Abstract

SPECT myocardial perfusion imaging provides critical information concerning the severity and functional significance of coronary artery disease (CAD). It has now been demonstrated that correction for attenuation, scatter, and spatial resolution significantly improves the diagnostic accuracy of perfusion SPECT imaging. The goal of the research of this proposal is to further improve the detection accuracy of SPECT for CAD through perfecting the transmission imaging strategy used in the estimation of patient-specific attenuation maps, and developing compensation strategies for respiratory motion of the heart and surrounding structures, the presence of significant extra-cardiac activity close to the heart, and partial volume effect caused differences in apparent maximal wall counts. The investigations will be carried out by a mixture of simulation, phantom, and clinical studies. The first specific aim is to develop the next-generation of transmission imaging which consists of cone-beam transmission imaging of point-sources whose highenergy photons penetrate through parallel-hole collimators as an accurate, practical, and robust alternative to present commercial transmission-imaging geometries for the estimation of attenuation maps for use specifically with cardiac imaging. Tasks to be accomplished include the optimization of point source shielding, number, geometry of placement, extent of axial and angular coverage, and modeling of the physics of transmission imaging in the reconstruction algorithm. The second specific aim is to develop a compensation strategy which will significantly reduce limitations to cardiac-wall visibility and apparent nonuniformity of perfusion caused by respiratory motion. Correction of respiratory motion both in emission and transmission imaging will be explored. The third specific aim is to investigate methods to diminish the interference of extra-cardiac activity with myocardial wall visibility and appearance of perfusion defects. The fourth specific aim is to formulate a correction method for the impact of the partial volume effect on the apparent uniformity of myocardial counts. The proposed method will assume that high spatial-resolution cardiac anatomy is available from a second imaging modality. The fifth specific aim is to investigate with clinical ROC studies the impact on the accuracy of CAD detection of the above compensation strategies. The use of normal clinical acquisitions to which defects are inserted mathematically (hybrid images) will be investigated as an alternative to the collection of clinical studies with """"""""known"""""""" truth as to the presence of CAD for ROC comparisons of detection accuracy.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL050349-13
Application #
7238628
Study Section
Diagnostic Imaging Study Section (DMG)
Program Officer
Buxton, Denis B
Project Start
1995-01-01
Project End
2009-06-30
Budget Start
2007-07-01
Budget End
2009-06-30
Support Year
13
Fiscal Year
2007
Total Cost
$385,198
Indirect Cost

  Institution

Name
University of Massachusetts Medical School Worcester
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
603847393
City
Worcester
State
MA
Country
United States
Zip Code
01655

  Publications

Pretorius, P Hendrik; King, Michael A (2009) Diminishing the impact of the partial volume effect in cardiac SPECT perfusion imaging. Med Phys 36:105-15
Dey, Joyoni; Pan, Tinsu; Choi, David J et al. (2009) Estimation of Cardiac Respiratory-Motion by Semi-Automatic Segmentation and Registration of Non-Contrast-Enhanced 4D-CT Cardiac Datasets. IEEE Trans Nucl Sci 56:3662-3671
Pretorius, P Hendrik; King, Michael A (2008) Spillover Compensation in the Presence of Respiratory Motion Embedded in SPECT Perfusion Data. IEEE Trans Nucl Sci 55:537-542
Feng, Bing; Gifford, Howard C; Beach, Richard D et al. (2006) Use of three-dimensional Gaussian interpolation in the projector/backprojector pair of iterative reconstruction for compensation of known rigid-body motion in SPECT. IEEE Trans Med Imaging 25:838-44
Feng, Bing; Pretorius, P Hendrik; Farncombe, Troy H et al. (2006) Simultaneous assessment of cardiac perfusion and function using 5-dimensional imaging with Tc-99m teboroxime. J Nucl Cardiol 13:354-61
Feng, B; Bruyant, P P; Pretorius, P H et al. (2006) Estimation of the Rigid-Body Motion from Three-Dimensional Images Using a Generalized Center-of-Mass Points Approach. IEEE Trans Nucl Sci 53:2712-2718
Feng, Bing; Fessler, Jeffrey A; King, Michael A (2006) Incorporation of system resolution compensation (RC) in the ordered-subset transmission (OSTR) algorithm for transmission imaging in SPECT. IEEE Trans Med Imaging 25:941-9
Soares, Edward J; Glick, Stephen J; Hoppin, John W (2005) Noise characterization of block-iterative reconstruction algorithms: II. Monte Carlo simulations. IEEE Trans Med Imaging 24:112-21
Pretorius, P Hendrik; King, Michael A; Gifford, Howard C et al. (2005) Myocardial perfusion SPECT reconstruction: receiver operating characteristic comparison of CAD detection accuracy of filtered backprojection reconstruction with all of the clinical imaging information available to readers and solely stress slices iterativ J Nucl Cardiol 12:284-93
Narayanan, Manoj V; King, Michael A; Pretorius, P Hendrik et al. (2003) Human-observer receiver-operating-characteristic evaluation of attenuation, scatter, and resolution compensation strategies for (99m)Tc myocardial perfusion imaging. J Nucl Med 44:1725-34

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