A Supervised Learning Framework for Automatic Prostate Segmentation in Trans Rectal Ultrasound Images

Ghose, Soumya; Mitra, Jhimli; Oliver, Arnau; Martí, Robert; Lladó, Xavier; Freixenet, Jordi; Vilanova, Joan C.; Comet, Josep; Sidibé, Désiré; Mériaudeau, Fabrice

doi:10.1007/978-3-642-33140-4_17

Cited by 10 publications

(8 citation statements)

References 19 publications

(45 reference statements)

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“…The supervised methods can be grouped into support vector machines (SVM)‐based, random forest‐based, and the deep learning‐based methods. The SVM‐based and random forest‐based methods use TRUS contour boundary information, such as texture features or shape statistic information, to train a SVM or random forest classifier for future segmentation . To address the problem that traditional machine‐learning‐based methods are challenging to handcrafted, high‐dimensional, and ill‐posed mapping from TRUS image to binary segmentation, a deep learning method has been introduced into medical image segmentation .…”

Section: Introductionmentioning

confidence: 99%

Ultrasound prostate segmentation based on multidirectional deeply supervised V‐Net

Lei

Tian²,

He³

et al. 2019

Medical Physics

107

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Purpose: Transrectal ultrasound (TRUS) is a versatile and real-time imaging modality that is commonly used in image-guided prostate cancer interventions (e.g., biopsy and brachytherapy). Accurate segmentation of the prostate is key to biopsy needle placement, brachytherapy treatment planning, and motion management. Manual segmentation during these interventions is time-consuming and subject to inter-and intraobserver variation. To address these drawbacks, we aimed to develop a deep learning-based method which integrates deep supervision into a three-dimensional (3D) patch-based V-Net for prostate segmentation. Methods and materials: We developed a multidirectional deep-learning-based method to automatically segment the prostate for ultrasound-guided radiation therapy. A 3D supervision mechanism is integrated into the V-Net stages to deal with the optimization difficulties when training a deep network with limited training data. We combine a binary cross-entropy (BCE) loss and a batch-based Dice loss into the stage-wise hybrid loss function for a deep supervision training. During the segmentation stage, the patches are extracted from the newly acquired ultrasound image as the input of the well-trained network and the well-trained network adaptively labels the prostate tissue. The final segmented prostate volume is reconstructed using patch fusion and further refined through a contour refinement processing. Results: Forty-four patients' TRUS images were used to test our segmentation method. Our segmentation results were compared with the manually segmented contours (ground truth). The mean prostate volume Dice similarity coefficient (DSC), Hausdorff distance (HD), mean surface distance (MSD), and residual mean surface distance (RMSD) were 0.92 AE 0.03, 3.94 AE 1.55, 0.60 AE 0.23, and 0.90 AE 0.38 mm, respectively. Conclusion: We developed a novel deeply supervised deep learning-based approach with reliable contour refinement to automatically segment the TRUS prostate, demonstrated its clinical feasibility, and validated its accuracy compared to manual segmentation. The proposed technique could be a useful tool for diagnostic and therapeutic applications in prostate cancer.

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Section: Introductionmentioning

confidence: 99%

Ultrasound prostate segmentation based on multidirectional deeply supervised V‐Net

Lei

Tian²,

He³

et al. 2019

Medical Physics

107

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“…Extracting key imaging features using image processing techniques alone has been employed in convolutional neural networks for feature extraction and would be of interest to explore for the brachytherapy-specific ML algorithm evaluated in this thesis [122]. Supervised ML algorithms for auto-contouring of the prostate gland on Transrectal Ultrasound (TRUS) imaging alone have also been evaluated with excellent results [123].…”

Section: Database and Feature Extractionmentioning

confidence: 99%

“…Multicenter learning for prostate treatment plan creation (for both external radiotherapy and brachytherapy) is a possibility; anonymized meta-data may be transferrable between centers and offers an indirect method of sharing expertise, or even aggregating data for predicting outcomes more accurately [130,131]. More common applications that focus on workflow efficiencies include methods for automated contouring of target structures such as the prostate gland [123,132], and treatment planning assistance tools in Intensity Modulated Radiotherapy (IMRT) [133]. An excellent book by El Naqa et al…”

Section: Machine Learning For Prostate Radiotherapymentioning

confidence: 99%

Machine Learning Optimization for Prostate Brachytherapy Treatment Planning

Nicolae¹

2021

Preprint

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Prostate Low-Dose-Rate brachytherapy (LDR) is one of the most effective treatments for localized prostate cancer. Machine Learning (ML), the application of statistics to complex computational problem solving, was applied to prostate LDR brachytherapy treatment planning. Planning time, pre-implant dosimetry, and various measures of clinical implant quality for ML plans were compared against plans created by expert brachytherapists. The average planning time to create an ML plan was 0.84 _ 0.57 min compared to over 17.88 _ 8.76 min for an experienced brachytherapists. Dosimetry was not significantly different for ML and expert brachytherapist plans. Clinical implant quality for the ML plans were ranked as nearly equivalent to the brachytherapist treatment plans in all qualitative categories evaluated. The results of this thesis demonstrate that it is possible to generate high quality prostate brachytherapy treatment plans with comparable quality to those of a human expert using a custom ML algorithm.

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“…Another combination was also tested: the shape and a posteriori probability distribution [9,54,118,119]. Three types of features were employed by Li et al [15] to obtain information about the movement of the prostate in the pelvis: appearance, the histogram of the oriented gradient, and the coordinates of each pixel.…”

Section: 122mentioning

confidence: 99%

A survey of prostate modeling for image analysis

Chilali¹,

Ouzzane²,

Diaf³

et al. 2014

Computers in Biology and Medicine

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Computer technology is widely used for multimodal image analysis of the prostate gland. Several techniques have been developed, most of which incorporate a priori knowledge extracted from organ features. Knowledge extraction and modeling are multi-step tasks. Here, we review these steps and classify the modeling according to the data analysis methods employed and the features used. We conclude with a survey of some clinical applications where these techniques are employed.

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A Supervised Learning Framework for Automatic Prostate Segmentation in Trans Rectal Ultrasound Images

Cited by 10 publications

References 19 publications

Ultrasound prostate segmentation based on multidirectional deeply supervised V‐Net

Ultrasound prostate segmentation based on multidirectional deeply supervised V‐Net

Machine Learning Optimization for Prostate Brachytherapy Treatment Planning

A survey of prostate modeling for image analysis

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