Deep learning‐based digitization of prostate brachytherapy needles in ultrasound images

Andersén, Christoffer; Rydén, Tobias; Thunberg, Per; Lagerlöf, Jakob H.

doi:10.1002/mp.14508

Cited by 18 publications

(16 citation statements)

References 32 publications

(71 reference statements)

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“…This algorithm can then be tested prospectively, ideally with less-experienced and more-experienced observers across multiple centers, to evaluate whether such an AI algorithm can reduce errors in prostate delineation. This algorithm could also be utilized in conjunction with deep-learning algorithms for catheter digitization on TRUS, 17,18 which may allow for more accurate and rapid treatment planning.…”

Section: Discussionmentioning

confidence: 99%

Observer preference of artificial intelligence‐generated versus clinical prostate contours for ultrasound‐based high dose rate brachytherapy

King,

Kehayias,

Chaunzwa

et al. 2023

Medical Physics

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BackgroundFor trans‐rectal ultrasound (TRUS)‐based high dose rate (HDR) prostate brachytherapy, prostate contouring can be challenging due to artifacts from implanted needles, bleeding, and calcifications.PurposeTo evaluate the geometric accuracy and observer preference of an artificial intelligence (AI) algorithm for generating prostate contours on TRUS images with implanted needles.MethodsWe conducted a retrospective study of 150 patients, who underwent HDR brachytherapy. These patients were randomly divided into training (104), validation (26) and testing (20) sets. An AI algorithm was trained/validated utilizing the TRUS image and reference (clinical) contours. The algorithm then provided contours for the test set. For evaluation, we calculated the Dice coefficient between AI and reference prostate contours. We then presented AI and reference contours to eight clinician observers, and asked observers to select their preference. Observers were blinded to the source of contours. We calculated the percentage of cases in which observers preferred AI contours. Lastly, we evaluate whether the presence of AI contours improved the geometric accuracy of prostate contours provided by five resident observers for a 10‐patient subset.ResultsThe median Dice coefficient between AI and reference contours was 0.92 (IQR: 0.90–0.94). Observers preferred AI contours for a median of 57.5% (IQR: 47.5, 65.0) of the test cases. For resident observers, the presence of AI contours was associated with a 0.107 (95% CI: 0.086, 0.128; p < 0.001) improvement in Dice coefficient for the 10‐patient subset.ConclusionThe AI algorithm provided high‐quality prostate contours on TRUS with implanted needles. Further prospective study is needed to better understand how to incorporate AI prostate contours into the TRUS‐based HDR brachytherapy workflow.

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Section: Discussionmentioning

confidence: 99%

Observer preference of artificial intelligence‐generated versus clinical prostate contours for ultrasound‐based high dose rate brachytherapy

King,

Kehayias,

Chaunzwa

et al. 2023

Medical Physics

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“…In our approach, segmentation regions were predicted for the entire image volume by making predictions from previous slices. This work is partially dependent on the original form of the UNet deep learning model developed by Ronneberger et al 21 This model was chosen because (i) this model is based on the convolution neural network (CNN), which has been extensively used to develop automated accurate and stable detection and segmentation methods for the clinical target volume and brachytherapy catheters on US, MR and CT images during prostate and gynecological brachytherapy, 18,24,25 and (ii) learned features from UNet CNN layers can be recognized regardless of their position in the image.This makes it useful for processing images with similar features (e.g., catheter positions), and is robust against variations in feature position or imaging conditions. 26 Few studies have investigated the use of fully automatic or semiautomatic reconstruction of interstitial catheters during gynecological HDR brachytherapy.…”

Section: Discussionmentioning

confidence: 99%

Deep‐learning‐assisted algorithm for catheter reconstruction during MR‐only gynecological interstitial brachytherapy

Shaaer

Paudel

Smith

et al. 2021

J Applied Clin Med Phys

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Magnetic resonance imaging (MRI) offers excellent soft-tissue contrast enabling the contouring of targets and organs at risk during gynecological interstitial brachytherapy procedure. Despite its advantage, one of the main obstacles preventing a transition to an MRI-only workflow is that implanted plastic catheters are not reliably visualized on MR images. This study aims to evaluate the feasibility of a deep-learning-based algorithm for semiautomatic reconstruction of interstitial catheters during an MR-only workflow. MR images of 20 gynecological patients were used in this study. Note that 360 catheters were reconstructed using T1-and T2-weighted images by five experienced brachytherapy planners. The mean of the five reconstructed paths were used for training (257 catheters), validation (15 catheters), and testing/evaluation (88 catheters). To automatically identify and localize the catheters, a two-dimensional (2D) U-net algorithm was used to find their approximate location in each image slice. Once localized, thresholding was applied to those regions to find the extrema, as catheters appear as bright and dark regions in T1-and T2-weighted images, respectively. The localized dwell positions of the proposed algorithm were compared to the ground truth reconstruction. Reconstruction time was also evaluated. A total of 34 009 catheter dwell positions were evaluated between the algorithm and all planners to estimate the reconstruction variability. The average variation was 0.97 ± 0.66 mm. The average reconstruction time for this approach was 11 ± 1 min, compared with 46 ± 10 min for the expert planners. This study suggests that the proposed deep learning, MR-based framework has potential to replace the conventional manual catheter reconstruction. The adoption of this approach in the brachytherapy workflow is expected to improve treatment efficiency while reducing planning time, resources, and human errors.

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“…However, for 3D volumetric data, the decomposition approach may limit semantic information usage due to the compromised 3D information after slicing. To address this, patch-based 2.5D or 3D U-Net were proposed to segment the cardiac catheter (Yang et al 2019a(Yang et al , c, f, 2020a or prostate needles (Zhang et al 2020d;Andersén et al 2020) in 3D volumetric data by dividing the image into smaller patches or reducing the image size. In this way, the 3D contextual information is preserved and the requirement on GPU memory is reduced for 3D deep learning.…”

Section: Deep Learning-based Methodsmentioning

confidence: 99%

Medical instrument detection in ultrasound: a review

Yang

Shan²,

Kolen³

et al. 2022

Artif Intell Rev

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Medical instrument detection is essential for computer-assisted interventions, since it facilitates clinicians to find instruments efficiently with a better interpretation, thereby improving clinical outcomes. This article reviews image-based medical instrument detection methods for ultrasound-guided (US-guided) operations. Literature is selected based on an exhaustive search in different sources, including Google Scholar, PubMed, and Scopus. We first discuss the key clinical applications of medical instrument detection in the US, including delivering regional anesthesia, biopsy taking, prostate brachytherapy, and catheterization. Then, we present a comprehensive review of instrument detection methodologies, including non-machine-learning and machine-learning methods. The conventional non-machine-learning methods were extensively studied before the era of machine learning methods. The principal issues and potential research directions for future studies are summarized for the computer-assisted intervention community. In conclusion, although promising results have been obtained by the current (non-) machine learning methods for different clinical applications, thorough clinical validations are still required.

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Deep learning‐based digitization of prostate brachytherapy needles in ultrasound images

Cited by 18 publications

References 32 publications

Observer preference of artificial intelligence‐generated versus clinical prostate contours for ultrasound‐based high dose rate brachytherapy

Observer preference of artificial intelligence‐generated versus clinical prostate contours for ultrasound‐based high dose rate brachytherapy

Deep‐learning‐assisted algorithm for catheter reconstruction during MR‐only gynecological interstitial brachytherapy

Medical instrument detection in ultrasound: a review

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