Unsolved Problems and Unmet Needs in Magnetic Resonance - PowerPoint PPT Presentation

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Unsolved Problems and Unmet Needs in Magnetic Resonance

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Title: Unsolved Problems and Unmet Needs in Magnetic Resonance


1
Unsolved Problems and Unmet Needs in Magnetic
Resonance
  • Morning Categorical Course
  • ISMRM 14th Scientific Meeting Exhibition
  • Seattle, WA, USA
  • May 9-12, 2005

2
Why a course on UNsolved problems?
  • At the annual ISMRM meeting and in many of our
    professional interactions, we tend to focus on
    what we or others have recently accomplished in
    our areas of interest, or else we speculate
    together on current trends and promising future
    directions in MR research and practice.

3
Why a course on UNsolved problems?
  • In the midst of all this lively and topical
    activity, the less satisfying questions of what
    we cannot but would very much like to achieve
    with MR receive little concentrated, collective
    attention.

4
Why a course on UNsolved problems?
  • Discussions of unmet needs and research
    priorities are often left to funding
    organizations, which publish periodic requests
    for proposals and roadmaps to which many of us
    as researchers are encouraged to respond. 
  • The process of assessing needs and formulating
    priorities, however, could very well benefit from
    broader participation by our MR community at
    large. 

5
Overview
  • The morning sessions on Unsolved Problems and
    Unmet Needs in MR are intended to bring new
    attention to such questions.
  • Over the course of the next four days, the top
    ten reviewed submissions from a prior call for
    abstracts on key problems and needs will be
    presented.
  • The sessions will also include substantial time
    for open discussion, in order to promote
    interactions and to foster innovation.

6
Educational objectives
  • Upon completion of this session, participants
    should be able to
  • Identify and assess a sampling of key unsolved
    problems and unmet needs in the field of magnetic
    resonance
  • Establish criteria for successful solutions to
    such problems
  • Consider any large-scale coordination across our
    field or with other fields that may be called for
    to address some classes of research or clinical
    needs
  • Identify and share additional unsolved problems
    or unmet needs in your areas of interest.

7
Broader objectivesThe ISMRM Strategic Plan
  • Vision The ISMRM aspires to be the premier
    international society working to promote
    innovation, development, implementation, and
    communication of magnetic resonance science in
    medicine and other related fields.

8
Broader objectives
  • Foster conversation (Strategic plan, goal 1)
  • Foster collaboration (Strategic plan, goal 1)
  • Foster innovation (Strategic plan, goal 1)
  • Promote interactions between our
    clincially-focused and our research-focused
    members (goal 1)
  • Educate new entrants into our field (goal 2)
  • Develop a shared sense of collective targets for
    research (goals 1,5,6)
  • Play an active role in informing funding
    organizations by highlighting important
    directions (goals 1,5,6)

9
Precedents in other fields
  • Mathematics
  • Millennium Prize Problems, Clay Mathematics
    Institute
  • (http//www.claymath.org/millennium)
  • Multiple individual lists of unsolved problems
    Hilbert, Croft, et al
  • Physics, Astronomy
  • Decadal Survey of Physics
  • Decadal Survey of Astronomy and Astrophysics
  • (http//www7.nationalacademies.org/bpa/)
  • Medicine
  • The NIH Roadmap
  • Others
  • The National Academies Keck Futures Initiative
    Conferences(http//www.keckfutures.org)
  • Intellectual Ventures, Nathan Myhrvold et al
    (http//www.intellectualventures.com)

10
What do we mean by unsolved problems and unmet
needs?
  • If only I had X, then I could diagnose / monitor
    / treat Y
  • If only I could measure / build / control Z,
    then I could accomplish X
  • What is the true mechanism underlying Q?

11
What do you mean by unsolved problems and unmet
needs?
  • Survey of ISMRM Study Groups returned nearly 100
    items representing 7 Study Groups

12
MR Engineering
  1. Wireless or optical transmission of the MR signal
    out of the bore, to facilitate the use of large
    receiver coil arrays.
  2. What number of channels is optimal/required for
    both receive (Parallel Imaging) and transmit
    (Transmit SENSE)
  3. SAR how to control SAR at high fields (gt 3T),
    how to know where the hot spots are in vivo, how
    to monitor the SAR in the human body in real
    time.
  4. Length of magnet/bore how short can it be? What
    are the limits in openness?
  5. Actively shielded gt 7 T whole body magnets.
  6. Dynamic shimming development of shim coils that
    can be used in dynamic shimming (strong, low
    inductance, actively shielded) and quantification
    of the advantages to be gained via dynamic
    shimming.
  7. Reduction of acoustic noise to due switched
    magnetic field gradients, especially at high
    field.
  8. Methods for imaging without the use of pulsed
    field gradients.
  9. Methods for Precise QA of the MRI scanner in
    terms of SNR/ stability/ distortion/ artifacts
    and differences between MR methods. Currently,
    the lack of such methods limit the pooled use of
    MR data generated from different
    scanners/vendors.
  10. Practical methods for measuring the electrical
    properties of tissues using MRI.
  11. Methods for increasing patient throughput - can
    we produce an order-of-magnitude improvement in
    any way (parallel imaging, higher field, dockable
    tables, etc.) in the time needed to image
    (leading to a reduction in scanning costs).
  12. A discussion board to draw an active group of
    engineers together for dissemination of knowledge
    and experience, rather than retainment in
    individual labs.

13
High-Field
  1. Solutions for the transmit B1 inhomogeneity at
    high field due to wavelength/dielectric effects.
  2. Development of standardized method for SAR
    monitoring and setting SAR limits for multiple
    local transmit coils.
  3. Development of transmit SENSE at ultra-high
    field, along with development of algorithms for
    determining the phase and amplitude of the RF for
    each driven element in a coil, such as a TEM
    coil.
  4. Acoustic noise reduction at high field.
  5. Low noise, high fidelity, and powerful gradient
    amplifiers.
  6. Development of an actively shielded 7 T
    whole-body sized magnet.
  7. Fast CSI pulse sequences.
  8. Pulse sequences for clinical applications of
    hetero-nucleus imaging (such as 3Li, 31P, 17O,
    etc.)
  9. Detection of molecular probes that can pass
    through the blood-brain barrier and selectively
    bind to specific cells or tissues.
  10. A method for identifying areal boundaries via
    high resolution MRI (to allow definition of
    functional areas on individual subjects).
  11. Long-term health consequences of exposure to very
    high magnetic field.
  12. Methods to remove magnetic susceptibility-induced
    image distortion.

14
Diffusion/Perfusion
  1. Definitively quantify the contributions of the
    intra- and extra-cellular components to the
    diffusion signal
  2. Measure brain perfusion in acute stroke patients
    accurately enough to be useful Score 27
    Number of votes 7
  3. Have realistic phantoms for diffusion imaging
    Score 26 Number of votes 11
  4. Quantify connectivity between different regions,
    separated by different distances, reliably and
    consistently Score 25 Number of votes 8
  5. Have an accepted and practical gold standard for
    tract tracing in the human brain Score 23
    Number of votes 7
  6. Reliably measure the vascular territories of
    individual arteries Score 21 Number of votes
    6
  7. Better understand the biophysical nature of
    diffusion MR signal, in order to optimize
    diffusion experiments more effectively Score
    20 Number of votes 4
  8. Have a definitive, reproducible and easy way of
    calibrating ASL experiments with respect to M0
    (of tissue or blood, depending on the model) in
    order to get quantitative CBF values Score
    18 Number of votes 4
  9. Use diffusion-derived measures, other than the
    mean diffusivity, in a clinical manner Score
    16 Number of votes 5
  10. Have standard post-processing software
    (including motion correction) for ASL integrated
    onto a clinical scanner Score 16 Number of
    votes 5
  11. Perform meaningful group comparisons on low
    dimensionality diffusion data (scalar invariants
    of the tensor), even if we dont understand the
    biophysical mechanisms underlying them /
    Perform meaningful voxel-based comparisons of
    DTI data Score 16 Number of votes 4
  12. Reliably quantify the dependence of diffusion on
    diffusion time, to identify different tissue
    types or geometrical features Score 15
    Number of votes 5
  13. Have realistic phantoms for perfusion imaging
    Score 15 Number of votes 5
  14. Use DTI to reliably discriminate tumor
    infiltration from bland (tumorfree) edema Score
    14 Number of votes 5
  15. Use arterial spin labeling to measure perfusion
    in white matter Score 14 Number of votes
    3
  16. "Establish the definitive biophysical mechanism
    underlying the dependence of ADC on the b-value
    in the brain". Score 12 Number of votes 4
  17. Resolve the topological ambiguity in diffusion
    displacement profiles (cross, kiss, twist, bend)
    Score 11 Number of votes 4
  18. Reach a common consensus, once and for all, on
    the number of directions needed for DTI, and the
    b-values needed (i.e., do we need b lt 600 s/mm2
    or bgt 3000 s/mm2) Score 11 Number of votes
    4
  19. Identify the cellular correlates of changes in
    diffusion anisotropy in white matter Score
    11 Number of votes 5

15
MSK
  1. Applications of Parallel Imaging in MSK MRI
  2. New coils for 3T and 7T phased array, small
    coils
  3. Kinematic and loaded imaging of joints and spine
  4. Novel sequences to image cartilage including SSFP
    and uTE
  5. Automated segmentation and parameter mapping
    software (morphology, T1, T2, T1rho)
  6. Spectroscopy for MSK MRI - muscle, spine,
    cartilage (1H, 31P, Na)
  7. Fat saturation for low field - robust Dixon
    imaging
  8. New hardware gradient inserts and dedicated
    extremity 3T systems
  9. Fast T1 and T1rho mapping sequences
  10. DWI and DTI imaging for muscle and nerves
  11. Marrow Imaging

16
Flow and Motion
  1. How to achieve robust, accurate,
    high-temporal-and-spatial-resolution flow
    measurements in, for example, the right and
    circumflex coronary arteries, which move a lot.
  2. We need a well-defined, complex flow phantom for
    comparison/calibration of scanners.
  3. How to have first-time, every-time measurements
    of flow with likely errors less than 10 in
    PATIENTS in vessels down to 5mm diameter?
  4. What consistutes a clinical report of an MR flow
    study? an MR cardiac motion study?
  5. When will MR velocimetry match ultrasound?
  6. Spiral, EPI, segmented gradient echo, FVI, etc,
    etc, etc, do we have the right tools for every
    situation? and do we really need them all in
    clinic and in research settings?
  7. Limits of temporal, spatial and velocity
    resolution - how low and how high can we go (in
    flow and tagging)?
  8. How well does phase mapping work with accelerated
    imaging techniques?
  9. How do I know if a flow study was done well?
  10. 4D velocity mapping - how fast? how good?

17
Dynamic MR
  • A hand-held MRI scanner. The NMR mouse exists and
    is capable of measuring spectra at very small
    depths. However, for hand held medical imaging we
    would need to a. Create a reasonably homogeneous
    B0 field penetrating the body to organ depth.b.
    Overcome B0 field inhomogeneities.c. Create
    reasonably linear B0 gradientsd. Compensate for
    the residual non-linearity of the gradients.e.
    Have MRI sequences with only adiabatic pulsesf.
    Have enough B1 penetration for the adiabatic
    pulse without exceeding SAR limits.
  • Create The mother of all sequences (so named by
    Paul Bottomley), a truly high resolution 3D pulse
    sequence that in a reasonably short scan time
    measures spin density, T1 and T2. Then use this
    information to generate any slice at any oblique
    angle with any T1 or T2 weighted contrast. This
    would replace the series of scout images, oblique
    scouts, T1 and T2 weighted images that usually
    make examinations long.
  • Measure real time changes in spin density at a
    time scale shorter than T1. Example measure real
    time changes in phosphorous metabolites or in
    intracellular sodium in vivo in muscle or other
    excitable tissue.
  • Measure changes in T1 at a time scale shorter
    than T1.
  • How to distinguish between demyelination,
    inflammation and axonal loss?
  • Early diagnosis of Alzheimers (before occurrence
    of atrophy)
  • Increased specificity for diagnosis of Multiple
    Sclerosis in patient with WM lesions
  • Possibility to establish glioma grading with high
    confidelity
  • Expand the MRI capabilities for brain white
    matter to high resolution imaging of the spine
    columns
  • Diagnose White Matter Pathology Definitively
    using MRI.

White Matter
18
This years initiative Abstract review
  • Each abstract reviewed by at least 3 referees
    (AMPC members, with expertise chosen to match the
    abstract topics)
  • Abstracts graded separately from regular ISMRM
    abstracts, but on a similar point system
  • The ten top-rated submissions selected for oral
    presentation, and grouped into themes

19
This years initiative Topics over the week
  • Tue May 9 What are we missing? Seeing through
    metal and divining with RF coils
  • Wed May 10 Can MRI provide a noninvasive biopsy?
  • Thu May 11 Will new contrast agents
    revolutionize MRI?
  • Fri May 12 Do we need a virtual scanner, and do
    we understand real ones?

20
Tuesday
  • What are we missing?  Seeing through metal and
    divining with RF coils
  • Moderators Stuart Crozier, Michael Smith
  • 0700 Introduction Daniel K. Sodickson,
    M.D., Ph.D.
  • 0715 Techniques for MR Imaging Near
    Metallic Implants Garry E. Gold, M.D.
  • 0730 Prospects of Absolute B1 Calibration
    Florian Wiesinger, Ph.D.
  • 0745 Open Discussion

21
Wednesday
  • Can MRI provide a noninvasive biopsy?
  • Moderators Michael Moseley, John Detre
  • 0700 Cytoarchitectonic MRI  Can MRI Be
    Used to Quantify Neural Tissue? Itamar
    Ronen, Ph.D.
  • 0715 Tissue Structure through Diffusion and
    Transverse Relaxation Measurements Valerij
    G. Kiselev, Ph.D.
  • 0730 Unresolved Issues in Diffusion and
    Perfusion MRI  A Consensus from the Study
    Group Derek K. Jones, Ph.D.
  • 0745 Open Discussion

22
Thursday
  • Will new contrast agents revolutionize MRI?
  • Moderator Thomas Grist, Martin Prince
  • 0700 Exclusively MRI - Based Molecular
    Imaging  Can Magnetic Labeling of
    Physiologically Important Compounds via DNP or
    Parahydrogen-Induced Hyperpolarization Provide
    a Potential Supplement or Replacement of
    PET? Joachim Bargon, M.D.
  • 0715 Direct Detection of Neuromodulation
    Rachel Katz-Brull, Ph.D.
  • 0730 Development of Status Tracers for
    Myocardial Perfusion Imaging by MRI Timothy
    F. Christian, M.D.
  • 0745 Open Discussion

23
Friday
  • Do we need a virtual scanner, and do we
    understand real ones?
  • Moderators David Hoult, Richard Bowtell
  • 0700 Need for a Non-Commercial Open-Source MR
    Simulator Ralf B. Loeffler, Ph.D.
  • 0715 Does the Principle of Reciprocity Hold at
    High Field MR? Jinghua Wang, Ph.D.
  • 0730 Reciprocity at High Field Counterpoint
    David Hoult, Ph.D.
  • 0740 Open Discussion
  • 0755 Conclusion Daniel K. Sodickson, M.D.,
    Ph.D.

24
After the meeting
  • Results of this years call for abstracts and
    survey of Study Groups will be published on the
    ISMRM Web site
  • A web list of unsolved problems and unmet needs
    will be maintained and updated as a resources
  • Future possibilities workshop, challenge grants,
    etc
  • Your suggestions?
  • Gather your submissions for next year
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