Program Information
Analysis of the 3-D Shape of Patients' Breast for Breast Imaging and Surgery Planning
G Agasthya*, I Sechopoulos , Emory University, Atlanta, GA
Presentations
TU-CD-207-9 (Tuesday, July 14, 2015) 10:15 AM - 12:15 PM Room: 207
Purpose:
Develop a method to accurately capture the 3-D shape of patients’ external breast surface before and during breast compression for mammography/tomosynthesis.
Methods:
During this IRB-approved, HIPAA-compliant study, 50 women were recruited to undergo 3-D breast surface imaging during breast compression and imaging for the cranio-caudal (CC) view on a digital mammography/breast tomosynthesis system. Digital projectors and cameras mounted on tripods were used to acquire 3-D surface images of the breast, in three conditions: (a) positioned on the support paddle before compression, (b) during compression by the compression paddle and (c) the anterior-posterior view with the breast in its natural, unsupported position. The breast was compressed to standard full compression with the compression paddle and a tomosynthesis image was acquired simultaneously with the 3-D surface. The 3-D surface curvature and deformation with respect to the uncompressed surface was analyzed using contours. The 3-D surfaces were voxelized to capture breast shape in a format that can be manipulated for further analysis.
Results:
A protocol was developed to accurately capture the 3-D shape of patients’ breast before and during compression for mammography. Using a pair of 3-D scanners, the 50 patient breasts were scanned in three conditions, resulting in accurate representations of the breast surfaces. The surfaces were post processed, analyzed using contours and voxelized, with 1 mm³ voxels, converting the breast shape into a format that can be easily modified as required.
Conclusion:
Accurate characterization of the breast curvature and shape for the generation of 3-D models is possible. These models can be used for various applications such as improving breast dosimetry, accurate scatter estimation, conducting virtual clinical trials and validating compression algorithms.
Funding Support, Disclosures, and Conflict of Interest: Ioannis Sechopoulos is consultant for Fuji Medical Systems USA.
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