The objective of the project is to translate a phase-sensitive x-ray tomosynthesis technique to clinical practice to reduce radiation dose and improve accuracy in breast cancer diagnosis. The technique is based on the principle of inline phase-sensitive x-ray imaging operating at high energies of 120 to 150 kVp. We will build a patient imaging system and conduct preclinical evaluations and phase 1 clinical trial. As the result of more than 20 years of research, digital breast tomosynthesis (DBT) was recently approved by the FDA and introduced into clinical practice. The key advantage of DBT as compared with projection mammography is its 3D capability that effectively removes the superimposed breast parenchymal structures and improves the conspicuity and detection of breast cancer. However, there are two main limitations with DBT. The first regards its ability to detect subtle breast calcifications, and the second involves the higher radiation dose as compared with conventional mammography. It is therefore necessary to improve the sensitivity and specificity of DBT and reduce the radiation dose to patients. It has been shown that tissue- lesion contrast based on x-ray phase-shifts is greater than the corresponding attenuation contrast. In addition, while low x-ray energies must be used in conventional attenuation-based breast imaging, high x-ray energies can be used in phase-sensitive imaging to reduce the radiation dose. We therefore propose the integration of innovative phase-sensitive methods with DBT. The hypothesis of our proposal is that high energy phase-sensitive breast tomosynthesis (PBT) can greatly enhance tissue contrast and significantly reduce radiation dose as compared to current digital breast tomosynthesis (DBT). To test our hypotheses, we will (1) assemble a high energy (120-150 KV) x-ray phase- sensitive breast tomosynthesis system with a micro-focus tube source and a high-resolution flat panel detector; (2) optimize the phase retrieval algorithm and test it under clinical patient imaging conditions; (3) characterize the performance of the patient imaging system and its key components for system optimization, and compare the proposed system with DBT to determine radiation dose savings; (4) conduct subjective preclinical evaluations with cadaver and other phantoms to determine the optimal operating parameters for patient studies; (5) conduct a Phase 1 clinical evaluation and statistical analysis with 110 patients to compare phase- sensitive and conventional tomosynthesis systems. The proposed research will facilitate the translation of this innovative phase-sensitive breast tomosynthesis technique to clinical practice, and enhance the sensitivity and specificity of breast cancer detection while also reducing the radiation dose.

Public Health Relevance

The goal of this project is to translate a phase-sensitive x-ray tomosynthesis technique to clinical practice by developing a patient imaging system and conducting preclinical evaluations and a Phase 1 clinical trial. This novel approach to patient imaging has great potential to enhance the sensitivity and specificity of breast cancer screening and diagnosis, as well as reduce the radiation dose as compared with current digital breast tomosynthesis techniques.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
1R01CA193378-01
Application #
8860536
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Baker, Houston
Project Start
2015-04-01
Project End
2020-03-31
Budget Start
2015-04-01
Budget End
2016-03-31
Support Year
1
Fiscal Year
2015
Total Cost
Indirect Cost
Name
University of Oklahoma Norman
Department
Engineering (All Types)
Type
Biomed Engr/Col Engr/Engr Sta
DUNS #
848348348
City
Norman
State
OK
Country
United States
Zip Code
73019
Yan, Aimin; Wu, Xizeng; Liu, Hong (2018) Quantitative theory of X-ray interferometers based on dual phase grating: Fringe period and visibility. Opt Express 26:23142-23155
Ghani, Muhammad U; Wong, Molly D; Omoumi, Farid H et al. (2018) Detectability comparison of simulated tumors in digital breast tomosynthesis using high-energy X-ray inline phase sensitive and commercial imaging systems. Phys Med 47:34-41
Ren, Liqiang; Zheng, Bin; Liu, Hong (2018) Tutorial on X-ray photon counting detector characterization. J Xray Sci Technol 26:1-28
Wu, Di; Wong, Molly Donovan; Yang, Kai et al. (2018) Using Microbubble as Contrast Agent for High-Energy X-Ray In-line Phase Contrast Imaging: Demonstration and Comparison Study. IEEE Trans Biomed Eng 65:1117-1123
Ghani, Muhammad U; Wong, Molly D; Ren, Liqiang et al. (2017) Characterization of Continuous and Pulsed Emission modes of a Hybrid Micro Focus X-ray Source for Medical Imaging Applications. Nucl Instrum Methods Phys Res A 853:70-77
Ghani, Muhammad U; Ren, Liqiang; Wong, Molly et al. (2017) Noise Power Characteristics of a Micro-Computed Tomography System. J Comput Assist Tomogr 41:82-89
Yan, Aimin; Wu, Xizeng; Liu, Hong (2017) Polychromatic X-ray effects on fringe phase shifts in grating interferometry. Opt Express 25:6053-6068
Yan, Aimin; Wu, Xizeng; Liu, Hong (2017) Beam hardening correction in polychromatic x-ray grating interferometry. Opt Express 25:24690-24704
Wu, Di; Wong, Molly Donovan; Li, Yuhua et al. (2017) Quantitative investigation of the edge enhancement in in-line phase contrast projections and tomosynthesis provided by distributing microbubbles on the interface between two tissues: a phantom study. Phys Med Biol 62:9357-9376
Ghani, Muhammad U; Wong, Molly D; Wu, Di et al. (2017) Detectability comparison between a high energy x-ray phase sensitive and mammography systems in imaging phantoms with varying glandular-adipose ratios. Phys Med Biol 62:3523-3538

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