Elasticity Training Helps AI Diagnose Breast Cancer
By MedImaging International staff writers Posted on 22 Jul 2019 |
Teaching artificial intelligence (AI) algorithms to identify the ultrasound elastic heterogeneity of a tumor can be used to distinguish benign tumors from their malignant counterparts, according to a new study.
Researchers at the University of Southern California (USC; Los Angeles, USA), Rensselaer Polytechnic Institute (RPI; Troy, NY, USA), and other institutions created physics-based models that simulated varying levels of the two key ultrasound properties of a cancerous breast tumor - elastic heterogeneity and nonlinear elastic response. They then used thousands of data inputs derived from the models in order to train a deep convolutional neural network (CNN) to classify tumors as malignant or benign.
A 5-layer CNN was trained with 8,000 samples for heterogeneity, and a 4-layer CNN was trained with 4,000 samples for nonlinear elasticity. When queried on additional synthetic images, the CNNs achieved classification accuracies of 99.7%−99.9%. The researchers then applied the nonlinear elasticity classifier, which was trained entirely using simulated data, in order to classify displacement images obtained from ten patients with breast lesions; the CNN correctly classified eight out of ten cases.
“The general consensus is these types of algorithms have a significant role to play, including from imaging professionals whom it will impact the most,” said senior author Professor Assad Oberai, PhD, of the USC department of aerospace and mechanical engineering. “However, these algorithms will be most useful when they do not serve as black boxes, but instead, a tool that helps guide radiologists to more accurate conclusions.”
Elastography relies on the generation of shear waves determined by the displacement of tissues induced by the force of a focused ultrasound beam or by external pressure. The shear waves are lateral waves, with a motion perpendicular to the direction of the generating force, traveling slowly, and are rapidly attenuated by tissue. The propagation velocity of the shear waves correlates with the elasticity of tissue.
Related Links:
University of Southern California
Rensselaer Polytechnic Institute
Researchers at the University of Southern California (USC; Los Angeles, USA), Rensselaer Polytechnic Institute (RPI; Troy, NY, USA), and other institutions created physics-based models that simulated varying levels of the two key ultrasound properties of a cancerous breast tumor - elastic heterogeneity and nonlinear elastic response. They then used thousands of data inputs derived from the models in order to train a deep convolutional neural network (CNN) to classify tumors as malignant or benign.
A 5-layer CNN was trained with 8,000 samples for heterogeneity, and a 4-layer CNN was trained with 4,000 samples for nonlinear elasticity. When queried on additional synthetic images, the CNNs achieved classification accuracies of 99.7%−99.9%. The researchers then applied the nonlinear elasticity classifier, which was trained entirely using simulated data, in order to classify displacement images obtained from ten patients with breast lesions; the CNN correctly classified eight out of ten cases.
“The general consensus is these types of algorithms have a significant role to play, including from imaging professionals whom it will impact the most,” said senior author Professor Assad Oberai, PhD, of the USC department of aerospace and mechanical engineering. “However, these algorithms will be most useful when they do not serve as black boxes, but instead, a tool that helps guide radiologists to more accurate conclusions.”
Elastography relies on the generation of shear waves determined by the displacement of tissues induced by the force of a focused ultrasound beam or by external pressure. The shear waves are lateral waves, with a motion perpendicular to the direction of the generating force, traveling slowly, and are rapidly attenuated by tissue. The propagation velocity of the shear waves correlates with the elasticity of tissue.
Related Links:
University of Southern California
Rensselaer Polytechnic Institute
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