Ahmed Amr Harouni1, Nael F. Osman2,
Michael A. Jacobs3
1Electrical & Computer
Engineering, Johns Hopkins University, Baltimore , MD, United States; 2Department
of Radiology, Johns Hopkins University, Baltimore, MD, United States; 3Department
of Radiology & Oncology, Johns Hopkins University school of Medicine,
Baltimore, MD, United States
Previously, we proposed using mass stiffness to increase specificity of breast cancer detection using MRI. We used strain-Encoded (SENC) MRI to measure strain, which is inversely proportional to stiffness. However, since SENC was originally developed for cardiac applications, 30% compression was used. In this work, we investigate the minimum compression required to apply in order to detect and classify breast masses through finite element method simulations and phantom experiments. Our results, shows that we can detect masses with low compressions (5-10%), but in order to classify benign from malignant masses we need to use higher compression (10-15%).