Identifying clinically applicable machine learning algorithms for glioma segmentation: recent advances and discoveries

Tillmanns, Niklas; Lum, Avery E; Cassinelli, Gabriel; Merkaj, Sara; Verma, Tej; Zeevi, Tal; Staib, Lawrence H.; Subramanian, Harry; Bahar, Ryan; Brim, W R; Lost, Jan; Jekel, Leon; Brackett, Alexandria; Payabvash, Sam; Ikuta, Ichiro; Lin, MingDe; Bousabarah, Khaled; Johnson, Michele H.; Cui, Jin; Malhotra, Ajay; Omuro, Antonio; Turowski, Bernd; Aboian, Mariam

doi:10.1093/noajnl/vdac093

Cited by 4 publications

(5 citation statements)

References 27 publications

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“…Multiple works demonstrated high accuracy with use of ML for tumor segmentation, identification of images with brain tumors from other pathologies, glioma grade and molecular subtype prediction, differentiation of gliomas from lymphoma or brain metastases. These results suggest that clinical implementation of these algorithms is imminent and will be seen in the clinical practice in the next few years (Subramanian et al, 2021;Afridi et al, 2022;Avery et al, 2022;Bahar et al, 2022;Cassinelli Petersen et al, 2022;Jekel et al, 2022;Tillmanns et al, 2022). The next frontier in neuro-oncology imaging is identification of clinical applications of ML algorithms in clinical practice and determining the aspects of clinical care that can be improved with predictions that can be generated by these algorithms.…”

Section: Discussionmentioning

confidence: 98%

Clinical implementation of artificial intelligence in neuroradiology with development of a novel workflow-efficient picture archiving and communication system-based automated brain tumor segmentation and radiomic feature extraction

Aboian

Bousabarah²,

Kazarian

et al. 2022

Front. Neurosci.

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PurposePersonalized interpretation of medical images is critical for optimum patient care, but current tools available to physicians to perform quantitative analysis of patient’s medical images in real time are significantly limited. In this work, we describe a novel platform within PACS for volumetric analysis of images and thus development of large expert annotated datasets in parallel with radiologist performing the reading that are critically needed for development of clinically meaningful AI algorithms. Specifically, we implemented a deep learning-based algorithm for automated brain tumor segmentation and radiomics extraction, and embedded it into PACS to accelerate a supervised, end-to- end workflow for image annotation and radiomic feature extraction.Materials and methodsAn algorithm was trained to segment whole primary brain tumors on FLAIR images from multi-institutional glioma BraTS 2021 dataset. Algorithm was validated using internal dataset from Yale New Haven Health (YHHH) and compared (by Dice similarity coefficient [DSC]) to radiologist manual segmentation. A UNETR deep-learning was embedded into Visage 7 (Visage Imaging, Inc., San Diego, CA, United States) diagnostic workstation. The automatically segmented brain tumor was pliable for manual modification. PyRadiomics (Harvard Medical School, Boston, MA) was natively embedded into Visage 7 for feature extraction from the brain tumor segmentations.ResultsUNETR brain tumor segmentation took on average 4 s and the median DSC was 86%, which is similar to published literature but lower than the RSNA ASNR MICCAI BRATS challenge 2021. Finally, extraction of 106 radiomic features within PACS took on average 5.8 ± 0.01 s. The extracted radiomic features did not vary over time of extraction or whether they were extracted within PACS or outside of PACS. The ability to perform segmentation and feature extraction before radiologist opens the study was made available in the workflow. Opening the study in PACS, allows the radiologists to verify the segmentation and thus annotate the study.ConclusionIntegration of image processing algorithms for tumor auto-segmentation and feature extraction into PACS allows curation of large datasets of annotated medical images and can accelerate translation of research into development of personalized medicine applications in the clinic. The ability to use familiar clinical tools to revise the AI segmentations and natively embedding the segmentation and radiomic feature extraction tools on the diagnostic workstation accelerates the process to generate ground-truth data.

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Section: Discussionmentioning

confidence: 98%

Clinical implementation of artificial intelligence in neuroradiology with development of a novel workflow-efficient picture archiving and communication system-based automated brain tumor segmentation and radiomic feature extraction

Aboian

Bousabarah²,

Kazarian

et al. 2022

Front. Neurosci.

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“…While there have been several efforts to segment brain lesions from MRIs, such as through the Brain Tumor Segmentation Challenge (BraTS), those efforts have focused on pre-surgical brain MRIs, and have yet to make a substantial translation into clinically useful tools [6][7][8][9]. There have been minimal efforts to develop segmentation algorithms to assist RT planning after surgery.…”

Section: Related Workmentioning

confidence: 99%

A Fully Automated Post-Surgical Brain Tumor Segmentation Model for Radiation Treatment Planning and Longitudinal Tracking

Ramesh

Trivedi

et al. 2023

Cancers

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Glioblastoma (GBM) has a poor survival rate even with aggressive surgery, concomitant radiation therapy (RT), and adjuvant chemotherapy. Standard-of-care RT involves irradiating a lower dose to the hyperintense lesion in T2-weighted fluid-attenuated inversion recovery MRI (T2w/FLAIR) and a higher dose to the enhancing tumor on contrast-enhanced, T1-weighted MRI (CE-T1w). While there have been several attempts to segment pre-surgical brain tumors, there have been minimal efforts to segment post-surgical tumors, which are complicated by a resection cavity and postoperative blood products, and tools are needed to assist physicians in generating treatment contours and assessing treated patients on follow up. This report is one of the first to train and test multiple deep learning models for the purpose of post-surgical brain tumor segmentation for RT planning and longitudinal tracking. Post-surgical FLAIR and CE-T1w MRIs, as well as their corresponding RT targets (GTV1 and GTV2, respectively) from 225 GBM patients treated with standard RT were trained on multiple deep learning models including: Unet, ResUnet, Swin-Unet, 3D Unet, and Swin-UNETR. These models were tested on an independent dataset of 30 GBM patients with the Dice metric used to evaluate segmentation accuracy. Finally, the best-performing segmentation model was integrated into our longitudinal tracking web application to assign automated structured reporting scores using change in percent cutoffs of lesion volume. The 3D Unet was our best-performing model with mean Dice scores of 0.72 for GTV1 and 0.73 for GTV2 with a standard deviation of 0.17 for both in the test dataset. We have successfully developed a lightweight post-surgical segmentation model for RT planning and longitudinal tracking.

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“… 36–38 Deep convolutional neural network models have been widely used for tumor segmentation. 39 U-Net architecture and its variants are among the most commonly used models for tumor segmentation. 40 In fact, conventional machine learning (ML) and DL U-Net models proposed for glioma segmentation have been systematically reviewed.…”

Section: Radiomics As a Clinical Toolmentioning

confidence: 99%

“… 40 In fact, conventional machine learning (ML) and DL U-Net models proposed for glioma segmentation have been systematically reviewed. 39 They reported that deep learning models such as U-Net have the potential for deployment in a clinical setting.…”

Section: Radiomics As a Clinical Toolmentioning

confidence: 99%

Radiomics as an emerging tool in the management of brain metastases

Nowakowski

Lahijanian

Panet-Raymond

et al. 2022

Neuro-Oncology Advances

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Brain metastases (BM) are associated with significant morbidity and mortality in patients with advanced cancer. Despite significant advances in surgical, radiation, and systemic therapy in recent years, the median overall survival of patients with BM is less than one year. The acquisition of medical images, such as computed tomography (CT) and magnetic resonance imaging (MRI), is critical for the diagnosis and stratification of patients to appropriate treatments. Radiomic analyses have the potential to improve the standard of care for patients with BM by applying artificial intelligence (AI) with already acquired medical images to predict clinical outcomes and direct the personalized care of BM patients. Herein, we outline the existing literature applying radiomics for the clinical management of BM. This includes predicting patient response to radiotherapy and identifying radiation necrosis, performing virtual biopsies to predict tumor mutation status, and determining the cancer of origin in brain tumors identified via imaging. With further development, radiomics has the potential to aid in BM patient stratification while circumventing the need for invasive tissue sampling, particularly for patients not eligible for surgical resection.

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Identifying clinically applicable machine learning algorithms for glioma segmentation: recent advances and discoveries

Cited by 4 publications

References 27 publications

Clinical implementation of artificial intelligence in neuroradiology with development of a novel workflow-efficient picture archiving and communication system-based automated brain tumor segmentation and radiomic feature extraction

Clinical implementation of artificial intelligence in neuroradiology with development of a novel workflow-efficient picture archiving and communication system-based automated brain tumor segmentation and radiomic feature extraction

A Fully Automated Post-Surgical Brain Tumor Segmentation Model for Radiation Treatment Planning and Longitudinal Tracking

Radiomics as an emerging tool in the management of brain metastases

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