RSNA 2007 

Abstract Archives of the RSNA, 2007


SSC13-05

Novel Gantry-free Digital Breast Tomosynthesis (DBT) System Using a Stationary Multibeam Field Emission X-ray Source Array Based on Carbon Nanotubes

Scientific Papers

Presented on November 26, 2007
Presented as part of SSC13: Physics (Tomosynthesis/Breast Tomosynthesis)

 Trainee Research Prize - Resident

Participants

Guang Yang, Presenter: Nothing to Disclose
Ramya Rajama, Abstract Co-Author: Nothing to Disclose
Guohua Cao, Abstract Co-Author: Nothing to Disclose
Shabana Sultana, Abstract Co-Author: Nothing to Disclose
David Lalush, Abstract Co-Author: Nothing to Disclose
Jianping Lu, Abstract Co-Author: Nothing to Disclose
Otto Zhou PhD, Abstract Co-Author: Nothing to Disclose
et al, Abstract Co-Author: Nothing to Disclose
et al, Abstract Co-Author: Nothing to Disclose

PURPOSE

To test the feasibility of a novel gantry-free digital breast tomosynthesis (DBT) system using a stationary multi-beam field emission X-ray source array based on carbon nanotubes (CNTs) and to compare the system performance with the conventional devices.

METHOD AND MATERIALS

Two tomosynthesis imaging systems have been built: a compact model and a full scale model, which contain 9 and 25 individual X-ray pixels, respectively. The compact model can only image a partial breast phantom due to the limited span of the X-ray source array and the small FOV of the detector. The full scale system is capable of full field digital mammography by utilizing a detector with 20-cm FOV. The geometry of the full scale system is also comparable to the conventional DBT devices (refer to the supporting material). The system geometry, such as the source to detector distance (SDD) and X-ray source position, is calibrated. The slice images at different depths are reconstructed using ordered subset convex (maximum likelihood) method. The system performance is evaluated by measuring parameters such as MTF and SNR.

RESULTS

By eliminating the rotary gantry, the system design is simplified and the issue if image blurring due to x-ray source motion is removed. The total scan time can potentially be further shortened with a faster detector readout speed.

CONCLUSION

By eliminating the rotary gantry, the system noise and equipment cost of the tomosynthesis imaging system are reduced. The total scan time can be further shortened with faster detector readout speed. The novel stationary tomosysthesis system shows great potential in clinical imaging.

CLINICAL RELEVANCE/APPLICATION

Stationary DBT system has similar performance to conventional systems with much higher cost, and is recommended for all mammography applications.

Cite This Abstract

Yang, G, Rajama, R, Cao, G, Sultana, S, Lalush, D, Lu, J, Zhou, O, et al, , et al, , Novel Gantry-free Digital Breast Tomosynthesis (DBT) System Using a Stationary Multibeam Field Emission X-ray Source Array Based on Carbon Nanotubes.  Radiological Society of North America 2007 Scientific Assembly and Annual Meeting, November 25 - November 30, 2007 ,Chicago IL. http://archive.rsna.org/2007/5009907.html