Simultaneous Classification and Segmentation of Intracranial Hemorrhage Using a Fully Convolutional Neural Network

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Simultaneous Classification and Segmentation of Intracranial Hemorrhage Using a Fully Convolutional Neural Network


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Simultaneous Classification and Segmentation of Intracranial Hemorrhage Using a Fully Convolutional Neural Network

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Intracranial hemorrhage (ICH) is a critical disease that requires immediate diagnosis and treatment. Accurate detection, subtype classification and volume quantification of ICH are critical aspects in ICH diagnosis. Previous studies have applied deep learning techniques for ICH analysis but usually tackle the aforementioned tasks in a separate manner without taking advantage of information sharing between tasks. In this paper, we propose a multi-task fully convolutional network, ICHNet, for simultaneous detection, classification and segmentation of ICH. The proposed framework utilizes the inter-slice contextual information and has the flexibility in handling various label settings and task combinations. We evaluate the performance of our proposed architecture using a total of 1176 head CT scans and show that it improves the performance of both classification and segmentation tasks compared with single-task and baseline models.
Intracranial hemorrhage (ICH) is a critical disease that requires immediate diagnosis and treatment. Accurate detection, subtype classification and volume quantification of ICH are critical aspects in ICH diagnosis. Previous studies have applied deep learning techniques for ICH analysis but usually tackle the aforementioned tasks in a separate manner without taking advantage of information sharing between tasks. In this paper, we propose a multi-task fully convolutional network, ICHNet, for simultaneous detection, classification and segmentation of ICH. The proposed framework utilizes the inter-slice contextual information and has the flexibility in handling various label settings and task combinations. We evaluate the performance of our proposed architecture using a total of 1176 head CT scans and show that it improves the performance of both classification and segmentation tasks compared with single-task and baseline models.