is inferior to that of BOLD, and is not ideal for whole
brain studies. Finally, due to the pairwise acquisition of label and
control images as well as the required delay time for the tagged blood
to flow into imaging slices, the temporal resolution in perfusion fMRI
is relatively low. Specifically, an effective temporal resolution of
4 seconds represents a practical limit. Nevertheless, recent technical
developments are rapidly changing the face of ASL methods. The use
of phase-delayed experimental events with respect to image acquisition
can provide higher effective temporal resolution of evoked responses.
Also, refinement of fast-spin echo methods will provide improvements
in slice coverage and acquisition times. |
||
| 3. There seem to be a variety of ASL techniques out there. Which one provides the best sensitivity for functional neuroimaging studies? | ||
ASL contains a class of techniques and can be
generally divided into two categories: continues and pulsed ASL. Continuous
ASL, which utilizes long RF pulses for labeling, provides improved
perfusion contrast at the cost of imaging time and a high level of
RF power deposition. Pulsed ASL, which utilizes a nearly instant RF
pulses for labeling, is easier to implement. Although the perfusion
signal is smaller in pulsed ASL methods, more sample points can be
acquired in the same amount of time in pulsed than in continuous ASL
methods. As a consequence, these two types of ASL techniques provide
comparable sensitivity and statistical power for functional activation
studies. Pulsed ASL methods also contain a variety of subtypes, such
as FAIR, PICORE and QUIPSS. The perfusion contrast in these techniques
are fairly similar although subtle differences do exist. Keep in mind
that the temporal stability of the MRI scanner plays an important role
in determining the sensitivity of ASL methods. |
||
| 4. It is unclear how perfusion parameters are selected. What is the best way to optimize the signal to noise ratio while minimizing artifacts? Are there any trade-off or implications of the choice of the parameters? | ||
The
delay time (between the labeling and image acquisition) is a specific
parameter related to ASL methods. Shorter delay times, improve the
perfusion signal but reduce the accuracy of perfusion quantification.
If the delay time is too short for the labeled blood to reach imaging
slices, activation cannot be picked up by ASL methods. In experimental
settings, delay time should be chosen as the optimal point in the
trade-off between these factors. Most studies have reported transit
time on the order of a few hundred ms to around 1 sec. In pulsed
ASL methods, the delay time should be at the upper limit of the transit
time range. An empirical way to determine the optimal delay time
is to do ASL at serial delay times. A rough estimation of transit
time can be visually judged as the time that the large vascular signal
disappears. In continuous ASL methods, shorter delay time can be
used to improve the SNR as the labeling has accumulated in the brain
during the long labeling period. The image acquisition time in ASL methods is limited by the T1 relaxation of the labeled blood, allowing a time window of only a few hundreds ms. The choice of slice number, image resolution and coverage has to be balanced to meet the criteria for total image acquisition time. It is generally suggested to use larger slice thickness in perfusion fMRI than in BOLD to improve the SNR and image coverage. |
||
| 5. How do I generate the perfusion data from the raw image series? What is the difference between the preprocessing of perfusion and BOLD data? | ||
Perfusion
image time series are generally produced by pair-wise subtraction
between interleaved label
and control acquisitions.
The simplest way is to do direct pair-wise subtraction between temporally
adjacent label and control acquisitions. Artifacts can be reduced by
first performing a sinc interpolation to shift the series of label
(or control) images by one TR, followed by pair-wise subtraction between
time-matched label and control images. “Surround subtraction” has
also been proposed through linear interpolation to shift the series
of label (or control) images by one TR, followed by pair-wise subtraction.
However, the “surround subtraction” method will slightly
inflate the false-positive rate in statistical analysis through temporal
smoothing. The preprocessing of perfusion and BOLD data is similar,
although motion correction may be performed separately on the label
and control images in the raw image data. Also, perfusion fMRI data
tend to benefit from spatial smoothing to a greater extent than does
BOLD data as a consequence of the noise characteristics. Finally, the
preprocessing of BOLD fMRI data may include baseline detrend, which
is not necessary for perfusion data. |
||
| 6. What is the difference between the statistical analysis of perfusion and BOLD data? | ||
Because
perfusion time series is independent in time, it is legitimate to
apply the standard general
linear model for
statistical analysis. Unlike BOLD data, temporal smoothing is not required
in the analysis of perfusion fMRI data and the degree of freedom can
be preserved. The inherent “white noise” property in ASL
data simplifies statistical analysis and affords the opportunity to
apply virtually any traditional parametric or non-parametric statistical
test, such as permutation analysis. The group analyses of perfusion
and BOLD data are very similar. |
||
| 7. Is it necessary to calculate the quantitative perfusion image series for data analysis? | ||
It helps, but in some cases is not strictly necessary.
Because the procedure to generate quantitative perfusion images generally
involves calibration using a reference image, absolute perfusion series
are less sensitive to variations in the scanner condition. This is
important for comparison of temporally widely-spaced blocks. Perfusion
quantification will also reduce the inter-subject variability in the
group analysis as cerebral blood flow tends to be quite consistent
in healthy adult subjects. If absolute perfusion quantification is
not possible, the subtracted (relative) perfusion image series can
be used for most paradigms except those involving scans on different
days. |
||
| 8. How can perfusion fMRI improve studies of brain areas with high susceptibility from magnetic field inhomogeneities (e.g., orbital frontal cortex)? | ||
Perfusion images with gradient echo acquisitions
have reduced susceptibility effect compared to BOLD images because
a minimum TE is used. Spin echo sequences can be used for image acquisition
in ASL methods, such as spin echo EPI and SPIRAL. Parallel imaging
with array coil will further shorten the TE and image acquisition time,
and subsequently reduce susceptibility artifact. Echo train and steady
state imaging sequences such as FSE and FISP can also be used but generally
restricted to single slice. Some specific sequence with reduced susceptibility
sensitivity, such as reversed SPIRAL, offers alternative approach for
perfusion imaging in orbitofrontal and temporal regions. |
||