This bioengineering research grant is responsive to PA-07-279 (reissue of PA-06-419). It is a collaboration between the University of Massachusetts Medical School and the Utah Center for Advanced Imaging Research at University of Utah. Superposition of breast structures in screen-film and digital mammography may result in missed cancers due to 'masking'effect, or may mimic the presence of a lesion resulting in additional imaging or biopsy. Dedicated breast Computed Tomographic (CT) imaging of the breast can overcome this superposition problem, and provide much improved contrast, thus improving lesion detectability. Further, breast CT can be performed at low radiation dose (equivalent to mammography) with no or minimal physical compression of the breast, alleviating patient discomfort. It can provide for 3-D lesion morphology, which could serve as a diagnostic indicator, and for better quantitative assessment of breast glandular content, a likely risk factor for breast cancer. This work is focused on design and optimization of a dedicated breast CT system. Specifically, the research plan is to address known challenges in breast CT, such as maximizing the inclusion of breast tissue within scan field, determining appropriate source-detector trajectory with consideration for data completeness and reconstruction complexity, and developing noise suppression schemes to improve microcalcification visibility. The research plan includes determining optimal patient position for maximizing breast tissue inclusion, implementation of several image acquisition trajectories and appropriate reconstruction algorithms, comprehensive mathematical simulation and optimization of critical system and reconstruction parameters. Complete characterization of the improvement achieved on a bench-top system will be performed through observer-independent physical metrics and through surgical mastectomy specimen-based observer studies. The results from this study will provide for an ergonomic design and optimized image acquisition and reconstruction technique that can be readily translated to a clinical imaging system. A well-designed dedicated breast CT system can serve as a platform technology for screening and diagnostic imaging, implant imaging, 3-D presurgical planning, monitoring preoperative treatment, and guidance in minimally invasive surgery. We believe our approach will have a major impact on the detection and management of breast cancer.

Public Health Relevance

Volumetric 3-D imaging with a dedicated breast CT system has the potential to be an effective tool to overcome the tissue superposition problem in mammography which results in missed cancers and unnecessary recall of the patient for additional imaging, and for monitoring the effectiveness of therapeutic treatments. However, there are known challenges such as maximizing breast tissue inclusion during the scan, visualization of microcalcifications due to image noise and loss of contrast, and cone- beam artifacts. In this research, we propose to develop methods to overcome these challenges and demonstrate the improved image quality obtained with such methods.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA128906-02
Application #
7907802
Study Section
Biomedical Imaging Technology Study Section (BMIT)
Program Officer
Tandon, Pushpa
Project Start
2009-08-06
Project End
2012-05-31
Budget Start
2010-06-01
Budget End
2011-05-31
Support Year
2
Fiscal Year
2010
Total Cost
$337,119
Indirect Cost
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
Vedantham, Srinivasan; Shi, Linxi; Karellas, Andrew (2014) Large-angle x-ray scatter in Talbot-Lau interferometry for breast imaging. Phys Med Biol 59:6387-400
O'Connell, Avice M; Karellas, Andrew; Vedantham, Srinivasan (2014) The potential role of dedicated 3D breast CT as a diagnostic tool: review and early clinical examples. Breast J 20:592-605
Vedantham, Srinivasan; Karellas, Andrew (2013) X-ray phase contrast imaging of the breast: analysis of tissue simulating materials. Med Phys 40:041906
Vedantham, Srinivasan; Shi, Linxi; Karellas, Andrew et al. (2013) Personalized estimates of radiation dose from dedicated breast CT in a diagnostic population and comparison with diagnostic mammography. Phys Med Biol 58:7921-36
Shi, Linxi; Vedantham, Srinivasan; Karellas, Andrew et al. (2013) Technical note: Skin thickness measurements using high-resolution flat-panel cone-beam dedicated breast CT. Med Phys 40:031913
van der Bom, I M J; Hou, S Y; Puri, A S et al. (2013) Reduction of coil mass artifacts in high-resolution flat detector conebeam CT of cerebral stent-assisted coiling. AJNR Am J Neuroradiol 34:2163-70
Vedantham, Srinivasan; Karellas, Andrew; Emmons, Margaret M et al. (2013) Dedicated breast CT: geometric design considerations to maximize posterior breast coverage. Phys Med Biol 58:4099-118
Vedantham, Srinivasan; Shi, Linxi; Glick, Stephen J et al. (2013) Scaling-law for the energy dependence of anatomic power spectrum in dedicated breast CT. Med Phys 40:011901
Vedantham, Srinivasan; Shi, Linxi; Karellas, Andrew et al. (2012) Dedicated breast CT: fibroglandular volume measurements in a diagnostic population. Med Phys 39:7317-28
Vedantham, Srinivasan; Shi, Linxi; Karellas, Andrew et al. (2012) Dedicated breast CT: radiation dose for circle-plus-line trajectory. Med Phys 39:1530-41

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