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Understanding Behavior and Brain

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Title: Understanding Behavior and Brain


1
  • Understanding Behavior and Brain
  • Activity Using fMRI Imaging
  • Simone Campbell, Jim DeLeo, Carl Leonard
  • Aron Barbey and Jordon Grafman
  • National Institutes of Health
  • Bethesda, Maryland
  • Scientific Computing Section, NIHCC
  • Cognitive Neuroscience Section, NINDS

2
Objective
  • To study achievements in cognitive neuroscience
    that have led to better under-standing of how
    mental representations map into neural activity
    patterns and to suggest that new advancements in
    computer science may be useful in furthering this
    work, particularly with regard to bridging the
    gap between basic research and patient care - the
    main goal of translational medicine.

3
What is Functional MRI?
  • Functional Magnetic Resonance Imaging (fMRI) is a
    neuroimaging technique that measures dynamic
    regulation of blood flow (hemodynamics) related
    to neural activity in the brain.
  • The difference between an MRI and an fMRI scanner
    is that MRI scanners depict anatomical structure
    of the brain and other body areas, whereas fMRI
    depicts the metabolic activity within that
    anatomical structure in the brain.

MRI scan depicts only the structural make up of
the brain.
fMRI scan colored regions represent areas of
increased metabolic activity.
A typical fMRI scanner.
Source http//www.dmoma.org/lobby/movies/images/w
_logan_fry_axial_section.jpeg
4
Energy Use in the Brain
  • The brain requires energy in the form of glucose
    and oxygen in order to function. This energy is
    supplied by the blood, which carries oxygen in
    the protein hemoglobin. This energy is used by
    neurons, the basic information processing cell in
    the brain.

5
Neural Activation
Source http//www.scholarpedia.org/article/Neurov
ascular_coupling
Neural activity requires energy in the form of
Adenine Triphosphate (ATP). ATP is produced by
glycolysis, which is the breaking down of
glucose, and by oxidative phosphorylation, which
requires oxygen to produce a large amount of ATP.
Blood vessels dilate in response to activation,
increasing blood flow and oxygen and glucose
delivery to the brain.
6
Energy Delivery
  • Regions of increased neural activity require more
    energy, thus more blood flow to that active
    region. When a brain region is activated, a
    hemodynamic response is triggered, which is an
    increase in blood flow and blood volume in the
    brain. This action is the foundation for fMRI
    acquisition.

Resting vs. activated regions of activity
Vessels dilate to facilitate an increase in blood
flow to the active region.
Source http//www.fmrib.ox.ac.uk/education/fmri/in
troduction-to-fmri/images/BOLDeffect.png
7
Magnetic Properties
  • A difference in the magnetic properties of
    oxygenated and deoxygenated hemoglobin is the
    starting point for acquiring fMRI scans.
    Oxygenated hemoglobin is diamagnetic, slightly
    repelling a magnetic field, while deoxygenated
    blood is paramagnetic, slightly attracting a
    magnetic field.

8
BOLD Response
  • Blood Oxygen Level Dependent (BOLD) signal
    measured represents the total amount of
    deoxygenated hemoglobin present.

There will be more magnetic resonance (MR) signal
where blood is highly oxygenated and less MR
signal where blood is highly deoxygenated.
This image depicts the changes in MR signal
depending on the level of oxygenated vs.
deoxygenated blood present
Source http//www.cmrr.uic.edu/sections/fmri20ma
terials/images/Bold_contrast
9
Precession
  • MRI scanners apply a powerful magnetic field to
    the subject. This causes the nuclei of a
    particular atom to undergo precession. Precession
    occurs when nuclei alter their orbit and align
    with the induced magnetic field. Some atoms have
    a positive spin, while others have a negative
    spin. Positive spin atoms always cancel out
    negative spin atoms. At room temperature there
    are more positive spin atoms than negative spin
    atoms, leaving unmatched positive spin atoms.

Source http//hyperphysics.phy-astr.gsu.edu/hbas
e/mechanics/imgmech/topp.gif
Precession refers to a change in the
direction of the axis of a rotating object. The
axis of the spinning object wobbles when a
magnetic field is applied to the atom. All
spinning objects, like the spinning top above,
can undergo precession.
10
Electron
How Signal is Detected
Nucleus
Atom
Energy levels
Positive spin atom in resting state.
Radio frequency pulse
Radio frequency pulse applied, causing atom to
resonate
Radio frequency pulse absorbed as a photon,
raising energy level
Radio frequency pulse removed. MRI machines
detect the photon energy emitted by atoms as they
transit from excited to resting
state.
Unmatched positive spin atoms are used by MRI
machines. Positive spin atoms are in a low energy
state. Magnetic energy perpendicular to the main
magnetic field is introduced in the form of a
radio frequency pulse specific to the atom,
causing the atom to jump up an energy level. When
this radio frequency pulse is removed, the atom
returns to its resting energy state. MRI machines
detect the photon energy emitted by the atom
while it is dropping back down to its resting
energy level after the radio frequency pulse has
been removed.
Positive spin atom in resting state.
11
fMRI Imaging
fMRI imaging provides thin tomographic vol-
ume slice images that reflect neuronal activity
in the brain.
12
Example of fMRI Image
  • Increased blood flow is represented in fMRI
    volume elements (voxels) in three dimensional
    space. Colored regions represent voxel patterns
    where blood flow has increased. This corresponds
    to increased neural activity. Analyzing images
    like these has been important in cognitive
    neuroscience for achieving a better understanding
    of brain function.

Source http//www.nature.com/jcbfm/journal/v26/n1
0/fig_tab/9600274f1.html
13
Cognitive Neuroscience And Neural Activity
  • Cognitive neuroscience is providing new knowledge
    about how mental representations map onto
    patterns of neural activity. Much of this
    success is related to the use of
    pattern-classification algorithms applied to
    voxel patterns of functional MRI data with the
    goal of decoding the information that is
    represented in the subjects brain at a
    particular point in time. These multi-voxel
    pattern analysis (MVPA) methods are useful for
    advancing understanding of neural information
    processing.

14
Method of Analysis for fMRI Results
  • MVPA can be used to distinguish between
    cognitive states. Upon analysis of the results,
    categories of stimuli (ex. houses, scissors and
    chairs) can be with a reliable pattern of
    activity in a region of the brain. MVPA can be
    effective in distinguishing the category of a
    viewed object.

15
Patterns of Response
The image to the left shows the results of
analyses of fMRI scans used to measure patterns
of response in the ventral temporal cortex while
subjects viewed pictures of houses, chairs, and
other manmade products. Distinct patterns of
response were detected for each category of
stimuli. These distinct patterns were seen as
well when that particular region was excluded
from the analysis. Red and dark blue bars
represent analysis involving ventral temporal
cortex, an area most responsive to the stimuli.
Orange and light blue bars represent analysis
excluding the ventral temporal cortex.
16
Clinical Applications of fMRI
  • Functional MRI (fMRI) has had a major impact in
    cognitive neuroscience. It now has an increasing
    role in clinical applications. (See Table 1.)
    These applications may be realized more fully
    with the support of modern computer science
    methodology.

17
Table 1. Clinical Applications for fMRI
pre-symptomatic diagnoses understanding
functional brain disorders understanding diseases
in general developing individualized
therapies clinical management fMRI-guided
neurosurgical planning fMRI-guided neurosurgery
understanding plasticity in recovery discovery
and development of new therapies
  • pre-symptomatic diagnoses
  • understanding functional brain disorders
  • understanding diseases in general
  • developing individualized therapies
  • clinical management
  • fMRI-guided neurosurgical planning
  • fMRI-guided neurosurgery
  • understanding plasticity in recovery
  • discovery and development of new therapies

18
Presurgical Mapping
  • fMRI guided neurosurgery is a method by which
    physicians map the brain prior to surgery, in
    order to localize cerebral functions in tissue
    near brain regions that are going to be removed
    during surgery. The primary goal would be to
    spare tissue that would limit recovery if damaged
    or removed from the brain. fMRI would be a
    manageable alternative to other imaging
    techniques such as magnetoencephalo-graphy.

19
Functional Characterization of Disease
  • fMRI has the potential to be able to characterize
    the features of functional brain disorders.
    Functional brain disorders are disorders that
    arent clearly associated with any structural
    abnormalities in the brain.

20
Modern Computer Science
  • Modern computer science provides many
    computational tools and strategies that may be
    relevant here. For example evolutionary
    computing (EC) provides techniques for evolving
    specific computational tools for specific
    purposes. Borrowing on ideas from Darwinian
    evolution, solutions evolve guided by optimizing
    one or more fitness functions. Within the frame
    of the EC paradigm, artificial neural networks,
    support vector machines, expert systems, fuzzy
    logic etc. may be used. Data mining (DM) is a
    major theme in computer science today. DM may be
    guided or unguided. In guided DM, particular
    questions are asked. In unguided DM, the machine
    is basically set loose to find interesting
    patterns that may reveal new knowledge or suggest
    new hypotheses worthy of exploration.
    Interactive data visualization is also an
    important and useful tool provided by modern
    computer science. We are interested in exploring
    possible applications of these techniques.

21
Conclusions
  • We have accomplished our objectives in this
    project which were (1) to study the work in
    cognitive neuroscience that has lead to better
    understanding of how mental representations map
    into neural activity patterns and (2) to suggest
    how modern computer science may be used in
    advancing this work particularly with regard to
    bridging the gap between basic research and
    clinical applications - the main goal of
    translational medicine.

22
References
  • 1. Bayesian decoding of brain images
  • Karl Friston, Carlton Chu, Janaina
    Mourão-Miranda, Oliver Hulme,
  • Geraint Rees,Will Penny and John Ashburnera
  • Wellcome Trust Centre for Neuroimaging,
    Institute of Neurology, UCL
  • 2. Analyzing for information, not activation, to
    exploit high-resolution Fmri
  • Nikolaus Kriegeskorte and Peter Bandettini
  • Section on Functional Imaging Methods, Lab of
    Brain and Cognition,
  • National Institute of Mental Health, USA
  • 3. Predicting human brain activity associated
    with the meanings of nouns.
  • Mitchell TM, Shinkareva SV, Carlson A, Chang
    KM, Malave VL, Mason
  • RA, Just MA
  • Science. 2008 May 30320(5880)1191-5
  • 4. Identifying natural images from human brain
    activity.
  • Kay KN, Naselaris T, Prenger RJ, Gallant JL.
  • Nature. 2008 Mar 20452(7185)352-5. Epub
    2008 Mar 5
  • 5. Functional Magnetic Resonance Imaging. Scott
    A. Huettel, Allen W.

23
References
  • 6. Applications of fMRI in translational
    medicine and clinical
  • practice. Paul M. Matthews, Garry D. Honey,
    Edward T.
  • Bullmore
  • 7. Computational aspects of cognition and
    consciousness in
  • intelligent devices.
  • Robert Kozma Hrand Aghazarian, Terry
    Huntsberger, Eddie
  • Tunstel, Walter J. Freeman
  • 8. Beyond mind-reading multi-voxel pattern
    analysis of fMRI data
  • Kenneth A. Norman, Sean M. Polyn, Greg J.
    Detre and James
  • V. Haxby
  • 9. Distributed and overlapping representations
    of faces and objects
  • in ventral temporal cortex
  • James V. Haxby, M. Ida Gobbini, Maura L.
    Furey, Alumit Ishai,
  • Jennifer L. Schouten, Pietro Pietrini
  • 10. wikepedia.com

24
Acknowledgements
  • I am thankful to the Department of Clinical
    Research Informatics (DCRI) in the NIH Clinical
    Center (CC) for allowing me the opportunity to
    learn and experience as an intern here. I would
    like to thank Jim DeLeo and Carl Leonard for
    being supportive and helpful mentors throughout
    this project. My thanks also goes out to Dr.
    Jordon Grafman and Aron Barbey for sharing a
    depth of knowledge that was truly fascinating and
    intriguing.
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