Breast cancers are typically Stage-1 (<2cm) at presentation, which limits the use of common functional imaging modalities in the work-up of early breast cancer because of limited spatial resolution. At the University of Washington (UW), positron emission tomography (PET) has been used with success as a biomarker to provide prognostic information about and evaluate therapy in locally advanced breast cancers. Our long-term goal in this project is to expand the use of PET as a biomarker for treatment response in breast cancer. This will more specifically direct therapy selection, resulting in improved outcomes and preventing cost and side effects associated with ineffective therapy. High resolution quantitatively accurate PET will be integrated with clinical mammography or tomosynthesis and biopsy-guidance methods to achieve this goal.
The aims of this project are: (1) design a PET detector unit using monolithic scintillation crystals coupled to Geiger-mode silicon photo-multipliers; (2) build and test a fully tomographic PET scanner that mates to a conventional mammography/tomosynthesis gantry for combined PET and x-ray imaging within the mammography suite; (3) integrate the PET scanner with clinical mammography or tomosynthesis equipment and biopsy guidance; (4) characterize the prototype and test it with pilot patient studies. This will be a collaboration between the UW and the GE Global Research Center. Using monolithic crystal detector methodologies developed at UW, the basic detector development will be lead by GRC with close involvement of UW co-investigators; GRC team will also lead systems integration onto mammography equipment; the overall system performance and clinical implementation will be spearheaded at the UW. The result of this work will be a dedicated breast PET system that operates in a mammography suite; initially used to expand therapy evaluation trials currently underway for advanced breast cancer using clinical PET. The device will enable investigation of using PET as a biomarker in early stage disease, including the use of diverse PET tracers available from the UW Radiochemistry cyclotron. It will be a prototype for a commercial-ready design that can be replicated for deployment at other institutions. The proposed system will provide a clinical tool to effectively investigate possible uses of PET to fight early-stage breast cancer.
Positron emission tomography (PET) can be used for evaluating early response to breast cancer treatments and may allow individualized, optimized therapy selection, including avoiding the costs and side effects of administering treatments that turn out to be ineffective. However, current PET scanners cannot accurately measure response in early-stage breast cancer that is by far most prevalent at diagnosis. This project will develop combined PET-mammogram-biopsy system capable of therapy response measurements (PET) correlated with conventional breast cancer imaging (mammography) and biopsy guidance to confirm results in early stage disease, thus enabling optimization of current therapy agents, and evaluation of new drugs and therapies.
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| Zeng, Chengeng; Kinahan, Paul E; Qian, Hua et al. (2017) Simulation study of quantitative precision of the PET/X dedicated breast PET scanner. J Med Imaging (Bellingham) 4:045502 |
| Morrocchi, M; Hunter, W C J; Del Guerra, A et al. (2016) Evaluation of event position reconstruction in monolithic crystals that are optically coupled. Phys Med Biol 61:8298-8320 |
| Pierce, L A; Hunter, W C J; Haynor, D R et al. (2014) Multiplexing strategies for monolithic crystal PET detector modules. Phys Med Biol 59:5347-60 |
| MacDonald, Lawrence R; Hunter, William C J; Kinahan, Paul E et al. (2013) Effects of Detector Thickness on Geometric Sensitivity and Event Positioning Errors in the Rectangular PET/X Scanner. IEEE Trans Nucl Sci 60:3242-3252 |
