Purpose Glioblastoma-multiforme (GBM) treatment is a challenging task in clinical oncology. Convection Enhanced Delivery (CED) is showing encouraging but still suboptimal results due to drug leakages. Numerical models can predict drug distribution within the brain, but require retrieving brain physical properties, such as the axon diameter distribution (ADD), through axon architecture analysis. The goal of this work was to provide an automatic, accurate and fast method for axon segmentation in electronic-microscopy images based on fully convolutional neural network (FCNN) as to allow automatic ADD computation. Methods The segmentation was performed using a residual FCNN inspired by UNet and Resnet. The FCNN training was performed exploiting mini-batch gradient descent and the Adam optimizer. The Dice coecient was chosen as loss function. Results The proposed segmentation method achieved results comparable with already existing methods for axon segmentation in terms of Information Theoretic Scoring (0:98%) with a faster training (5 hours on the deployed GPU) and without requiring heavy post-processing (testing time was 0:2 s with a non-optimized code). The ADDs computed from the segmented and ground-truth images were statistically equivalent. Conclusions The algorithm proposed in this work allowed fast and accurate axon segmentation and ADD computation, showing promising performance for brain micro-structure analysis for CED delivery optimization.

FCNN-based axon segmentation for convection-enhanced delivery optimization

Vidotto, Marco;De Momi, Elena;Gazzara, Michele;Ferrigno, Giancarlo;Moccia, Sara
2019-01-01

Abstract

Purpose Glioblastoma-multiforme (GBM) treatment is a challenging task in clinical oncology. Convection Enhanced Delivery (CED) is showing encouraging but still suboptimal results due to drug leakages. Numerical models can predict drug distribution within the brain, but require retrieving brain physical properties, such as the axon diameter distribution (ADD), through axon architecture analysis. The goal of this work was to provide an automatic, accurate and fast method for axon segmentation in electronic-microscopy images based on fully convolutional neural network (FCNN) as to allow automatic ADD computation. Methods The segmentation was performed using a residual FCNN inspired by UNet and Resnet. The FCNN training was performed exploiting mini-batch gradient descent and the Adam optimizer. The Dice coecient was chosen as loss function. Results The proposed segmentation method achieved results comparable with already existing methods for axon segmentation in terms of Information Theoretic Scoring (0:98%) with a faster training (5 hours on the deployed GPU) and without requiring heavy post-processing (testing time was 0:2 s with a non-optimized code). The ADDs computed from the segmented and ground-truth images were statistically equivalent. Conclusions The algorithm proposed in this work allowed fast and accurate axon segmentation and ADD computation, showing promising performance for brain micro-structure analysis for CED delivery optimization.
2019
Axon segmentation, electron microscopy, deep learning, convection-enhanced delivery, glioblastoma
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11311/1072471
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