Abstract

Positron emission tomography (PET) breast imaging can potentially improve the detection and diagnosis of cancer in women with radiodense and/or fibrocystic breasts. Additionally, the quantitative capabilities afforded by PET may also be exploited to provide early and accurate assessment of cancer treatment. During the last four years, our group, with the support of the National Institutes of Health, have developed a high-resolution positron emission mammography and tomography imaging and biopsy device (called PEM-PET) to detect and guide the biopsy of suspicious breast lesions, and quantify radionuclide concentrations in tissue. The system consists of two sets of rotating planar detector heads. Each detector head consists of a 4x3 array of Hamamatsu H8500 flat panel position sensitive photomultipliers (PSPMTs) coupled to a 96W72 array of 2W2W15mm3 LYSO detector elements (pitch= 2.1mm). Image reconstruction is performed with a 3D-OSEM algorithm optimized to run on an eight CPU computer system, significantly reducing image reconstruction times. Initial testing of the device is focusing yielded a spatial resolution at the center of the FOV of 1.87mm (radial), 1.84mm (tangential) and 1.67mm (axial);at 7cm from the center, the results were 1.9mm (radial), 1.89mm (tangential) and 1.69mm (axial). Total system detection sensitivity is 363.3kcps/microcurie/ml. In the continuing development of our breast imaging and biopsy system we propose the further optimization of the PET system;addressing some areas of weakness (count rate performance, for example) identified in our initial testing regime. We also propose the addition of a cone beam, x-ray computed tomography (CT) scanner to the current PEM-PET system, creating the PEM-PET-CT breast imaging and biopsy device. PEM-PET-CT will have the unique ability to continuously rotate during data acquisition, permitting the ability to rapidly produce PET and CT images. The anatomical information gained by integration of the CT imager will permit the correlation of structural features of the breast and abnormal areas with functional information from these areas. Thus, the two methods complement each other well. The data provided by the CT images will also be used improve corrections for physical phenomena that can confound quantitative measures of radiotracer concentrations. Finally, the completed system be tested in these two application during a pilot human trial, comparing its performance to whole body PET, MRI and MRS. The data from these studies will be crucial in the planning of future larger human trials. We envision that PEM-PET-CT could be used to detect lesions in women with dense breasts and indeterminate mammograms that have additional risks factors for cancer. It could also be used in the diagnostic role as a """"""""second look"""""""" method to assess suspicious lesions or micro- calcifications. Lastly, the unique quantitative capabilities of the system could facilitate its use in treatment assessment of chemotherapy, especially in small tumors. Thus, the development of this new multi-modality system is a unique opportunity to improve a number of important clinical aspects of breast care.

Public Health Relevance

This application proposes the continued development of a dedicated breast PET-CT system. This device could be instrumental in the detection, diagnosis and treatment assessment of breast cancer.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
2R01CA094196-05
Application #
7590070
Study Section
Special Emphasis Panel (ZRG1-SBIB-P (02))
Program Officer
Nordstrom, Robert J
Project Start
2001-12-01
Project End
2013-02-28
Budget Start
2009-05-20
Budget End
2010-02-28
Support Year
5
Fiscal Year
2009
Total Cost
$501,861
Indirect Cost

  Institution

Name
West Virginia University
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
191510239
City
Morgantown
State
WV
Country
United States
Zip Code
26506

  Publications

Raylman, Raymond R; Van Kampen, Will; Stolin, Alexander V et al. (2018) A dedicated breast-PET/CT scanner: Evaluation of basic performance characteristics. Med Phys 45:1603-1613
Stolin, Alexander V; Martone, Peter F; Jaliparthi, Gangadhar et al. (2017) Preclinical positron emission tomography scanner based on a monolithic annulus of scintillator: initial design study. J Med Imaging (Bellingham) 4:011007
Raylman, Raymond R; Stolin, Alexander V; Martone, Peter F et al. (2016) TandemPET- A High Resolution, Small Animal, Virtual Pinhole-Based PET Scanner: Initial Design Study. IEEE Trans Nucl Sci 63:75-83
Raylman, Raymond R; Vaigneur, Keith; Stolin, Alexander V et al. (2015) Arrays of Segmented, Tapered Light Guides for Use with Large, Planar Scintillation Detectors. IEEE Trans Nucl Sci 62:694-698
Stolin, Alexander V; Majewski, Stan; Jaliparthi, Gangadhar et al. (2013) Construction and Evaluation of a Prototype High Resolution, Silicon Photomultiplier-Based, Tandem Positron Emission Tomography System. IEEE Trans Nucl Sci 60:82-86
Raylman, Raymond R; Abraham, Jame; Hazard, Hannah et al. (2011) Initial clinical test of a breast-PET scanner. J Med Imaging Radiat Oncol 55:58-64
Champley, Kyle M; Raylman, Raymond R; Kinahan, Paul E (2010) Advancements to the planogram frequency-distance rebinning algorithm. Inverse Probl 26:45008
Champley, Kyle; Defrise, Michel; Clackdoyle, Rolf et al. (2008) Planogram rebinning with the frequency-distance relationship. IEEE Trans Med Imaging 27:925-33
Raylmana, Raymond R; Smith, Mark F; Kinahan, Paul E et al. (2008) Quantification of radiotracer uptake with a dedicated breast PET imaging system. Med Phys 35:4989-97
Raylman, Raymond R; Majewski, Stan; Smith, Mark F et al. (2008) The positron emission mammography/tomography breast imaging and biopsy system (PEM/PET): design, construction and phantom-based measurements. Phys Med Biol 53:637-53

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