A New Stationary Digital Breast Tomosynthesis System: Implementation and Characterization

Digital breast tomosynthesis systems (DBT) use a single thermionic x-ray source that moves around the breast in a fixed angular span. As a result, all current DBT system requires the mechanical motion of the x-ray source during the scan, limiting image quality either due to the focal spot blurring or a long scan time. This causes an unfavorable reduction in the in-plane resolution compared to 2D mammography. Our research group developed and demonstrated a first generation stationary digital breast tomosynthesis (s-DBT) system that uses a linear carbon nanotube (CNT) x-ray source array. Since the stationary sources are not subject to focal spot blurring, and images can be acquired rapidly, the in-plane system resolution is improved. Additionally, image acquisition time is independent of angular span since there is no motion, allowing for large angular spans, and increased depth resolution. The improved resolution of the first generation s-DBT system over continuous motion (CM) DBT has been demonstrated with image evaluation phantoms and a human specimen study. The first generation s-DBT is currently undergoing clinical trials at the University of North Carolina Cancer Hospital. Limitations associated with the first generation system, such as limited tube flux, and limited x-ray energy, placed limitations on our clinical trials and future clinical implementation. Also, the limited angular span could be improved for increased depth resolution, as there is no cost on patient imaging time. The goal of this thesis work was to design construct and characterize a second generation s-DBT system, capable of faster image acquisition times, and higher depth resolution than our first generation system. The second generation s-DBT system was built using a newly designed distributed CNT x-ray source array. The system was then characterized and compared to the first generation system and two commercially available DBT systems. Using physical measurements that are used in medical imaging, the system showed significant improvement in resolution over the first generation system and both commercially available systems, coupled with equal or faster image acquisition times. A separate study investigating the feasibility of contrast enhanced (CE) imaging was conducted, where the system showed capability in both temporal subtraction (TS) and dual energy (DE) imaging.Doctor of Philosoph

Comparison of a Stationary Digital Breast Tomosynthesis System to Magnified 2D Mammography Using Breast Tissue Specimens

RATIONAL AND OBJECTIVES: The objective of this study was to compare the stationary digital breast tomosynthesis (s-DBT) system to a conventional mammography system in a study of breast specimens. Radiologist evaluation of image quality was assessed in a reader study. This study represents the first human tissue imaging with the novel carbon nanotube-based s-DBT device. MATERIALS AND METHODS: Thirty-nine patients, with known breast lesions (Breast Imaging Reporting and Data System 4 or 5) by conventional mammography and scheduled for needle localization biopsy, were recruited under an institutional review board-approved protocol. Specimen images were obtained using a two-dimensional (2D) mammography system with a ×1.8 magnification factor and an s-DBT system without a high magnification factor. A reader study was performed with four breast fellowship-trained radiologists over two separate sessions. Malignancy scores were recorded for both masses and microcalcifications (MCs). Reader preference between the two modalities for MCs, masses, and surgical margins was recorded. RESULTS: The s-DBT system was found to be comparable to magnified 2D mammography for malignancy diagnosis. Readers preferred magnified 2D mammography for MC visualization (P < .05). However, readers trended toward a preference for s-DBT with respect to masses and surgical margin assessment. CONCLUSIONS: Here, we report on the first human data acquired using a stationary digital breast tomosynthesis system. The novel s-DBT system was found to be comparable to magnified 2D mammography imaging for malignancy diagnosis. Given the trend of preference for s-DBT over 2D mammography for both mass visibility and margin assessment, s-DBT could be a viable alternative to magnified 2D mammography for imaging breast specimens