News
SNM Press Releases
May 1, 2009
SNM Cardiovascular Symposium Focuses on Benefits of Imaging Modalities
Symposium on Multimodality Cardiovascular Molecular Imaging Shifts Emphasis from Treatment to Prevention of Heart Damage
The SNM Symposium on Multimodality Cardiovascular Molecular Imaging convened for a second day on Friday, May 1, at the National Institutes of Health (NIH) in Bethesda, Md. The meeting—hosted by SNM's Molecular Imaging Center of Excellence (MICoE) with the support of NIH and of multiple corporate and nonprofit partners—probed the prevention of cardiac events as a critical next step toward improving cardiovascular health and patient care.
"The symposium was designed to help disseminate the latest cardiovascular imaging research and raise awareness of the most promising clinical techniques with the potential to decrease the frequency and mitigate the severity of heart attacks and other cardiac events," said MICoE president Henry F. VanBrocklin, Ph.D., professor of radiology and director of radiopharmaceutical research at the University of California, San Francisco.
Cardiologists Highlight Advances in Targeted Imaging of the Cardiovascular System
Building on the foundation laid the previous day, speakers from the fields of chemistry, engineering, physics, molecular biology, cardiovascular physiology and imaging sciences focused on important lessons that can be gleaned from imaging damaged heart tissue in hopes of diagnosing potential cardiac events—and preventing them before they occur.
"Changes in the structure, geometry and—eventually—function of the left ventricle occur following myocardial infarction, or heart attack," said Albert J. Sinusas, M.D., professor of medicine and diagnostic radiology and director of cardiovascular nuclear imaging, Yale School of Medicine. "A targeted molecular imaging approach can provide both prognostic and diagnostic potential by revealing unique insights into molecular processes involved in repair and remodeling of the heart following a heart attack."
During the symposium, speakers presented research about new imaging and drug delivery technologies that are currently being developed to counter the effects of atherosclerosis, or chronic inflammation of the heart's arterial walls. According to these researchers, cardiovascular disease is the leading cause of mortality and morbidity in developed countries—and atherosclerosis is a major cause of severe cardiovascular disease.
"One third of adult men and women have some form of cardiovascular disease—and the estimated direct and indirect costs to our health care system exceed $400 billion," said David K. Glover, Ph.D., associate professor of cardiovascular medicine, University of Virginia School of Medicine. "We are currently investigating an antibody-based molecular imaging probe that may be a useful and sensitive tool for advancing our understanding of the formation of atherosclerotic lesions and for the noninvasive detection of vulnerable plaques."
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| Rob Beanlands, MD, discusses FDG PET utilization in cardiac imaging. |
Other presentations explored both the established and the leading edge in imaging techniques—from positron emission tomography (PET) and magnetic resonance (MR) to a variety of hybrid imaging modalities in biomedicine, including applications of ultrasonics for medicine and nondestructive testing.
"Metabolic imaging has played a key role in diagnosis and prognostication as well as directing therapy and understanding these disease states and new therapies," said Rob S. B. Beanlands, M.D., director of the University of Ottawa Heart Institute's cardiac PET center. "A recent comprehensive meta-analysis confirmed that FDG PET is the most sensitive method available for predicting heart wall motion recovery and revealing improved outcomes in the healthy heart wall tissue of patients whose blood supply has been restored."
"Photoacoustic imaging represents one of the most promising techniques for molecular imaging," said Matthew O'Donnell, Ph.D., the Frank and Julie Jungers Dean of Engineering, professor of bioengineering and adjunct professor of mechanical engineering, College of Engineering at the University of Washington. "Photoacoustics combines optical and acoustic methods and can provide real-time images with molecular sensitivity at significant image depth with high spatial resolution."
