BLM Background Information
The access of the VTC data for latency
estimation is performed in one out of three possible modes:
1.
VOI-based access and VOI-based estimation.
Given the current VOI definition (visible in the Region-Of-Interest dialog) the
VTC time courses are spatially averaged within each separated VOI and one value
per VOI is provided for each of the four estimated parameters.
2.
VOI-based access and voxel-based
estimation.
Given the current VOI definition (visible in the Region-Of-Interest dialog) the
VTC time courses are considered voxel-wise only from
those voxels which belong to one of the VOIs and one value per voxel is
provided for each of the four estimated parameters.
3.
VTC Mask-based access and voxel-based
estimation.
A mask file (*.msk) can be provided by the user to
select the VTC time-courses for voxel-wise latency
estimation.
Once specified the protocol condition
defining the event-type of interest, the average and single-trial epoch-based
responses are isolated from the VTC time-courses. It is possible to specify an
interpolation factor (2-3-4) to upsample the VTC
data, thus increasing the temporal resolution of the BLM analysis. The total
duration of the window of estimation must be specified in milliseconds.
The
BOLD latency estimation is based on a piece-wise linear (PWL) fitting
(pseudo-trapezoid) with initial and final (optional) baseline and four
break-point estimates.
In the single-trial mode an estimate is
provided for each repetition of the selected condition. In this case, BLM maps
are generated not only for the average trial responses (averaged across all the
trials of the single VTCs and, in case of multiple VTCs, further averaged across all VTCs)
but also for the average latency of all single trials from all VTCs. In VOI-based VOI-level mode (1) all the signals, the
fits and the latencies for each trial are saved in the TXT files and will be
available for all kinds of statistical analysis outside Brain Voyager (e.g.
Excel, Statistica, SPSS, …).
The results of the BLM analysis is saved as
"*.blm" files for all three modes of
operation and can be saved in any later session of the main program.
Note 1. The response shape (pseudo-trapezoidal) fitting
procedure allows a robust estimation of the BOLD latencies in the presence of
noise-related fluctuations in the data and complex shapes of the BOLD response
itself. However, depending on the temporal window-of-interest, the original TR
and the interpolation factor, the resulting computation time needed for the
non-linear fit quite extensive. To avoid unexpected long-lasting calculations,
it is suggested to start using the VOI-based approach (mode 1) and to estimate
the computation time for high interpolation factors, extended windows, both in
single- and average- trial modes. After having an estimate of the computation
time for the available number of VOIs as well as of
the accuracy of the fits (which may imply a fine tuning of the temporal window
of operation and/or the removal of the “return-to-baseline”
constraint), the computation time for the number of VTC and masked voxels which would be included in the eventual voxel-based BLM analysis (mode 2 or 3) can be roughly
estimated.
Note 2.
Sometimes the BOLD responses may exhibit more complex shapes than a simple
gamma-like response, especially in those experiments where multiple tasks are
coupled in series, following the time-locking external stimulus (e.g. a cue
followed by a presentation, followed by a judgment task) .
In such cases, it is very important to optimize the temporal window of operation
to capture the right latencies and in the most accurate way. This is made
possible by making more or less flexible the fitting procedure. The two
snapshots below illustrate possible behaviors of the fits in the presence of
(sort of) “two-phase” responses, exhibiting two peaks with variable
relative weighting. Here we show the same four signals analyzed in two
different possible time windows (22s in the upper row and 8s only in the lower
row). The upper snapshot shows the results of the fit when using extended
temporal windows, while the lower snapshot illustrates the fit when the
temporal window is reduced in such a way to model only the “early
bump” of the response. Besides the temporal window, the user can decide either
to force or not to force an explicit “return-to-baseline” part of
the response (see also the detailed operation document). If yes, a signal fit
is accepted only when a complete return to baseline of the response is detected
(snapshot 1). Depending on the ratio between possible multiple phases of the
response, the presence of multiple peaks may produce the effects of slightly
altering the onset estimate of the first peak (like in 1) or the program may
simply decided to skip the first peak and keep the second when this latter becomes
the prevalent effect in size (like in 3 and 4). Instead, if the user decides not to
force the “return-to-baseline” while optimally tuning the temporal
window of observation around the part of interest of the response, any signal
behavior can be addressed properly and the first “main” onset of
the response can be detected regardless of the size, as is in the spirit of the
BLM analysis to separate as much as possible the pure latency effect from the
pure size effect. This way the resulting estimate will be allowed to be highly
optimized with respect to the onset latency (snapshot 2) and even the presence
of small bumps in the response can be considered properly, if this is the
intention. Of course, because the offset of the response is not constrained
anymore, the duration latency cannot be used. In conclusion, it is possible to
use shorter temporal windows focused on specific temporal “components”
of the BOLD responses in change of the full BOLD response duration latency
estimation.
