Options
Deep Learning for High Speed Optical Coherence Elastography
Publikationstyp
Conference Paper
Date Issued
2020-04
Sprache
English
Institut
TORE-URI
Volume
2020-April
Start Page
1583
End Page
1586
Article Number
9098422
Citation
IEEE 17th International Symposium on Biomedical Imaging (ISBI 2020)
Contribution to Conference
Publisher DOI
Scopus ID
Mechanical properties of tissue provide valuable information for identifying lesions. One approach to obtain quantitative estimates of elastic properties is shear wave elastography with optical coherence elastography (OCE). However, given the shear wave velocity, it is still difficult to estimate elastic properties. Hence, we propose deep learning to directly predict elastic tissue properties from OCE data. We acquire 2D images with a frame rate of 30 kHz and use convolutional neural networks to predict gelatin concentration, which we use as a surrogate for tissue elasticity. We compare our deep learning approach to predictions from conventional regression models, using the shear wave velocity as a feature. Mean absolut prediction errors for the conventional approaches range from 1.32± 0.98 p.p. to 1.57± 1.30 p.p. whereas we report an error of 0.90± 0.84 p.p. for the convolutional neural network with 3D spatio-temporal input. Our results indicate that deep learning on spatio-temporal data outperforms elastography based on explicit shear wave velocity estimation.
Subjects
Convolutional Neural Networks
Deep Learning
High-Speed Imaging
Optical Coherence Elastography
Shear Wave Elastography