Yale
Seminar Series in
Bioimaging Sciences
Please note that these talks are held in N135 TAC
which is the conference room at the MRRC located at
300 Cedar Street (corner of Congress and Cedar).
Refreshments served 15 minutes prior to start of seminar.
Please call 5-6622 for directions.
Previous Seminars
Fall 2003
Dec 16 (Tuesday), 4:15 pm
John Detre, M.D. (University of Pennsylvania)
ASL perfusion fMRI
The majority of fMRI studies have used blood oxygenation level dependent
(BOLD) contrast as a surrogate marker for regional neural activation. An
alternative contrast mechanism for visualizing regional brain function
provides direct measurement of cerebral blood flow (CBF) using MRI. This
class of techniques is termed arterial spin labeled (ASL) perfusion MRI, and
utilizes magnetically labeled arterial blood water as endogenous tracer for
measuring CBF. ASL methods demonstrate clinically meaningful alterations in
baseline CBF in a variety of CNS disorders. ASL methods are also useful for
imaging changes in CBF in response to task activation or pharmacological
challenges. Existing data demonstrate that 1) CBF measured using ASL
perfusion MRI is accurate and reproducible, 2) ASL contrast shows stable
noise characteristics over the entire frequency spectrum, making it suitable
for studying sequential changes in resting or activated brain function over
long periods, 3) CBF-based task-activation measured by ASL shows less
intersubject variability than BOLD, and 4) ASL perfusion fMRI can be
measured using pulse sequences that are insensitive to susceptibility
effects. ASL methods may be particularly suitable for populations in which
knowledge of baseline CBF contribute to the interpretation of activation
results. This presentation will summarize methodological considerations in
ASL perfusion MRI and illustrate its applications in basic and clinical
neuroimaging.
Dec 9 (Tuesday), 4:15 pm
Michael Garwood, Ph.D. (University of Minnesota)
Magnetic resonance spectroscopy and imaging
of human breast at 4 Tesla
Improved diagnostic tools are needed to reliably detect breast cancer
and to assess therapeutic response early in the course of treatments.
At the University of Minnesota's Center for Magnetic Resonance Research,
we are exploring the use of high magnetic field (4 Tesla) MR imaging and
spectroscopy of breast. As part of this work, we have developed new MR
coils, scanning techniques, and processing methods to exploit the
advantages of high field. Results to be presented show that high field
MRS provides valuable information which improves diagnostic accuracy and
allows early identification of therapeutic response vs. non-response.
The latter capability will ultimately allow oncologist to individualize
treatments to achieve maximal benefit and to speed the transfer of new
drugs from the laboratory to clinic.
Jianhui Zhong, Ph.D. (University of Rochester)
Oct 23 (Thursday), 4:15 pm
Imaging from intermolecular multiple-quantum coherence:
Do we need another contrast mechanism?
Dr. Zhong is Professor in the Departments of Diagnostic Radiology
and Biomedical Engineering, Schools of Medicine and Engineering
at the University of Rochester, NY.
The list of different MR techniques and related contrast mechanisms
continues to grow even after more than 50 years of development and
four Nobel Prizes. One of the reasons is that with the introduction of
every new technique, there is hope (or hype) of achieving a new level
of understanding of underlying physio-/pathology revealed by the
measurement. We have done some preliminary works with
intermolecular multiple-quantum coherence (iMQC) imaging both in
animals and in humans. In this talk I will demonstrate that iMQC
signals possess some characteristics different from conventional
MRI signal, and can be used potentially to study functions and
microstructures of biological interests. Fundamental issues including
low intrinsic SNR in iMQC and possible remedies will also be discussed.
Spring 2003
Robert Mach, Ph.D.
Receptor imaging studies in nonhuman primate
models of aging and substance abuse
Tues, Apr 29, 4:00 PM (refreshments at 3:45 pm)
CAB N135
MRRC, CAB Building
300 Cedar Street
Dr. Mach is Professor of Division of Radiological Sciences at the
Mallinckrodt Institute of Radiology in Washington University School of
Medicine, St. Louis, MO.
Prof. Mach's laboratory is actively participating in synthesis and
biological evaluation of ligands for imaging the activity of various
receptors in vivo. He will discuss some recent PET work on primate
models.
Derek Toomre, Ph.D.
Cellular highways, traffic jams, explosions and
the (Q-) bridge: new insights with advanced live
cell imaging approaches
Tues, Feb 18, 2003, 4:00 PM (refreshments at 3:45 pm),
MRRC, CAB Building, N135
300 Cedar Street
Dr. Derek Toomre is a new faculty with the Department of
Cell Biology and is also the Director of a new light
microscopy imaging center called "The CINEMA laboratory"
(Cellular Imaging using New Microscopy Approaches)
located in the Yale School of Medicine. As a post-doc he
trained with Dr. Kai Simons at the EMBL in Heidelberg,
Germany.
The application of new advanced live cell imaging (and related)
approaches are providing new insight to the dynamics and
organization of important cellular processes. For instance,
the use of evanescent wave or Total Internal Reflection
Fluorescent Microscopy (TIRFM) allows one to observe and
analyze membrane and cytoskeleton dynamics in the first
100nm of the cell with incredible signal-to-noise - permitting
visualization of fusion of single vesicles with the plasma
membrane. Automated image processing and Monte Carlo
simulations have revealed that these exocytic fusion events
occur non-randomly in cellular hotspots. 4D multicolor imaging
of membrane traffic will also be discussed.
Vince Calhoun, PhD
Independent Component Analysis of Functional
MRI Data in the Complex Domain
Tues Jan 21 2003 4:00 pm (refreshments at 3:45 pm),
MRRC Conference Room N135 CAB
Dr. Calhoun is an Assistant Clinical Professor in the Department of
Psychiatry, Yale University School of Medicine and is the Director
of Medical Image Analysis Laboratory at the Olin Neuropsychiatry
Research Center, Institute of Living, Hartford.
Virtually all fMRI studies analyze only magnitude images even though the
acquired data are complex image pairs. We recently proposed a
synthesis/analysis model for fMRI data that can be used to optimize
independent component analysis (ICA), a flexible modeling technique, and
extended it to multiple subjects. In this talk, we discuss the extension of
the model to processing of complex images. Using a flexible approach such
as ICA is especially important in this case since it is unclear how to
model the complex fMRI data. We will derive and apply several complex ICA
approaches to fMRI data and discuss their relative advantages and
disadvantages. We will also discuss certain challenges when using the phase
information, such as increased sensitivity to certain artifacts. Through
simulations and fMRI data we show that utilizing complex data appears to
provide an empricial sensitivity increase. Additionally, the phase
information may be useful for data interpretation and enable the separation
of smaller and larger blood vessels. We will thus demonstrate that it makes
both intuitive and empirical sense to develop methods to more fully utilize
the available data in an fMRI experiment.
Fall 2002
Rikki Waterhouse, PhD
Development of PET Radiotracers for Glutamate Receptors
Tues Dec 17 2002 4:00 pm,
CAB N135 MRRC Conference Room, 300 Cedar Street
Dr. Waterhouse is an Assistant Professor in the Departments of
Neuroscience and Psychiatry and is also is a faculty in the
Division of Biological Psychiatry at Columbia University.
The presentation will cover various aspects of the development of
metabotropic and ionotropic glutamate receptor radiotracers for PET
and SPECT, with a paricular focus on the NMDA ion channel, and
group II mGluRs. The speaker will present her work in this area
carried out over the past 3 years.
Arne Hengerer, PhD
Molecular biology for medical imaging
Mon, Dec 9, 4:00 PM
CAB N135 MRRC 300 Cedar Street
Dr. Hengerer is presently Director for New Business Development
in Molecular Imaging at Siemens Medical Solutions in Erlangen,
Germany. He received his ph.D. in Molecular Biology, and his
thesis focussed on recombinant proteins for biosensors.
Molecular imaging is currently in its early stages. Encouraging advances
achieved in clinical PET and animal research indicates that this technique
evolves into an indispensable diagnostic tool. When employed
complementary to morphological imaging procedures, molecular imaging
will result in a substantially improved diagnostic power. With molecular
imaging earlier diagnosis of diseases compared to morphological imaging
will come within reach, since anatomical structures always follow changes
at the molecular level. Thereby it is possible to detect diseases much earlier,
preferentially at their onset. Finally the focus from diagnostics might change
from simple diagnosis to disease prediction and prevention. Consequently
a conversion of the healthcare systems aimed at "sickness repair" to one
focused on maintaining wellness might evolve. Nuclear imaging is the only
clinically established molecular imaging modality so far. Among the emerging
therapies, which will create further applications for medical imaging are targeted
drug delivery, gene therapy and stem- and immuno-cell therapy. All these
therapy schemes heavily depend on localized molecular information, i.e. on
molecular imaging.
David A. Jaffray, Ph.D.
Flat-Panel Cone-Beam CT: An Adaptable Technology
for Image-Guidance Applications
Wed, Dec 4, 4:00 PM
CAB N135
MRRC
CAB
300 Cedar Street
Dr. Jaffray is the Fidani Chair of Radiation Physics and Head of Radiation
Therapy Physics at the Departments of Radiation Oncology and Medical
Biophysics in University of Toronto.
Localized therapies are often compromised by the lack of peri-therapeutic
imaging data. Additional imaging data acquired in the therapy setting
allows intra-operative planning as well as monitoring and feedback.
Many investigators have pursued the development of such imaging systems
with varying degrees of success. Flat-panel cone-beam CT (FP-CBCT)
promises to be a powerful and adaptable new imaging technology for
applications that demand volumetric soft-tissue imaging in a variety of
settings. FP-CBCT has been made viable through the development of large,
robust 2D x-ray detectors (amorphous-silicon photodiode arrays) and high-
speed reconstruction hardware for cone-beam CT. Investigations over the
past three years have demonstrated the potential of this technology to
generate high-resolution (sub-millimeter), low-dose (~0.5 cGy) volumetric
([25cm]3) CT images with soft-tissue contrast sensitivity comparable to
conventional CT. Many of the physical challenges of cone-beam CT have
been examined and the hypothesis that flat-panel cone-beam CT is a
powerful technology for image-guided therapy remains strong. The real
test of this technology is beginning, as application specific embodiments
of the technology are being explored. At present, two image-guidance
system are being constructed based upon this technology - a linear
accelerator with on-board cone-beam CT, and an isocentric, mobile
C-arm capable of intra-operative cone-beam CT. Clinical applications for
this new technology will be presented, ranging from high-precision
radiation therapy of the prostate to C-arm based image-guided
brachytherapy and vertebroplasty.
Spring 2002
Donald G. Buerk, Ph.D.
Physiological measurements and modeling of
nitric oxide biotransport in vivo
Thurs, Jan 10, 4:15 PM
Hope 110
Jane Ellen Hope Building
315 Cedar Street
Dr. Buerk is a Professor in the Departments of Physiology, Bioengineering,
and the Institute for Environmental Medicine at the University of
Pennsylvania, Philadelphia, PA.
In vivo measurements of tissue oxygen partial pressure (pO2) and nitric
oxide (NO) have been made with recessed electrochemical microsensors in the
cerebral cortex and other tissues in rodents and cats. Blood flow was
measured by laser Doppler flowmetry in most experiments. The role of NO in
coupling blood flow with increased neuronal activity has been studied in
the rat somatosensory cortex during electrical stimulation of the forepaw,
and in the cat optic nerve during photic stimulation of the eye with
flickering light. Hyperbaric O2 exposure has been studied in rats, and in
knock-out mice lacking genes for neuronal NOS (nNOS) or endothelial NOS
(eNOS). Increases in cortical tissue NO with hyperbaric O2 at 2.8
atmospheres absolute (ATA) were associated with increased nNOS
activity. Vascular endothelial growth factor (VEGF) and growth of new blood
vessels into collagen gels implanted over the cortex has been studied with
NO microsensors. Mathematical models for NO biotransport including effects
on O2 metabolism and O2 transport to tissue are under development. Although
NO is a simple molecule, it has complex biological interactions that are
intriguing to investigate and difficult to model. Tissue NO measurements
using recessed NO microsensors provide insight into the complex behavior of
NO in physiological systems.
Robin A. de Graaf, Ph.D.
Nuclear Spin Gymnastics.
Optimization of In Vivo NMR Studies on
Brain Energy Metabolism.
Tues, Jan 22, 4:00 PM
Hope 103
Jane Ellen Hope Building
315 Cedar Street
Dr. de Graaf is an Assistant Professor in the Department of Diagnostic
Radiology and is an important member of the Section of Bioimaging Sciences
as well as the Magnetic Resonance Center.
NMR is becoming a dominant tool to study anatomy, function, and metabolism
non-invasively in vivo. MR imaging (MRI) and in particular functional MRI
is ideally suited to study brain function in response to physiological
stimulation, while MR spectroscopy allows the quantitative detection of
important metabolic pathways, like the TCA cycle. Even though NMR is, in
principle, a quantitative technique, the acquisition of reliable, robust
and quantitative NMR data is not straightforward. Nuclear spin gymnastics,
both theoretical and experimental, are at the heart of designing optimal
NMR sequences. Proton-observed, carbon-edited NMR spectroscopy sequences
will be used as a central example to illustrate the requirements to convert
induced electrical current ("the NMR signal") to quantitative metabolic
fluxes.
Mark D. Does, Ph.D.
Tissue characterization using sub-voxel
MRI studies
Tues, Jan 29, 4:00 PM
Hope 103
Jane Ellen Hope Building
315 Cedar Street
Dr. Does is an Assistant Professor in the Department of Diagnostic
Radiology and is an important member of the Section of Bioimaging
Sciences.
One of the great attributes of magnetic resonance imaging (MRI) as a
probe of biological samples is the array of different contrast mechanisms
available (e.g., T1 and T2 relaxation, diffusion, flow, magnetization
transfer, ?). Each unique preparation of magnetization can render image
contrast that can distinguish specific anatomical or physiological
characteristics. In this manner, and with contemporary MRI hardware,
tissues are typically characterized with voxel dimensions on the order
of about 1 mm3. However, in many tissues, complex NMR signal
characteristics can distinguish water compartments that are several
orders of magnitude smaller. For example, careful measurement of
transverse relaxation (T2) in nerve and white matter reveals multiple
relaxation rates, which are thought to be derived from unique micro-
anatomical compartments: myelin, axoplasm, and extra-axonal space.
Using such approaches with T2 and other contrast mechanisms, it
should be possible to better understand MRI tissue characteristics on
a sub-voxel level.
Graeme F. Mason, Ph.D.
MRS studies of neurotransmitter metabolism
in depression and other applications:
13C metabolic modeling
Thurs, Feb 7, 4:00 PM
Hope 103
Jane Ellen Hope Building
315 Cedar Street
Dr. Mason is an Assistant Professor in the Department of Psychiatry
and Biomedical Engineering Program.
1H magnetic resonance spectroscopy (MRS) is used routinely to measure
the concentrations of amino acid neurotransmitters and other compounds
in the brain, and concentration differences have been seen between
resting control states and conditions of altered function, pharmacological
treatment, and various disease states. To explore those differences, kinetic
measurements can be made using MRS of the carbon isotope 13C. 13C is
not radioactive but can be detected with MRS. 13C-labeled substrates are
supplied for use by the brain, where they are converted to labeled products.
The appearance of those products is detected over time. To evaluate those
data qualitatively requires mathematical modeling of the metabolic pathways
that lead to the product labeling. This presentation will cover basic
procedures
for simulating and fitting isotopic flows, with some applications to
illustrate the
method at work.
Rodolfo Llinas
"Imaging the functional substrate for cognition
from single neuron to global brain function:
Is it possible?"
Tues, Feb 12, 4:00 PM
Hope 103
Jane Ellen Hope Building
315 Cedar Street
Dr. Llinas is a Professor in the Departments of Physiology and
Neuroscience at New York University School of Medicine.
Attempting to understand how the brain, as a whole, might be
organized seems, for the first time, to be a serious topic of inquiry.
One aspect of its neuronal organizational that is particularly central
to global function is the rich thalamocortical interconnectivity, and
most particularly the reciprocal nature of this enormous neuronal
loop. Moreover, the interaction between the specific and non-specific
thalamic loops suggests that, rather than a gate into the brain, the
thalamus represents a hub from which any site in the cortex can
communicate with any other such site or sites. The goal of the
presentation is to explore the basic assumption that large-scale,
temporal coincidence of specific and non- specific thalamic
activity generates the functional states that characterize human
cognition.
Peter Bandettini
"The hemodynamic response and more:
Advances and prospects for fMRI"
Thurs, Mar 14, 3:00 PM
Fitkin Amphitheatre (LMP 1094)
Fitkin Building
330 Cedar Street
Dr. Bandettini is a Biophysicist at the Laboratory of Brain and Cognition
(NIMH, NIH) and directs the research efforts at the Unit on Functional
Imaging Methods as well as the Functional MRI Core Facility.
My research at the NIH has been essentially focused on developing
fMRI methodology. This includes better understanding the origins of
fMRI contrast, developing methods to extract more meaningful information
at higher spatial and temporal resolution, working on specific applications
based on what we have learned about fMRI contrast and contrast
dynamics, and lastly, to look into other potential sources of fMRI contrast.
In this lecture, I will describe some of this ongoing work. Specifically, I
will focus on our recent efforts to a) better understand and make use of
the dynamics of blood oxygenation level contrast, b) better understand
the time series fluctuations and how they relate to the "optimal resolution,"
and c) develop methods for extracting and mapping neuronal activity
directly.
Fall 2001
Richard P. Kennan
Transcranial Near Infrared Spectroscopy of
Brain Function
Thurs, Dec 6, 4 PM
Hope 103
Jane Ellen Hope Building
315 Cedar Street
Dr. Richard P. Kennan is an Assistant Professor in Diagnostic
Radiology at Albert Einstein School of Medicine. His lab has a
strong focus towards improving functional imaging methods
(fMRI and NIRS).
It has long been known that light in the near infrared region is
sensitive to changes in hemoglobin oxygenation state and
concentration in living tissue. This effect has been exploited
in the development of peripheral pulse oximetry and tissue
oximeters. More recently, transcranial near infrared spectroscopy
(referred to as optical topography) has been developed for
visualizing brain function by mapping optical absorption changes
on the cortical surface. Near infrared spectroscopy yields
complementary information to other hemoglobin sensitive
methods, such as fMRI, and can thus provide a more
complete understanding of the underlying phsyiology.
Furthermore, the facility of optical methods allows non-invasive
measurement of human brain function under a variety of
conditions without subject restriction . Data shall be presented
on the MRI based validation of optical topography techniques in
motor, auditory, and cognitive tasks as well as current work in
progress towards monitoring tissue oxygenation in sickle cell
disease.
Seong-Gi Kim
Limitation of fMRI resolution: How finely is CBF
regulated?
Thurs, Dec 13, 4 PM
Hope 103
Jane Ellen Hope Building
315 Cedar Street
Dr. Seong-Gi Kim is an Associate Professor in Diagnostic
Radiology at University of Minnesota, Minneapolis. His lab has
a strong focus towards improving the temporal and spatial
resolutions of MRI-based neuroimaging methods.
Functional MRI has been widely utilized for imaging brain functions.
However, the extent of the fMRI hemodynamic response around active
cortical columns remains poorly understood and controversial. Thus,
we evaluated BOLD and CBF responses using a well-established cat
orientation column model and a rat somatosensory model. As expected,
conventional positive BOLD signals contained large draining vessels,
and were not localized only to active neuronal active sites. Activation
maps obtained using CBF fMRI were devoid of large draining vein
contamination, and CBF responses were spatially localized to cortical
columns/layers. These results suggest that hemodynamic-based fMRI
can indeed be used to map high-resolution functional structures if large
vessel contributions can be minimized.
Kamil Ugurbil
Functional neuroarchitecture investigated using
nuclear spins
Tues, Dec 18, 4 PM
Hope 103
Jane Ellen Hope Building
315 Cedar Street
Dr. Kamil Ugurbil is a Professor in the Department of Diagnostic
Radiology at University of Minnesota, Minneapolis. He is also the
Director of the Center for Magnetic Resonance Research at
University of Minnesota, Minneapolis. His lab has played a pivotal
role in the development and application of 13C MRS and
1H MRI-based neuroimaging methods towards functional imaging
of the mammalian brain.
The history of Nuclear Magnetic Resonance is marked by ever
increasing number of innovations that have produced novel and
surprising uses of this phenomenon for probing biological processes.
In the last decade, this approaches has been increasingly used for the
acquisition of physiological and biochemical information non-invasively
in intact systems including the human brain. One of the most notable
accomplishments in this general effort has been the introduction of the
magnetic resonance approaches to map brain function (fMRI). fMRI is
based on the sensitivity of MR signals to secondary metabolic and
hemodynamic responses that accompany increased neuronal activity.
Despite this indirect link to neurotransmission, recent studies from our
laboratory have demonstrated in animal models that under appropriate
conditions, these fMRI maps have accuracy at the scale of submillimeter
neuronal organizations such as the orientation columns of the visual
cortex, and are directly proportional in magnitude to electrical signals,
such as single unit spiking activity, generated by the neurons. High
magnetic fields have been critical in achieving such specificity in
functional maps because they provide advantages through increased
signal-to-noise ratio (SNR), diminishing blood-related contributions to
mapping signals, and enhanced sensitivity to microvasculature. These
gains were recently utilized for the first time in human brain studies at 7
Tesla yielding information on functional parcellation in the millimeter
scale in the fusiform face area (FFA) for object recognition and faces.
Understanding brain function also requires information on connectivity
among different brain regions. Techniques based on anisotropy of water
diffusion have recently been pursued for this purpose. Limitations
encountered by such techniques can be alleviated significantly due to the
enhanced SNR available at high magnetic fields. Using this approach, we
have recently generated simultaneous connectivity and activation maps in
the cat brain at 9.4 Tesla. These recent high field human and animal brain
studies will be presented.
Spring 2001
James S. Duncan, Ph.D.
"Model-Based Medical Image Analysis"
Wed, Feb 7, 4 PM, Brady Auditorium (B 131),
Cedar Street, Yale University School of Medicine.
Dr. Duncan is a Professor in the Departments of Diagnostic Radiology and
Electrical Engineering and will speak about the model-based approaches
used in medical image analysis.
He will overview some of the recent work in his laboratory that is
representative of the variety of ideas and efforts being pursued in the
field of medical image analysis. The presentation will include a discussion
of algorithm development in the areas of: deformable models for
segmentation of anatomical structure, rigid and nonrigid image
registration, approaches for structural and functional quantitative
analysis, and physical/biomechanical modeling in image analysis. Some of
the application areas for these approaches that will be overviewed include:
the analysis of neuroanatomical structure, the study of the deformation of
the left ventricle of the heart and image-guided intervention in
neurosurgery and radiotherapy.
Douglas L. Rothman, Ph.D.
In vivo Magnetic Resonance Spectroscopy Studies
of the Glutamate and GABA Neurotransmitter Cycles
and Functional Neuroenergetics
Wed, Mar 14, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine.
Dr. Rothman is an Associate Professor in the Department of Diagnostic
Radiology and the Director of Magnetic Resonance Center for Research
in Metabolism and Physiology.
Recent developments in magnetic resonance spectroscopy ( MRS ) have
wllowed the study neuronal glutamate and GABA metabolism and the
relationship of amino acid metabolism to functional neuroenergetics. The
brain pools of GABA, glutamate, and glutamine have been shown to be
localized within glutamatergic neurons, GABAergic neurons, and glia
respectively (under non pathological conditions). Under non fasting
conditions glucose is the almost exclusive source of energy for the
brain. By following the flow of 13C label from glucose into these
metabolites MRS has been used to determine the separate rates of
glucose oxidation in these cell types. The metabolism of glutamatergic
neurons, GABAergic neurons and glia are coupled by neurotransmitter
cycles. In the glutamate/glutamine cycle, glutamate released from nerve
terminals (by either vesicular release or transport reversal) is
transported into surrounding glial cells , and converted to glutamine.
Glutamine in then transported out of the glia and transported in to
the neurons, where it is converted back to glutamate thereby completing
the cycle By following the flow of 13C label from glutamate into
glutamine the rate of the glutamate/glutamine cycle may be determined
using MRS. Through a similar strategy the GABA/glutamine cycle may be
measured.
The application of MRS to study brain glutamate and GABA metabolism,
and the coupling of neurotransmitter cycling to neuroenergetics , has
provided several new, and controversial, insights into the relationship
of brain metabolism and function. Contrary to the previous view of a
separate metabolic and neurotransmitter pool of glutamate, glutamate
release and recycling has been shown to be a major metabolic pathway.
MRS studies of GABA metabolism in the rodent and human brain have
suggested that there is also an important role of the metabolic pool of
GABA in inhibitory function. Another key finding is that the
glutamate/glutamine cycle in the cerebral cortex is coupled in a close
to 1:1 ratio to neuronal (primarily glutamatergic) glucose oxidation
above isoelectricity. This finding in combination with cellular studies
has led to a model for the coupling between functional neuroenergetics
and glutamate neurotransmission. The coupling between neurotransmission
and neuroenergetics provides a linkage between the functional imaging
signal and specific neuronal processes.
George I. Zubal
Nuclear Medicine Imaging of Human Brain Function
Wed, Mar 28, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine
Dr. Zubal is an Associate Professor in the Department of Diagnostic
Radiology and hold numerous other appointments throughout the
medical school; Chair of the Radioactive Drug Research Committee,
Chair of the Radiation Safety Committee, Director of the SPECT
Epilepsy Group, Senior Physicist in the NeuroSPECT Imaging Center.
Nuclear Medicine utilizes trace amounts of radioactive materials
bound to metabolitically active molecules, which transport the radioisotope
through functional pathways in the human organs. We can image these
isotopes (using SPECT or PET) to create 3-dimensional representations
of the organs' normal activity and/or its states of disease. This
information
is combined with the anatomy obtained from CT for MRI scans. The
pharmacokinetics of the radiotracer 99m-Tc-HMPAO allow it to be used to
image the brain blood flow at the time of injection. In epilepsy, we use
SPECT for obtaining brain images immediately after the onset of a seizure.
By registering the seizure and non-seizure SPECT data and applying a
normalization and subtraction, we calculate a functional image is calculated
demonstrating describing changes in brain perfusion at the time of the
seizure.
Using the radiotracer 18-FDG, the metabolism in the patient's brain
can be measured using PET techniques. We apply image processing
techniques to interictal PET and SPECT brain images to further aid in the
localization of epileptogenic foci by calculating a functional image which
represents the degree of un-coupling between perfusion and metabolism.
Un-coupling of these two functions is characteristices of epileptogenic
tissue
in temporal lobe epilepsy and has the potential to serve as a diagnostic
measure for localization in other areas as well. Similar to the SPECT
perfusion analysis above, PET metabolism and perfusion images are
spatially registered in three dimensions and a functional ratio-image is
computed. These functional maps are overlayed onto a 3D rendering of
the same patient's MRI anatomy. Such noninvasive imaging techniques
help to minimize surgical intervention during the work-up and ultimate
resection of tissue in curing epilepsy patients.
R. Todd Constable
Rapid imaging in the Presence of
Magnetic Field Inhomogeneities:
Problems and Solutions impacting
Functional MRI
Wed, Apr 4, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine
Dr. Constable is an Associate Professor in the Departments of
Diagnostic Radiology and Neurosurgery. He runs an active research
program in the development of new MR imaging methods with
applications to functional MR imaging of the brain and the heart.
Rapid imaging has many benefits the most important of which is the
ability to rapidly produce images with intensities that reflect changes
in local tissue blood oxygenation. The contrast mechanism exploited
in most fMRI applications is the BOLD effect (Blood Oxygen Level
Dependent contrast) wherein the image intensity in a gradient echo
image is made sensitive to local changes in magnetic susceptibility
which occur as diamagnetic oxygenated blood replaces paramagnetic
deoxygenated blood upon tissue activation.
Rapid imaging allows either time-course studies of brain activation to
be obtained (the so called event-related fMRI studies) or it allows the
collection of many samples within a block design paradigm in order to
produce robust statistical maps reflecting brain activation. The
combination of rapid imaging and the need for sensitivity to local
susceptibility effects (BOLD contrast) unfortunately also makes these
sequences highly sensitive to static field inhomogeneities. The problems
these field inhomogeneities cause and possible solutions to these
problems will be discusssed, and specific examples of these issues in
fMRI experiments described.
Steven W. Zucker
Computer Vision and Primate Vision
Wed, Apr 18, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine
Dr. Steven W. Zucker is the David and Lucile Packard Professor
of Computer Science and Electrical Engineering at Yale University.
Before moving to Yale in 1996, he was Professor of Electrical
Engineering at McGill University, Director of the Program in Artificial
Intelligence and Robotics of the Canadian Institute for Advanced
Research, and the Co-Director of the Computer Vision and Robotics
Laboratory in the McGill Research Center for Intelligent Machines.
He was elected a Fellow of the Canadian Institute for Advanced
Research, a Fellow of the IEEE, and (by) Fellow of Churchill College,
Cambridge.
We consider the analysis of visual information by brains and by
computers. A theory of computational vision, from edge detection to
shape recognition, is sketched. The theory is geometrical, and at
the early level is realized by interpreting edge elements as signaling
a local approximation to tangents. These tangents are then grouped
into global curves, which are classified by the Whitney theorem, and
which support a description of shape as the singularities of a
curve-evolution equation. A biologically-relevant theory of stereo
reconstruction for space curves emerges from this formulation, which
could be relevant for diagnostic applications. Other applications in
computational neuroscience will be included.
Hal Blumenfeld
Network Inhibition Hypothesis for Loss of
Consciousness During Seizures
Wed, May 2, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine
Dr. Blumenfeld is an
Assistant Professor of Neurology and Neurobiology at
Yale University School of Medicine
Epileptic seizures serve as a useful model system for exploring
the difficult question of how consciousness occurs and is impaired
through alterations in neuronal activity. Some epileptic seizures
cause loss of consciousness, while others do not, allowing questions
to be asked about the anatomical regions and physiological activity
patterns that are important for consciousness. We have found through
a convergence of data from functional neuroimaging and electrophysiological
studies in both animal and human models that specific neuronal networks
are disrupted during certain epileptic seizures, involving fronto-parietal
association cortex, medial thalamus, and the pontomesencephalic reticular
formation. These findings may have important functional consequences for
both the behavioral manifestations of seizures, and normal brain function.
Anna W. Roe
Optical imaging and electrophysiological studies
of sensory cortical function
Wed, May 9, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine
Dr. Anna W. Roe is an assistant professor in the Section of
Neurobiology at Yale University. Her graduate work was done
at M.I.T. and postdoctoral studies at the Rockefeller University
and Baylor College of Medicine
In the cerebral cortex, each sensory modality (vision, audition,
somatosensation) is represented in multiple cortical areas (e.g.
over 30 visual areas). We would like to know why so many areas
are required for the computation that allows us to see, hear, and
touch. What does one area do that another does not? How do
they work together? Previous studies have focussed on
understanding the role of single cortical areas. The goal of our
research is to understand how multiple areas work cooperatively
at the scale of single functional domains (e.g. 50um scale). We
are now examining the concurrent activation of pairs of closely
related cortical areas during the processing of : 1) visual contours
in visual areas V1 and V2, and 2) visual brightness in visual areas
V1 and V2, and 3) tactile information in primary somatosensory
cortex (Areas 3b and 1). In an effort to relate such cortical
activations with behavior, we have developed a chronic optical
chamber method that permits long-term study of cortical function
in the awake, behaving animal. These studies have shown that
each cortical area provides a specific (and uniquely abstracted)
view of the visual world, each of which by itself is insufficient, but
when considered together provides unique identification.
Lawrence B. Cohen
Voltage and Calcium imaging of brain activity
Wed, May 23, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine
Dr. Lawrence B. Cohen is a professor in Physiology at Yale University.
Optical measurements of brain activity can be divided into two types;
measurements of intrinsic optical properties (intrinsic imaging) and
measurements using extraneously added probes (of membrane potential
or calcium concentration). This talk will focus on measurements of the
second type.
These optical measurements have certain attractive features as well as
certain severe limitations. Among the attractive features are the speed
of the signal and the clear relationship to brain activity. Among the severe
limitations are their invasiveness and the difficulty in measuring activity
from structures deeper than 500-1000 microns from the surface.
Calcium imaging. A number of dyes are available whose absorption or
fluorescence are sensitive to the concentration of calcium. Because
calcium influx into a neuron is a frequent correlate of activity as well
as an important regulator of the consequences of activity, measurement
of the intracellular calcium concentration is a relatively direct
measure of activity. We have used calcium signals to measure the input
to the olfactory bulb in response to application of odorants to the
nose.
Voltage-imaging. A different class of dyes have optical signals that
follow membrane potential. We have used these dyes to follow the
oscillations that occur in the olfactory bulb following application of
odorants to the nose.
Robert G. Shulman
The Glycogen Shunt in Brain and Muscle
Wed, May 30, 4 PM
Brady Auditorium (B 131)
Cedar Street
Yale University School of Medicine
Dr. Robert G. Shulman is the Sterling professor in MB&B
at Yale University.
It is becoming clear that the tradtional picture of lactate generation,
which depends upon a scarcity of oxygen, has no experimental
support. In muscle it is well known that blood is far from depleted of
oxygen when lactate is generated. In the brain the very existence of the
BOLD functional imaging signal reflects an excess of oxygen during
stimulation, rather than a depletion, and yet it is under these condtions
that lactate is generated.
The explanation proposed then of lactate generation during stimulation
is that in order to supply the power (time rate of energy consumption)
needed during the millisecond neuronal stimulations in muscle and brain,
glycogen is mobilized, via the activation of the fast enzyne, glycogen
phosphorylase, the so callled fight or flight enzyme. This generaes more
lactate than is needed by the slower oxidatiove processes so that the
lactate concentration builds up and thereby stimulates the efflux. Lactate
so generated need not be wasted, but as Brooks had shown can be
transported to another site where it can be used efficiently. Hence
lactate is not a sign of energy mismatch but of the temporal lack of
synchrony between the millisecond needs for energy and the slower
steady state supply. It is a time buffer.
October 2003