AI Article Synopsis
- - The review focuses on how artificial intelligence (AI) is revolutionizing anomaly detection in magnetic resonance imaging (MRI), improving diagnostics across various medical fields.
- - It examines cutting-edge machine learning and deep learning techniques used for preprocessing, feature extraction, classification, and segmentation of MR images, with a look at metrics for evaluating these processes.
- - Additionally, the paper discusses recent advancements in ensemble methods and explainable AI, aiming to provide insights for future innovations in MRI technology to enhance diagnostic accuracy and patient care.
Article Abstract
Anomaly detection in medical imaging, particularly within the realm of magnetic resonance imaging (MRI), stands as a vital area of research with far-reaching implications across various medical fields. This review meticulously examines the integration of artificial intelligence (AI) in anomaly detection for MR images, spotlighting its transformative impact on medical diagnostics. We delve into the forefront of AI applications in MRI, exploring advanced machine learning (ML) and deep learning (DL) methodologies that are pivotal in enhancing the precision of diagnostic processes. The review provides a detailed analysis of preprocessing, feature extraction, classification, and segmentation techniques, alongside a comprehensive evaluation of commonly used metrics. Further, this paper explores the latest developments in ensemble methods and explainable AI, offering insights into future directions and potential breakthroughs. This review synthesizes current insights, offering a valuable guide for researchers, clinicians, and medical imaging experts. It highlights AI's crucial role in improving the precision and speed of detecting key structural and functional irregularities in MRI. Our exploration of innovative techniques and trends furthers MRI technology development, aiming to refine diagnostics, tailor treatments, and elevate patient care outcomes. LEVEL OF EVIDENCE: 5 TECHNICAL EFFICACY: Stage 1.
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| http://dx.doi.org/10.1002/jmri.29247 | DOI Listing |
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