Automatic landmark correspondence detection in medical images with an application to deformable image registration

Grewal, Monika; Wiersma, J.; Westerveld, Henrike; Bosman, Peter A. N.; Alderliesten, Tanja

doi:10.1117/1.jmi.10.1.014007

Cited by 5 publications

(3 citation statements)

References 52 publications

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“…Only one study utilized reinforcement learning [78], a technique where an agent learns to make decisions based on rewards and punishments. Regardless of the ML technique employed, training dataset sizes were generally small, with the three largest patient cohorts corresponding to auto-contouring studies (520-1108 patients) [49,51,86]. ML models often struggle with small sample sizes, especially when considering complex, multidimensional data like medical images, where models must learn intricate generalizable spatial relationships.…”

Section: Discussionmentioning

confidence: 99%

Artificial Intelligence Uncertainty Quantification in Radiotherapy Applications - A Scoping Review

Wahid,

Kaffey,

Farris

et al. 2024

Preprint

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Background/purpose: The use of artificial intelligence (AI) in radiotherapy (RT) is expanding rapidly. However, there exists a notable lack of clinician trust in AI models, underscoring the need for effective uncertainty quantification (UQ) methods. The purpose of this study was to scope existing literature related to UQ in RT, identify areas of improvement, and determine future directions. Methods: We followed the PRISMA-ScR scoping review reporting guidelines. We utilized the population (human cancer patients), concept (utilization of AI UQ), context (radiotherapy applications) framework to structure our search and screening process. We conducted a systematic search spanning seven databases, supplemented by manual curation, up to January 2024. Our search yielded a total of 8980 articles for initial review. Manuscript screening and data extraction was performed in Covidence. Data extraction categories included general study characteristics, RT characteristics, AI characteristics, and UQ characteristics. Results: We identified 56 articles published from 2015-2024. 10 domains of RT applications were represented; most studies evaluated auto-contouring (50%), followed by image-synthesis (13%), and multiple applications simultaneously (11%). 12 disease sites were represented, with head and neck cancer being the most common disease site independent of application space (32%). Imaging data was used in 91% of studies, while only 13% incorporated RT dose information. Most studies focused on failure detection as the main application of UQ (60%), with Monte Carlo dropout being the most commonly implemented UQ method (32%) followed by ensembling (16%). 55% of studies did not share code or datasets. Conclusion: Our review revealed a lack of diversity in UQ for RT applications beyond auto-contouring. Moreover, there was a clear need to study additional UQ methods, such as conformal prediction. Our results may incentivize the development of guidelines for reporting and implementation of UQ in RT.

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Section: Discussionmentioning

confidence: 99%

Artificial Intelligence Uncertainty Quantification in Radiotherapy Applications - A Scoping Review

Wahid,

Kaffey,

Farris

et al. 2024

Preprint

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“…Heinrich et al [9] proposed a landmark detection method specifically designed for lung computed tomography (CT) registration, which is not generalizable to other tasks. Grewal et al [10] presented DCNN-Match, that learns to predict landmark correspondences in lower abdominal CT scans and in a self-supervised manner, which significantly improves the performance in deformable image registration. Song et al [11] proposed an affine registration method for US and MR images based on four anatomical landmarks, which requires not only landmark detection network, but also segmentation network.…”

Section: Introductionmentioning

confidence: 99%

Anatomical Landmark Detection for Initializing US and MR Image Registration

Fang,

Delingette,

Ayache

2023

Lecture Notes in Computer Science

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Targeted MR/ultrasound (US) fusion biopsy is a technology made possible by overlaying ultrasound images of the prostate with MRI sequences for the visualization and the targeting of lesions. However, US and MR image registration requires a good initial alignment based on manual anatomical landmark detection or prostate segmentation, which are time-consuming and often challenging during an intervention. We propose to explicitly and automatically detect anatomical landmarks of prostate in both modalities to achieve initial registration. Firstly, we train a deep neural network to detect three anatomical landmarks for both MR and US images. Instead of relying on heatmap regression or coordinate regression using a fully connected layer, we regress coordinates of landmarks directly by introducing a differentiable layer in U-Net. After being trained and validated on 900 and 152 cases, the proposed method predicts landmarks within a Mean Radial Error (MRE) of 5.55 ± 2.63 mm and 5.77 ± 2.67 mm in 263 test cases for US and MR images, separately. Secondly, least-squares fitting is applied to calculate a rough rigid transformation based on detected anatomical landmarks. Surface registration error (SRE) of 6.62 ± 3.97 mm and Dice score of 0.77 ± 0.11 are achieved, which are both comparable metrics in clinical setting when comparing with previous method.

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“…Preprocessing improves the quality and relevance of the images by removing noise, enhancing contrast [ 12 ], and segmenting the regions of interest. Registration [ 13 ] aligns and merges multiple images of the same patient or anatomical region to enable accurate comparisons and analyses. Feature extraction [ 14 ] identifies and quantifies relevant characteristics or patterns in the image data to aid in diagnosis or treatment planning.…”

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confidence: 99%