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Undergraduate Thesis BSc Psychology Royal Holloway University of London
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10075476Tom Minor
Narender Ramnani
MODEL FREE APPROACHES TO INVESTIGATING THE NEURAL MECHANISMS OF WORKING MEMORY
ABSTRACT
A re-analysis of data from a study into the cerebellar contributions to working
memory (Hayter et al., 2007), was conducted, using the same General Linear Model
design matrix and an extension using Independent Component Analysis allowed for
a comparison of model-driven and data-driven statistical approaches and their
contributions to understanding the neural dynamics recruited during a verbal
working memory (VWM) task (PASAT). The increase in cognitive load within the
ADD condition, and the resulting changes in BOLD response was operationalised as
the variable most likely to demonstrate the execution of integrated cognitive
control. Focussing on brain areas that were found to be significantly activated
during the ADD > REPEAT condition, an attempt to evaluate model-free approaches
to neuroimaging is made and the suggestion that the use of both data-led and
hypothesis-driven models, may best suit an area of science that is renowned for the
difficulty in reliably interpreting incredibly noisy and complex data-sets, as in
functional Magnetic resonance imaging (fMRI)
INTRODUCTION
D’Esposito (2007) defines Working Memory (WM) as the temporary retention of
information recently experienced or retrieved from long-term memory that no
longer exists in the external environment. A good test of WM is the Paced Auditory
Serial Addition Task (PASAT) because it enables researchers to manipulate
cognitive and sensory demands within a task that can be learned and executed
within neuroimaging studies and allows for functional and anatomical introspection
into the inner workings of WM at the level of the brain. Evidence related to the
neural substrates of WM will be considered before introducing 2 different statistical
approaches, as the case for either model-based or data-driven methodologies to
interpreting fMRI, data from a WM task is assessed. Neuroscientific data, from
primate studies will be discussed to generalise and further our appreciation of the
range of brain areas that appear to be related to WM in humans .
Smith et al., (1996), confirms that the posterior parietal cortex is implemented left-
hemispherically, as a neural storage component to VWM, including a sub vocal
rehearsal component in Broca’s area and premotor and supplementary motor
(frontal) areas. Smith, (1998) also concludes that there is scientific convergence on
the idea that there are separate systems for verbal and spatial memory, in support
for Baddeley’s decomposition of VWM into a phonological buffer and rehearsal
process within the left posterior parietal cortex (Brodmanns areas/BA40), Broca’s
area (BA44), left premotor area (BA6) and left supplementary motor areas (BA6),
which are found to be activated in the maintenance and manipulation of information
in VWM. Broca’s aphasics show a steeper forgetting curve than controls
(Korsakoff’s patients), suggesting that this poorer performance is likely to be caused
by a lack of subvocal rehearsal, also left posterior parietal cortex lesions seem to
interrupt verbal repetition, implying a deficit in the storage component of VWM and
offering support to the idea that the posterior parietal area is generally involved in
phonological processing and not restricted to memorisation (Smith et al., 1996).
Majerus et al., (2006) note that the intraparietal sulcus (IPS) is one of the most
consistently activated regions during verbal short-term memory (VSTM) tasks,
although the precise role it plays is a matter of controversy. IPS activity was found
in Hayter et al., (2007), and the current reanalysis, providing a motivation to model
and try to theoretically understand why this region (and many others circumventing
the IPS) show significant activation in this experiment and what that might tell us
about the functional connectivity of potential networks of structurally independent
but functionally integrated brain regions involved in VWM. The IPS is functionally
connected to serial/temporal order processing areas in the right IPS, premotor and
cerebellar cortices (Majerus et al., 2006), suggesting some functional inter-
hemispheric interaction and strengthening the case that bilateral IPS activity may be
related to the cognitive demands of the task. During STM tasks, the left IPS shows
connectivity to the phonological, and orthographic processing areas in the superior
temporal and fusiform gyri (Marjerus et al., 2006), suggesting that the IPS acts as an
attentional modulation area for distant neural networks specialised in language or
order representation and strengthening attention-based accounts of VSTM.
Chen and Desmond, (2005) have implicated inferior and premotor frontal cortex,
the insula and the cerebellum in VSTM tasks, demonstrating that areas outside of
the parietal lobe are also involved in processes related to the phonological store and
providing evidence for a fronto-parietal-cerebellar network for VSTM. These
researchers also found that the IPS is connected to the medial superior frontal areas,
the left cuneus, and the posterior cingulate extending to the precuneus. Again, these
results reflect the original findings from the Hayter et al., (2007) study and seem to
be best represented in the current results from the extension analysis with a model-
free approach as opposed to the model-driven approach. Due to a significant part of
the operated experiment being verbal instruction and potential subvocal rehearsal,
it seems poignant to include the IPS and its connectivity, focussing on its
contribution to an integrated network of neural dynamics, evidenced to underlie
VSTM.
The first statistical approach used was a General Linear Model (GLM), which
assumes Gaussian distribution of data. GLM makes this assumption and sometimes
this rigid hypothesis is wrong, leading to inaccurate data that misses something
with import for the experiment, because it was not modelled (expected) in the
design matrix and therefore considered as noise. Hemodynamic activity varies
across many factors, including intra-individually, GLM assumes that all data
represents a Gaussian distribution, and ignores any data that isn’t distributed in a
Gaussian manner, as noise. Not all hemodynamic activity related to the experiment
is Gaussian in nature; there may be unexpected, non-Gaussian distributed data that
still has something to tell us about the processes of WM and this is why the use of
data-driven approaches is required. Using a General Linear Model (GLM) statistical
approach to their data analysis, Hayter et al., (2007), defined the parameters of their
design matrix, according to the variables of interest (regressors) and considered all
activity related to the temporal dynamics of their experiment, thus interpreting
results based on effects due to voxel-wise interactions that could be accounted for
by their preconceived model, driving the analysis in a hypothesis led fashion. In
order to test the usefulness of GLM, a second statistical approach was introduced,
this was Independent Component Analysis (ICA).
ICA has its own problems in that, without a defining model to refer to, there are
interpretive limitations. Fortunately a new form of ICA, used in this study, allows
for the analysis of regressors, so that the data set represents the best of model–free
and the best of model-driven statistical methods in order to more closely scrutinize
results. ICA allows for the blind source separation of a mixed data-set into its
component parts, dealing with ‘functional segregation’ by detecting focal differences
in neuropsychological effects in terms of a number of regionally specific changes
whose significance can be assessed independently of changes going on elsewhere in
the brain (Friston, 1998). ICA is a data-led approach to the analysis of fMRI data,
allowing for exploratory research. fMRI data sets, represent a mixture of signals
resulting from hemodynamic changes, reflecting neural activity, motion and
machine artefacts and signals from physiological cardiac and respiratory pulsations:
the relative contribution of each of these components is undetermined, suggesting a
role for blind source separation (Jung et al., 2000). In dealing with the ‘neural
cocktail-party problem,’ ICA allows for the delineation of a noisy signal into its
important component parts, attempting ‘true redundancy reduction’ by
‘minimalising mutual information,’ though it is important to note that true
‘independence’ does not really exist because neurons can be coupled by synapses
and share efferent connections (Brown et al., 2001). ICA is particularly effective at
detecting task-related activations, including unexpected activity that would not be
detected under the premise of a model-based analysis, which considers unexpected
activity as error. It is possible to input a regression framework into the ICA,
allowing for a combination of hypothesis testing and data-driven research (Brown
et al., 2001).
McKeown et al., (1997) state that the principle of localisation implies that each
psychomotor function is performed in a small set of brain areas, which are
anatomically segregated for each function. They point out that the goal for
decomposition of fMRI data into physiological and cognitive components is to
determine topographically distinct brain areas that are co-activated during time-
series acquisition throughout the experiment. Finally, under McKeown’s conception
of ICA, it is equivalent to saying that voxel values in one component, convey nothing
of any value about the voxels in any other component, which is a stronger criterion
than the assumption of GLM (that maps of voxel-wise interactions from different
components are uncorrelated and Gaussian in nature).
In attempting to assess the contribution of cortico-cerebellar loops in the execution
of skilled cognitive operations, Hayter et al., (2007) reported activity in the medial
portions of cerebellar cortical lobule VII, linking these activations to the motor
demands of their experimental condition (ADD) within the PASAT. Noting the
substantial evidence of prefrontal-cerebellar connectivity (Hoover & Strick, 1999,
Kelly & Strick, 2003, Middleton & Strick, 2001; Walker, 1940), Hayter et al., (2007)
tested the hypothesis that highly practiced execution of action, engages cerebellar
circuits (Wolpert et al., 1998) by manipulating the sensory demands within a task
that required speech motor control. Activity was predicted in the auditory areas of
the superior temporal gyrus and ventral areas of the Primary Motor Cortex
(PMC/M1) -- containing orofacial musculature representations, along with
cerebellar lobules, known to be components of the motor loop (IV, V and VI). In
addition to confirming their hypothesis, Hayter et al., (2007), found co-activations in
mid portions of the middle frontal gyrus (9/46 putatively), anterior portions of the
cingulate cortex and areas within the pars triangularis (inferior and middle frontal
gyri/Broca’s area), supporting literature documenting the activation of these areas
during WM in humans (Curtis & D‘Esposito, 2003; Passingham & Sakai, 2004; Smith
& Jonides. 1996). The Hayter et al., (2007) study provides support for the
‘automaticity function’ of the cerebellum by demonstrating that the cerebellum is
involved in the execution of learned actions thus freeing up cortical structures to
deal with novel information processing. It is proposed that due to the uniform
cytoarchitecture of the cerebellum, considered alongside the consistent findings of
activity related to the control of motor speech production and prefrontal cognition,
that the mechanisms supporting automaticity of action and automatic information
processing may be similar (Ramnani 2006). Hayter et al., (2007) add to the
consistently robust finding of activations in the lateral convexity of the PFC in
relation to maintenance and manipulation-related demands of WM (Curits &
D’esposito, 2003; Passingham & Sakai, 2004), highlighting the role of the cerebellum
in processes linked to verbal WM and emphasising the use of these processes in
acquiring a skill through the process of automaticity.
Cerebellar contributions to WM form the starting point of this investigation. Using
the rationale and data from the Hayter et al., (2007) paper, this investigation is
based on discovering what impact model based, hypothesis-driven techniques as
compared to minimal assumptions, data-led approaches to analysing fMRI data,
have on the actual statistical processing and interpretation of results. As such, part
of this investigation is a re-analysis of the Hayter et al., (2007) data set, using the
same design matrix within a GLM analysis (though on a later SPM5 program) and a
comparison to an extended analysis, using ICA, including a GLM model-fit,
displaying the variance of results based on the 2 techniques. On the whole, results
from the re-run, corresponded to the detail in the Hayter et al., (2007) study, some
differences were found and these will be discussed in terms of the operating
systems and potential human error, within a broader discussion of the techniques
used and potential fronto-parietal-cerebellar network for VSTM. The further
analysis (ICA) was able to allow for potentially more detailed, and more selective
choice of peak-voxel activation and as such, brings the possibility of a more complex
view of the structure and function of the hemodynamic activity relative to the
original experiment.
The reliability of neuroscientific interpretations of physiological data sets is
intimately linked to the quality of the scientific tools and methods used in detecting
and localising brain activity, which relies on a less than uniform nomenclature and
differing sets of anatomical atlases. The search for detailed knowledge of how the
brain works, and how interconnected but distinct brain areas communicate with
one another; through which pathways and in what serial order, has been greatly
advanced using non-human primate research which allows for deeper introspection
into the mechanics and architectures of brain areas that are typically out of reach in
human subjects, due to their critical, sub-cortical or frontopolar location.
Petrides & Pandya., (2001) have done much to assist in establishing meaningful
comparisons between the human and macaque brain by developing a common
architectonic map, allowing for delineations based on functionally and structurally
evolved parts of the human PFC and also contributing to our understanding of brain
function. Comparing the cytoarchitectonic nature of the human and macaque
ventrolateral PFC (vlPFC) and corticocortical connection patterns in the monkey, via
injecting tracers into Walkers area 12, herewith referred to as area 47/12. The
multimodal input into this area can be assessed and fed into a model of how this
area differs in its function to the corresponding brain area in humans, and what it is
about its function in monkeys that can add to our ‘as-close-to’ complete view.
Tracers were found in the rostral inferotemporal visual association cortex and in
temporal limbic areas such as the parahippocampal cortex. Dorsally adjacent to
47/12, lies area 45 which represents the dorsal part of the vlPF convexity, just
below area 9/46 and caudodorsal to Brodmanns area 47. Injections to area 45,
labelled the Superior Temporal Gyrus (STG) (auditory association cortex) and the
multimodal cortex in the upper bank of the Superior Temporal Sulcus (STS). Area
45 occupies a large part of the pars traingularis. Tracers beginning their journey
here were also found in dorsolateral frontal areas 6, 8Ad, 8B and 10, as well as area
24 of the cingulate gyrus. Petrides & Pandya (2001), suggest that area 45 subserves
higher-order aspects of organisation of linguistic processing, but is not limited to
that; due to the existence of these areas in monkey, the implication of a more
general and fundamental role in cognition which may have adapted in humans to
serve linguistic processing in the left hemisphere, is posited. Petrides, (2005)
believes that ventrolateral prefrontal cognition controls information processing in
posterior cortical areas necessary for active retrieval of information from memory.
Area 47/12, with its strong links to rostral inferotemporal visual association cortex
and ventral limbic areas (rostral parahippocampal gyrus) may be a part of a frontal
mid-ventrolateral exectutive system that is involved in active judgements on stimuli
that are coded and held in posterior association cortex (Petrides, 2005). This body
of work, does much to illuminate some of the findings from the current re-analysis
of the Hayter et al., (2007) data, using an ICA, as all the areas mentioned, show
activation and show tentative support for these hypotheses (frontal-
midventrolateral system).
Fuster (2004), refers to Koechlin et als., (2007) hierarchical cascading model of
executive processes in the lateral cortex of the frontal lobe. Discussing the upper
processing stages of the perception-action cycle, he concludes that at all levels of the
CNS, sensory processing happens sequentially and along a posteroanterior axis,
with feedback at every level. Cortically, information is believed to flow circularly
through a series of hierarchically organised areas and connections constituting the
perception-action cycle. Within this conception, automaticity (cerebellar learning in
order to free up frontal areas for novel information processing) is implied. Koechlin
et al., (2007), view the lateral PFC (lPFC) as a cascade of executive processes,
organised from premotor to anterior PFC regions, that control behaviour according
to the stimulus, perceptual context and temporal dynamics of the stimulus,
providing a unified and modular account of cognitive control. This top-down
interaction between the lPFC regions and premotor or posterior association cortices
predicts that episodic, contextual and sensory contributions to cognition, gradually
emerge from rostral to caudal lPFC and premotor regions, and that the increasing
demands of these factors have additive effects of behavioural reaction times, this is
characterised by Weber’s Law, (Blake & Sekuler, 2006). On the basis of this
research, it is believed that rostral activations of the lPFC (inferior/middle frontal
gyrus; pars triangularis) will result from variations in WM load, (maintaining
instructions relative to cues over the course of experimental episodes) and that
these areas are engaged in selection of appropriate representation-for-action
modules, processed across episodes and exert control on the caudal lPFC, but not
directly on the premotor representations – it is the caudal regions that select
premotor responses to task sets according to the context, and rostral regions select
caudal lPFC representations, modelling the classical theory of executive control
based on central control of multiple slave systems (Koechlin et al., 2007)
The caudate nucleus seems to function similarly to the PFC, in that damage to both
areas result in similar deficits due to the sharing of inputs from frontal and
temporo-parietal cortical areas and outputs to the basal ganglia. Part of the fronto-
caudate pathway projects via the thalamus back to BA 46 in PFC, suggesting that the
cognitive functions of the dorsolateral prefrontal (dlPF) and anterior cingulate (AC)
pathways implement the caudate (Abdullaev et al., (1997). The caudate (tail &
head) is activated in Hayter et al., (2007) and in the current re-analysis, including
the GLM and ICA, these results fits with cascade model along the posteroanterior
axis for corticosubcortical WM operations.
Desikan et al., (2006) warn that there is limited ability to qualify critical dimensions
of interest in localisation of fMRI data, because of the considerable inter-individual
variability of topographic cortical features. Stating that the banks of the superior
temporal gyrus (STG) and pericalcarine cortex have larger interindividual
variability due to their pure sulcal nature. Bearing this mind, a comparison of
results from the original data set and the current reanalysis with the same GLM on a
newer SPM5 programme and a new version of ICA that allows for GLM regression
analysis and illustrates the variations in results between the two approaches,
allowing for some good comparisons and elucidating the neural mechanics of VWM
in the PASAT.
METHODSThis is a report from an already published data set, we report the salient issues.
PARTICIPANTS:
The original study involved 15 Right-handed volunteers between the ages of 18 and
29 (6 males) who gave written and informed consent confirming that they had no
neurological or psychiatric history. The study ran in line with the Royal Holloway
University of London (RHUL) MRI Rules of Operation and the Medical Devices
Agency. Ethical approval from the RHUL Psychology Department Ethics Committee
was received for a reanalysis of the original results and no experiment took place.
EXPERIMENTAL DESIGN:
The aim of this study was to investigate what differences were found in the results
of a reanalysis of the original data from the Hayter et al., (2007) paper, using the
same General Linear Model used in the original study and an Independent
Components Analysis.
Paced Auditory Serial Addition Test (PASAT):
Tombaugh (2005) recognises that the PASAT measures the performance of subjects
across multiple sensory modalities due to the requirement of successful completion
of a variety for functions related to attention, including audition, visual perception,
numerical cognition and speech. In the original study, the adaptation of the PASAT
allowed for the investigation of BOLD activity related to the specific cognitive
demands of the task, whilst enforcing strict experimental controls. The preparation
phase, outside of the scanner allowed for familiarisation with requirements, then
subjects practiced the test inside the scanner, to familiarise themselves with the test
environment. The experimental phase consisted of 35 blocks of experimental
(ADD), 35 block of control (REPEAT), and 10 null blocks (with no stimuli), lasting 32
minutes altogether. Blocks were pseudo-randomly intermixed. For more detail
about the PASAT test, refer to Hayter et al., (2007)
APPARATUS:
Participants lay supine within the MRI Scanner with padded restraints immobilising
their head. Instructions were received audibly through headphones that were
compatible with MRI apparatus. Verbal responses were measured using an MRI-
compatible microphone. An overhead mirror mounted on a head coil made the
visually presented instructions viewable as they were back projected onto a screen.
Experimental and control stimuli were controlled by a computer. For detail and
timings of experimental episodes refer to Hayter et al., (2007).
IMAGE ACQUISITION:
Participants were scanned with the 3-T Siemans Trio MRI scanner at RHUL. First
structural images were acquired. The functional sequence during the experimental
phase was made up of 644 EPI images and 4 volumes were collected before the
experiment began to minimise longitudinal relaxation artefacts (Hayter et al, 2007).
SPARSE SAMPLING:
Participants produced overt verbal responses during periods of deliberate scanner
silence (sparse-sampling) in order to allow for and cope with the head motion
artefact expected during the spoken response.
MRI Image Analysis:
Image processing and analysis for the original replication were carried out in SPM5
(www.fil.ion.ucl.uk/spm) on a dual core AMD Athlon 64 MHz PC with 2 GB of RAM
Linux server 2003 and Matlab 6.5 (MathWorks.Inc., MA, USA)
For the ICA, the GLM from the previous analysis was fed into the ICA via the FSL
programme on the same PC and server using Linux.
Preprocessing:
REALIGNMENT
Realignment was computed with reference to the first EPI time-series and the
resulting head motion parameters (3 rotations and 3 translations) were saved and
included as regressors within the GLM. This step attempts to model the acquired
head motion regressors, statistically, to allow for accuracy in later steps based on
the variance in results that may be caused by the subjects translating or rotating
their head during the verbal response phase of the experiment and thus influencing
the maps of activity.
NORMALISATION
Brains aren’t all the same, so in order to meaningfully interpret the results, subjects’
individual brains need to be adjusted statistically to reduce individual differences
and provide a common stereotaxic space from within which to compare localised
activations across the board. Normalising the volumes to the ICBM template
(Montreal Neurological Institute series; MNI) of standard stereotaxic space was
achieved using rigid, linear scaling that brings the individual brain into the realm of
stereotaxic space and then non-linear warping which selects particular bits of the
brain that seem to have evaded normalisation through linear transformations and
require particular attention in order to match the template meaningfully.
SMOOTHING
An 8mm smoothing kernel was applied at the final stage of preprocessing. Within
the GLM analysis, these steps had to be processed manually, with the aid of the
SPM5 programme and within FSL, for the ICA, these steps were computed
automatically. Smoothing data amplifies significant signals and reduces signals of no
interest (noise). The size of the kernel is essentially an arbitrary value, however
using a smaller kernel may have magnified many more subcortical activations and it
would be extremely unfruitful to use higher than 10mm kernel, because at that
range, segregating activations loses specificity, especially between anatomically
proximal areas. Smoothing kernels need to be at least twice the size of the voxels to
be able to tell us anything meaningful, otherwise they may miss minute details in
signal significance, reducing something interesting or elaborating something that is
in fact noise and of no interest.
Statistics:
GLM is conducted using a Linux system, Statistical Parametric Mapping (SPM)
programme within MATLAB. This programme allows you to create the design
matrix, defining the parameters of the variables of interest. In this case, head
motion regressors (3 x rotations/ 3 x translations), conditions (instruction, add,
repeat) and error were modelled within the design matrix. Preprocessing the data
for SPM5 involved realigning the individual subject scans on the basis of the head
motion artefact to measure the extent to which a particular scan deviates from the
first time-series. By modelling approximate estimations of head motion from fMRI
data, using sparse sampling as a way to measure minute differences in head position
before and after overt verbal responses are made during scanner silence, SPM5 re-
slices the brain scan, adjusting the data according to the variance in signal due to
motion, as a first step to creating statistical validity. Normalising individual brain
images (T1s) into a common stereotaxic space (MNI template) requires telling SPM
which brain needs normalising and selecting the correct template within which to fit
it. The linear affine scaling and non-linear warping of the images that fits the
individual subjects brain into the template brain requires selecting the mean image
from the newly realigned files as the source image, and then selecting the 644
realigned files to be normalised to an EPI image. The last step before setting up the
GLM design matrix, is smoothing, which requires inputting the voxel dimensions of
the isotropic smoothing kernel desired for use (8mm x 8mm x 8mm).
Event definition and modelling:
The four events modelled from the original experiment were: Instruction (1s); ADD
blocks (15s); REPEAT blocks (15s); and Error blocks (15s).
GLM explains how much each regressor explains the variance in the data, in order to
do this GLM needs to know the temporal dynamics of the experiment so that it can
identify different time points of each block and convulve them with the
hemodynamic response recorded.
First-level single-subject analysis (Parameter estimation of GLM):
Within SPM5, after all preprocessing has been completed, specifying the 1st level
statistics begins by selecting the subject’s smoothed files, specifying the interscan
interval as 3 seconds and manually inputting the details of the 4 conditions of the
experiment (Instruction, Add, Repeat and Error), which later allow for t-contrasts.
For each condition, the Onset files have to be imported from the original data and
the duration of the blocks have to be specified as 15 seconds, except for Instruction
which was 1 second. A High Pass filter was set to 60 and a canonical hemodynamic
response function was selected as the basis function (expected BOLD response)
before the model was saved. Model setup completed the estimation stage of the
GLM, at which point some checks were necessary. By selecting review in SPM5, the
orthogonality of the design matrix is displayed, this allows for a quick check that
there are the right number of regressors within the design matrix and that they have
been estimated and modelled correctly. Once satisfied that the model is correct, the
GLM analysis for 1st level were run (See Table 3 in results for 4 individual GLM 1st
level analyses). T-contrast comparisons were run on: (1) INSTRUCTION only; (2)
ADD only; (3) REPEAT only; and (4) ADD > REPEAT.
T-contrasts and statistical parametric mapping (SPM{t}) maps highlighted voxels
within MNI space where Blood Oxygenation Level Dependent (BOLD) responses
were significantly different between the conditions ADD and REPEAT. The SPM.mat
file that is produced from the 1st level GLM is specified within SPM5, this requires
manual input of the values of different conditions, allowing SPM to bring up the
brain activations that relate to the specific demands of the contrast. For example,
Add greater than Repeat would be defined as Add carrying a weight of 1 and Repeat
carrying a weight of zero, for the statistics to produce maps that reflect brain
activity that was specific to the Add condition and greater than the activity found in
the Repeat condition. At this point, whole brain threshold tables are produced,
highlighting peak-voxel clusters, and SPM5 allows overlays onto canonical
templates which are a useful tool for localisation, as they share similar landmarks to
the anatomy in the atlas used for localisation (Duvernoy & Bourgouin, 1999), and
match the template in the MRICRO programme which allows for manual input of
MNI co-ordinates in order to specify where activity is in MNI space. SPM5 also
allows for overlaying back to individual T1 images, providing closer, adherence to
individual variations in brain size and shape.
Second-Level between-subjects analysis:
This involves a one-sample t-test applied to the contrasts from the first level
statistics (all results thresholded p<0.05, FWE corrected). Specifying 2nd level
statistics for GLM on SPM5 simply plugs the output from the 1st level statistics into
the group analysis. By selecting the contrast image files, saved from the 1st level,
SPM5 computes group level analysis on the contrasts you ask it to, finding
overwhelming common activations between subjects. Classical as opposed to
Bayesian inference methods were chosen and results were corrected for Family
Wise Error, which is a more commonly used, stringent correction for multiple
comparisons, applied to each and every voxel, meaning that GLM computes 100,000
t-tests at this level. The maps produced at 2nd level can be treated as in the 1st level,
with interactive thresholds and overlays within the SPM5 programme. Since group
level statistics, on the whole, tell us more about strong findings, a table of the results
of the contrast of Add > Repeat is presented in Table 1 of the results. Areas of
significant activation were localised using a overlay function within the SPM5 setup;
overlaying the T1 functional results (SPM{t} maps) onto a canonical anatomical
representative T1 image (MNI Series). Due to the variation of landmarks within
MNI space, a cross check involving overlaying individual SPM{t} maps back onto the
normalised T1 scans for each subjects’ results from the original study was done.
Independent Component Analysis:
ICA does not require predetermined regressors in order to separate the mixed
signal into its significant component parts. It is possible however to enter the GLM
model into the ICA on the FSL programme, allowing for an inspection of how well
ICA separates components of head motion, machine and physiological artefact from
interesting neuronal activity and the relevant, task-related hemodynamic
components. Within FSL, it is possible to import head motion vectors into the
analysis and build them into the weak model. 4 event variables were built into the
model (Instruction, Add, Repeat and Error), and prestats were computed using
MCFLIRT. The smoothing kernel was set to 8, as in the GLM. Registration to MNI
space, setting the high pass filter to 60 and the number of components set to 50
completes the model setup and then ICA is run on individual subjects data in
MELODIC within FSL. Once the ICA has run, within FEAT-FMRI in FSL, it is possible
to load the 4-dimensional EPI files for each subject and to inspect each component
that ICA found that could be separated from the source signal. Checks were made as
to the periodicity of activation within the component and whether it related to the
periodicity of the experiment, using temporal timecourses (see results). Tables with
p-values highlighted the most significant contrast within each component, allowed
for relation to specific contrasts such as Add > Repeat. Gamma distribution graphs
(see results) also helped to demonstrate that ICA was indeed delineating Gaussian
distributed data (components) from a mixed non-Gaussian source. ICA produces
many images for each component, mapping brain activity in different slices of the
brain, from the cortex down to the cerebellum. It also produces maps of relative
deactivation and colours these differently to activations, providing interactive
thresholds at every level. It is not possible, however to overlay the images produced
from the results of ICA within FSL, onto the individual TI brains, or into a canonical
template MNI space, this makes localising activations, more vulnerable to human
error. Duvernoy & Bourgouin (1999) was the anatomical atlas used in both the GLM
and ICA investigation.
Localising activation for both analyses, involved choosing sagittal and axial planes of
view of the brain within the atlas and finding landmarks that reflected the
dorsoventral and medial-lateral position of the images within the program. It was
important to use at least 2 planes of view, in order to make sure, something than
looked cortical, was not in fact subcortical and vice-a-versa. Unfortunately, the atlas
carries a tremendous amount more detail than either SPM5 of FSL seem capable of
producing at this stage, and even with the assistance of the MRICRO programme
within SPM5, considerable attacks on confidence levels for the accuracy of
localisation could be made. As far as this study goes, it is believed strongly that the
author’s localising skill is one of the more reliable aptitudes brought to this project,
and much painstaking time was spent, to ensure that the brain area selected as
representative of the result, was indeed, the closest possible result that could be
reported. Clearly, there were times when the activity could not be definitely located
to a marked area within the atlas, but in these cases, sulcul and gyral anatomy was
used as a gross morphological attempt to localise as accurately as possible.
RESULTSTable 1: (2nd level analysis of 1st level GLMs )ADD>REPEAT (FWE corrected for multiple comparisons, p<0.05, random effects analysis).
LOBE Gyri/Sulci MNI Co-ords Stats StatsT Z
Frontal (PF/PMC) Superior Frontal Gyrus (L) 0 12 48 13.25 5.81PFC Middle Frontal Gyrus (L) -42 0 52 13.08 5.78
Cingulate Gyrus (L) 8 26 32 11.59 5.57Cingulate Sulcus [R] -6 -68 52 12.34 5.66Central Gyrus/Sulcus [R] -46 -36 44 11.38 5.49
PMC Precentral Gyrus [R] -40 -48 55 11.38 5.49
Superior Precentral sulcus[R] -40 -48 55 11.38 5.49
Temporal Circular Insular sulcus [R] -22 24 8 11.47 5.51Circular Insular Sulcus (L) 38 20 -4 10.56 5.33Anterior/Intermediate transverse Temporal Gyrus (L) 38 20 -4 10.56 5.33
SUBCORTICALBasal Ganglia Caudate Nucleus [R] -18 -8 24 12.46 5.51
Subthalamic nucleus 14 -4 -10 10.27 5.28/Substantia Nigra (L)Cerebellum [R] -6 -50 -38 12.11 5.62
Results were corrected for Family Wise Error, a standard conservative control, which finds activations that are above 0.05 (p-value). If activations survive FWE correction, we know that there is absolutely something happening in the voxels highlighted. FDR correction finds more reasonable activations, but it was felt these gross voxel clusters would inhibit fine-tuned localisation with certainty.
Below is an example of the output in SPM5 for the group level analyses of 1st level GLM. Whole brain interactive thresholds, to select peak activity within voxel clusters
Table 2 (ICA results of individual 1st level analysis)LOBE Gyral/Sulcal anatomy STATISTICS Lateralisation
z pFrontal Superior frontal gyrus z = 5.64 p < 0.0000 Bilateral
Middle frontal gyrus z = 5.64 p < 0.0000 BilateralCingulate gyrus z = 0.68 p < 0.03501 Bilateral
Broca's area Inferior frontal gyrus z = 5.64 p < 0.0000 BilateralSuperior frontal sulcus z = 5.64 p < 0.0000 BilateralMedial orbital gyrus z – 1.88 P < 0.02979 Bilateral
Central sulcus z = 4.48 p < 0.0000 Bilateral
Inferior precentral sulcus z = 5.02 p < 0.00000 BilateralSuperior precentral sulcus z = 4.48 p < 0.0000 BilateralSuperior postcentral sulcus z = 6.18 p < 0.0000 BilateralParacentral sulcus z = 6.18 p < 0.0000 BilateralSuperior lingual gyrus z = 0.68 p < 0.03501 Bilateral
Parietal Supramarginal gyrus z = 5.02 p < 0.00000 BilateralSubparietal sulcus z = 0.68 p < 0.03501 BilateralInterparietal sulcusv z = 0.68 p < 0.03501 BilateralPost central gyrus z = 4.48 p < 0.0000 Bilateral
Superior parietal gyrus z = 5.64 p < 0.00000 BilateralPrecuneus z = 5.02 p < 0.00000 BilateralAngular gyrus z = 5.02 p < 0.00000
Occipital Lingual sulcus z = 0.68 p < 0.03501 BilateralInferior lingual gyrus z = 4.66 p < 0.0000 BilateralCalcarine sulcus z = 4.66 p < 0.0000 BilateralPosterior transverse Collateral BilateralSulcus z = 6.18 p < 0.0000
Temporal Inferior temporal gryus z = 6.18 p < 0.0000 BilateralSuperior temporal gyrus z = 6.18 p < 0.0000 BilateralMiddle temporal gyrus z = 6.18 p < 0.0000 BilateralSuperior temporal sulcus z = 6.18 p < 0.0000 BilateralFusiform gyrus z = 3.06 p < 0.00111 BilateralSubcollosal Gyrus z = 2.53 p < 0.00570 BilateralParahippocampal gyrus z = 5.59 p < 0.0000 Bilateral
Subcortical Hippocampus z = 6.18 p < 0.0000 BilateralBasal ganlia Head of Caudate nucleus z = 2.53 p < 0.00570 Bilateral
Basal nucleus of amygdala z = 5.59 p < 0.0000 BilateralCrus Cerebri z = 6.18 p < 0.0000 Bilateral
Some examples of the bilateral activation.Table 3. Common activations, individual comparisons of 1st level GLM and individual ICA analyses.Subject
Common Activation (ICA & GLM
GLM only ICA only
AM lobule VII superior lingual gyruscrus ii inferior lingual gyrusprecuneus inferior temporal gyrustail of caudate superior temporal gyrusSuperior parietal gyrus middle temporal gyruscentral sulcus superior temporal sulcusSuperior frontal sulcus Paracentral sulcus
Superior postcentral sulcus
FK Inferior frontal sulcus Cingulate sulcus Inferior lingual gyrusSuperior frontal gyrus Crus I head of the caudateSuperior temporal gyrus Inferior frontal sulcus inferior frontal gyrus
Superior frontal gyrus superior frontal sulcusCingulate gyrus Middle frontal gyrus
central sulcusprecentral gyruspostcentral gyrusPrecuneus
RO Superior frontal sulcus Lobule VII Head of the hippocampusSuperior frontal gyrus Crus II PrecuneusInferior frontal sulcus Superior precentral Superior temporal sulcusInferior frontal gyrus sulcus Inferior precentral sulcusMiddle frontal gyrus Supramarginal sulcus Supramarginal gyrusPost central gyrus Putamen Central sulcusLateral Fissure Superior precentral sulcus Precentral gyrusAngular gyrus Superior Parietal gyrus
SD Caudate nucleus tail of caudate head of caudateLateral fissure Superior frontal sulcus Inferior frontal gyrus
Superior frontal gyrus Inferior temporal gyrusPutamen Superior postcentral sulcusSuperior temporal sulcus Lingual sulcus
cingulate gyrusprecuneusInferior precental sulcusCentral sulcusSubparital sulcus
Superior parietal gyrusIntraparietal sulcusAngular gyrusParacentral lobuleCingulate sulcus
DISCUSSION
Seeing as the implicit goal of this thesis was to establish the methodological and
interpretational effects of using model-free approaches to biomedical signalling
experiments, this discussion will begin with focus on the statistics including the
technical issues related to the operating systems used for each and then go on to
discuss the specific anatomical discrepancies that show up in a comparison between
results from a model-based GLM and model-free ICA, relating to the research
introduced at the start of this paper.
The Hayter et al., (2007) hypothesis focussed on testing the interconnectedness of
the prefrontal cortex with the cerebellum in line with past research referred to in
the introduction and they used a GLM statistical approach. This study attempting to
discover what more could be said about the neural dynamics of the same data from
a PASAT VWM task, using a different, model-free statistical approach (ICA).
To create a GLM, manual input of the regressors of interest into a design matrix is
required, within SPM5 and MATLAB, allowing for a close inspection of the BOLD
responses relevant to the experimental episodes of ADD vs REPEAT condition.
Maps of peak-voxel cluster activity were produced and there were some definite
similarities as well as considerable lack of matching activity between the current
results of the earlier results from Hayter et al., (2007), especially in the Occipital and
Parietal lobes.
These differences, became, considerably more detailed in the ICA maps, which
produced nearly 600 less components for the analysis of temporally relevant
activations. Due to the sheer density of human programming, it can be estimated
that some of the lacking activations within the GLM re-run, were due to human
error, and disparate inter-observer reliability but more importantly, the fact that the
Hayter et al., (2007) study was solely driven by a hypothesis that expected to see
considerable activity in the cerebellum may have lead to their finding more supra
threshold voxels in that area. It is not suggested that the previous researchers,
made up these findings, only that the considerable variation could be due to the
inadequacies of the programs used to produce such maps and the substantial room
for selectivity in honing in on particular areas within whole brain activity that
support predetermined hypotheses in the minds of the researcher and within a
model-based approach in general.
There are several comparable differences and difficulties regarding the localisation
of activations from data from multiple subjects into a standardised space that allows
for direct comparisons, aside from the issues mentioned above, both FSL and SPM5
have their strengths and drawbacks with regards to this salient issue.
Whereas the GLM analysis within SPM5, lists tables with peak-voxel activations,
allowing you to explore the variously spread clusters of activation, to find the most
significantly activated voxel amongst a cluster of activations. FSL does not provide
interactive thresholds; it is possible to go into the components and establish which
activation was ‘peak’, but as for a simple method for doing that, there seems not to
be none, other than the colour intensity bars produced aside the component images,
reflecting the significance of the signal, using the colour spectrum as representative,
but it is extremely difficult to see, clearly, which areas are most significantly
activated and to get a sense of the relative activity across the brain; essentially its
like trying to look a jigsaw with lots of shades to blue and red and trying to see
which ones were more important, it is possible, but not very reliable. From a
general view, localisation from SPM5, with the ease of overlaying onto template
brains and the use of coordinates that are transferable into the MRICRO program,
which allows for even more scrutiny regarding localisation, seems to provide more
confidence in the process of localising, and somewhat helps to narrow down the
areas of interest, but then again, the GLM approach has the benefit of the model. FSL
appears to show you much more and makes the job of discerning important and
relevant localisations, not only more time consuming, but less reliable, as there is no
direct method of overlaying the activations from independent components onto a
stereotaxically homologous space. This vital tool, of being able to directly transfer
to image acquisitions onto a definite brain, with landmark features to assist in the
localisation, which by any stretch of the imagination is not without the risk of
human error, is a crucial failing of the FSL program approach to univariate analyses.
GLM attempts to extract a specific signal, that best fits the specified temporal model,
identifying regions of the brain that activate with similar time courses to the
experiment, depending on the Gaussian nature of the data. ICA extracts non-
gaussian data from a Gaussian, mixed source rather than the data that best fit the
model. ICA assumes that signal components are not only uncorrelated but also
‘statistically independent’, and attempts to find them from the mixed data-set of
fMRI timecourses and assumes that these signals derive from physically different
processes, thus maximising a measure of the joint entropy of the extracted signals
(Friston, 1998). Both ICA and GLM can be used; if there is sound reason for specific
hypothesis-testing, model-based approaches would be preferable, but if a model-
based approach wouldn’t extract all the signals of interest (as has been
demonstrated in this study), exploratory, data-driven methods can be more
appropriate.
FSL exceeds SPM5 in terms of options for viewing results, with one-click changes
from tables to graphs, displaying Gamma distributions of time courses that
represent independent components, allowing you to assess their affinity to the
experimental timings, and thus making sounder inferences regarding the relevance
of a particular component (if the time course matches that of the experiment, it is
likely to have something to do with experiment). You can plot graphs with SPM5,
but it lags in the immediacy of the FSL program, and somewhat in its usefulness.
SPM5 allows for whole brain p-values, which create tables of MNI co-ordinates
allowing for more certainty in localisation (with the use of MRICRO), whereas FSL
cannot do this. As a first time user, these comments may merely show a lack of
complete knowledge about the systems being discussed, but overall, there were
mixed pros and cons with both SPM5 and FSL. During different stages of the data
management and processing, each technique offered sometimes easier and
sometimes more difficult sets of command chains to go through in order to do the
necessary computations. Although the reanalysis did align generally to the results
from the previous study, there were some discrepancies, and it would seem almost
impossible for there not to be differences, because each time you reanalysed the
same set of data, there are clearly far to many areas for operational error.
In summary, GLM allows for partitioning of variance, in understanding the degree to
which each regressor explains the data. SPM5 computes a GLM on each voxel
serially, demanding Gaussian distribution of data. ICA takes an essentially Gaussian
mixture and tries to delineate the non-Gaussian distributions within it. It is
suggested that the use of both methods concurrently, is so far the best option for
trying to gather a holistic picture of brain activity during neuroimaging tasks, and
especially in the current climate of comparing each method to establish its relative
contribution; at this stage, neither stands out as a clear victor, so fortunately for
neuroscientists, applying multiple statistical techniques of brain imaging data,
seems to be the most sensible way forward
Understanding the neural mechanisms underlying active maintenance of task
relevant information hinges on how we resolve the nature of stored
representations, in addition to the types of operations performed on such
representations (D’Esposito, 2007). Representations equate to symbols and codes
for information that are activated transiently or continuously within neural
networks, and operations or processes (computations) are performed on these
representations. Areas of the multimodal cortex (PFC & parietal cortex) are in a
position to integrate representations through connectivity to the unimodal
association cortex and are also critically involved in the active maintenance of task
relevant information (D’esposito, 2007). Fuster, (1997), expounds that the PFC is
critically responsible for temporal integration and mediation of events that are
separated in time such as in the ADD condition of this PASAT test. To explore this
problem further specific results from both GLM and ICA will be discussed in relation
to the original Hayter et al., (2007) findings.
Frontal Lobe
At 2nd level (between groups), GLM analysis found similarities with the original
findings in the superior/middle frontal gyrus, cingulate gyrus, central sulcus,
precentral gyrus and superior precentral sulcus.
ICA finds inferior frontal gyrus, superior frontal sulcus, medial orbital gyrus, inferior
precentral sulcus, central gyrus, inferior precentral sulcus, superior postcentral
sulcus, paracentral sulcus, superior lingual gyrus, which did not show up from the
GLM.
According to Abdullaev (1997), bilateral premotor region (BA 6) – middle frontal
gyrus, activates due to stimulus effects, whereas BA 44/45 – inferior frontal gyrus,
shows effects of context but not stimulus and episode effects occur in both. The
frontal lobe activity found here, seems to support rostro-caudal accounts of lateral
PFC and premotor regions, dealing with cumulative cognitive demands, in a
cascading manner and fits within the classical theory of executive control (Koechlin
et al., 1997)
Ist level (individual differences) within GLM and ICA analyses highlight some other
discrepancies between the results. Some examples from individuals upon whose
results, both ICA and GLM analyses were computed.
Subject AM:
No common activations between GLM and ICA were found however GLM found
almost equal number of activations that ICA did not, including the central sulcus and
superior frontal sulcus. ICA found activity in the paracentral sulcus and superior
postcentral sulcus. These differences could be down to minute discrepancies in
localisation procedures, or they could reflect operational disparities between the 2
methods under discussion. Over all, these differing frontal activations, on their own,
do not negate other findings, indeed they may add to them, if we take the view that
both methods show us things that the other is not capable of, and by combining
data, our understanding is further enriched. Paracentral, superior postcentral and
central sulci move dorsoventrally from medial cortical areas towards and into the
superior frontal gyrus, it could be that these areas, play a significant role in the
particular demands of the VWM task but it would be difficult establish this from
group statistics alone, only by combining individual activations within 1st level GLM
results and the robust components from the ICA, can we begin to see, how both
methods, compliment, as oppose to exclude the other.
Parietal
2nd level GLM statistics, failed to retrieve any activations in the parietal lobe, despite
their being found with ICA and previously in Hayter et al., (2007). Considering, that
the GLM was input into the ICA, and the ICA managed to find similar activation in
the IPS and various parts of the parietal lobe. It is an anomaly to this researcher as
to why these results differed so extensively. On the basis that Hayter et al., (2007),
found similar activations and several significant independent components were
found in the parietal lobe during the ICA, it is proposed that these lacking data from
GLM reflect some mistake that may have been made in the preprocessing stages, for
there is no other obvious route to the discrepancy, and as such it is used an example
of how, the resource intensive manual data entry, involved in the setting up of the
model within the SPM5 programme, can allow for fairly huge differences in results,
due to human error, that is extremely difficult to trace and remedy.
Based on the research, these parietal areas probably represent how the Parietal lobe
is critically involved in VWM. Majerus et al., (2006), found that the IPS is
functionally connected to serial/temporal processing areas in the premotor and
cerebellar cortices, as well as to phonological and orthographic processing areas in
the superior temporal and fusiform gyri. This connectivity, suggest that parietal
areas (the IPS especially) act as attentional modulators of distant neural networks
that are known to deal with language and order information. The IPS, does seem to
be influenced by cognitive load and demonstrates a fronto-parietal-cerebellar
network for verbal short-term memory tasks, that is supported by our data.
Majerus et al., (2006), also note the recent discovery of increased connectivity
between IPS and medial superior frontal gyrus, cuneus and bilateral posterior
cingulate cortex involved in visual mental imagery, so these activations seem to
show that the Parietal areas of the brain, take part in managing and communicating
information from higher order processing areas in the frontal areas, to multimodal
cortex and towards the cerebellum, where automaticity of learning relieves the
demands on WM structures in the prefrontal areas to deal with novel information.
Phonological processing is known to activate the left interior parietal lobe, posterior
inferior frontal gyrus (Broca’s area), premotor cortex and the cerebellum
(D’Esposito, 2007). It is interesting to note that all parietal activations discovered
through ICA, were bilateral activations, which seem to suggest that their joint
activity, is not only task-related, but almost certainly not noise. The chances that
ICA would find perfectly bilateral activations in brain areas known to be
implemented during VWM tasks, consistently across subjects, is far more indicative
of the benefits of using ICA than the possibility that these may be uncorrelated.
Temporal
At 2nd Level, GLM finds the insular lobe (as did Hayter et al., 2007), along with
anterior and intermediate temporal gyri. ICA, on the other hand, does not find these
areas, but implicates inferior-, superior- and middle-temporal gyri, along with the
superior temporal sulcus, fusiform gyrus, subcollosal gyrus and parahippocampal
gyrus. 1st level GLM statistics for subject SD showed superior temporal gyral
activity that was not common to the ICA data, whereas subject FK, showed a
common activation there for both GLM and ICA. AM, RO and SD, all display
significant temporal lobe activations from the ICA, providing as yet, the most
commonly activated area in this comparison. Temporal activity here, reflects the
phonological component of the verbal task at hand. Majerus et al., (1996), state that
the posterior superior temporal gyrus is involved in the processing of novel
phonological information.
Subcortical
Caudate nucleus, subthalamic nucleus (putatively substantia nigra), and cerebellum,
all displayed clear activity from the 2nd level GLM statistics, whereas ICA delineated
the hippocampus, basal nucleus of the amygdala and crus cerebri, as being
significantly activated during the experiment. At 1st level GLM analysis, lobule VII
and crus II in the cerebellum were found in subjects AM and RO, caudate activations
were discovered in the results for subject AM and SD, and subject FK demonstrated
activity in crus I of the cerebellum. Overwhelmingly, ICA could not pick up any of
these findings, except for caudate activity, adding something by finding hippocampal
activity in subject RO. Clearly, there is subcortical involvement in the demands of
WM, but it seems as though GLM does a better job of retrieving these activations.
It is well established that the caudate nucleus, which is part of the striatum, is an
integral part of the fronto-striatal circuit subserving cognitive functions (Abdullaev
et al., 1997) with afferent connections from frontal and temporal-parietal cortical
areas and efferents to the basal ganglia, it would seem that these networks
contribute to the dorsolateral prefrontal and anterior cingulate pathways of
cognition. One suggestion is that the head of the caudate is implicated in the
prefrontal circuitry responsible for semantic and phonological computations in
cognitive tasks (Abdullaev et al., 1997) providing a reasonable explanation for why
caudate activity was found in this analysis, based on the phonological and higher
order cognitive demands of the original task.
CONCLUSION:
Over all ICA finds more, but there are instances where ICA misses something that
GLM finds, so using both methods is the surest way to get the fullest picture of what
is going on in the brain during this task. One caveat to the ICA is that group analysis
within stereotaxic space as opposed to individual brains is not possible at this stage.
This means that we can only make inferences about individual subjects and not
between subjects, at least not statistically. GLM adheres to a rigid hypothesis, which
is argued, may consider some significant activity as noise, which is why a
combination of hypothesis driven and data-driven methods is forwarded.
There were many complicated steps in the analysis of this data, and SPM5 requires
considerably more manual input, allowing for more potential human error. More
checks would increase reliability in the statistics, and although, necessary reviews
were made, more would be recommended to improve statistical confidence on the
part of the researcher. Had there been more time, more space on the server and
more brain power in the case of this novice attempt to understanding results from
neuroimaging studies, stronger arguments could be made. In future, working with
fresh data would be recommended and variations in the size of the smoothing
kernel applied might highlight some interesting results. It is believed that the
preprocessing and statistical analyses computed for this study, were the same as the
original study, though it seems more likely that discrepancies in results between the
2 identical GLM analyses are either due to the use of a different SPM5 (instead of
SPM2) programme, or that this first try, inevitably lead to some mistakes being
made. The group was also limited in the storage space available on the server’s
hard-drive to compute additional analyses, not that there would have really been
time or scope for this undergraduate thesis to deal with so much more detail.
A reanalysis of the Hayter et al., (2007) GLM analysis, revealed some consistent and
some discrepant findings of neuronal activity in areas that are now well established
as being recruited during the multimodal and multi-sensory activity of performing a
PASAT. Some suggestions for these discrepancies and evidence to support the
consistencies have been made, along with more detail found from running an ICA on
the same data. Overall, both statistical approaches, together, help to support the
cascading model of hierarchical executive function (Koechlin et al., 2007). The
relatively consistent prefrontal, parietal, temporal and subcortical activity found in
this study, that to a greater extent contributes, as opposed to disputes the earlier
findings in Hayter et al., (2007), seems to suggest a postero-anterior axis for
corticosubcortical WM operations. This study supports the notion of a fronto-
parietal/temporal-cerebellar network for VSTM, which is evidenced by the work of
Petrides (2005), who found that frontal area 47/12 had strong links to rostral
inferotemporal visual association cortex and ventral limbic areas including rostral
parts of the parrahippocampal gyrus. It is argued that active judegments on stimuli,
typical to the requirements of the PASAT, are coded along a frontal mid-
ventrolateral executive system that implements posterior association cortex during
VWM tasks.
GLM results or ICA results alone, would not provide enough detail for one to make
this conclusion, so the use of both techniques, in this case seems to have provided
the clearest picture of what happens in the brain during this PASAT. Some of the
strongest findings however, came from the ICA which brought attention to the
Parietal lobe in particular, which is why this paper took the position it did, regarding
fronto-caudal pathways which implicate a lot of the areas found in this investigation
that may not have been so well understood without the knowledge about the IPS
which certainly represents the most robust finding from this study and the unique
contribution that ICA has made to this line of research.
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