Recent Advances in Explainable Artificial Intelligence for Magnetic Resonance Imaging

Qian, Jinzhao; Li, Hailong; Wang, Junqi; He, Lili

doi:10.3390/diagnostics13091571

Cited by 16 publications

(7 citation statements)

References 105 publications

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“…However, most DL models are often considered ‘black boxes’ due to their nonlinear underlying structures. This has led to the emergence of explainable artificial intelligence (XAI) research, which aims to enhance transparency in AI models and interpret the fidelity of their inferences [ 18 ]. Gradient-weighted class activation mapping (Grad-CAM) is one of the most commonly used XAI methods for enhancing the visual evaluation of the site at which a CNN model is focusing its attention during inference [ 19 ].…”

Section: Methodsmentioning

confidence: 99%

Diagnosis of skull-base invasion by nasopharyngeal tumors on CT with a deep-learning approach

Nakagawa,

Fujima,

Hirata

et al. 2024

Jpn J Radiol

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Purpose To develop a convolutional neural network (CNN) model to diagnose skull-base invasion by nasopharyngeal malignancies in CT images and evaluate the model’s diagnostic performance. Materials and methods We divided 100 malignant nasopharyngeal tumor lesions into a training (n = 70) and a test (n = 30) dataset. Two head/neck radiologists reviewed CT and MRI images and determined the positive/negative skull-base invasion status of each case (training dataset: 29 invasion-positive and 41 invasion-negative; test dataset: 13 invasion-positive and 17 invasion-negative). Preprocessing involved extracting continuous slices of the nasopharynx and clivus. The preprocessed training dataset was used for transfer learning with Residual Neural Networks 50 to create a diagnostic CNN model, which was then tested on the preprocessed test dataset to determine the invasion status and model performance. Original CT images from the test dataset were reviewed by a radiologist with extensive head/neck imaging experience (senior reader: SR) and another less-experienced radiologist (junior reader: JR). Gradient-weighted class activation maps (Grad-CAMs) were created to visualize the explainability of the invasion status classification. Results The CNN model’s diagnostic accuracy was 0.973, significantly higher than those of the two radiologists (SR: 0.838; JR: 0.595). Receiver operating characteristic curve analysis gave an area under the curve of 0.953 for the CNN model (versus 0.832 and 0.617 for SR and JR; both p < 0.05). The Grad-CAMs suggested that the invasion-negative cases were present predominantly in bone marrow, while the invasion-positive cases exhibited osteosclerosis and nasopharyngeal masses. Conclusions This CNN technique would be useful for CT-based diagnosis of skull-base invasion by nasopharyngeal malignancies.

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Section: Methodsmentioning

confidence: 99%

Diagnosis of skull-base invasion by nasopharyngeal tumors on CT with a deep-learning approach

Nakagawa,

Fujima,

Hirata

et al. 2024

Jpn J Radiol

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“…Artificial intelligence (AI) plays a fundamental role in the interpretation and processing of data from fMRI, providing sophisticated tools to analyze in depth the functioning of the human brain [12][13][14][15][16][17][18][19][20][21][22][23][24][25]. One high-impact area is advanced data analytics, where AI can identify complex patterns and correlations that would be difficult or impossible to identify manually [13,17,22].…”

Section: Integrating Fmri and Ai For The Brain Studymentioning

confidence: 99%

“…Furthermore, AI is essential for automating critical processes such as brain segmentation and mapping of brain regions [14,15]. This automation significantly speeds up the analysis process and ensures greater accuracy, allowing scientists to focus more on interpreting results rather than manipulating raw data [18,19,21]. Another powerful application is the prediction of brain responses to certain stimuli or tasks based on historical fMRI data [23].…”

Section: Integrating Fmri and Ai For The Brain Studymentioning

confidence: 99%

An Umbrella Review of the Fusion of fMRI and AI in Autism

Giansanti

2023

Diagnostics

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The role of functional magnetic resonance imaging (fMRI) is assuming an increasingly central role in autism diagnosis. The integration of Artificial Intelligence (AI) into the realm of applications further contributes to its development. This study’s objective is to analyze emerging themes in this domain through an umbrella review, encompassing systematic reviews. The research methodology was based on a structured process for conducting a literature narrative review, using an umbrella review in PubMed and Scopus. Rigorous criteria, a standard checklist, and a qualification process were meticulously applied. The findings include 20 systematic reviews that underscore key themes in autism research, particularly emphasizing the significance of technological integration, including the pivotal roles of fMRI and AI. This study also highlights the enigmatic role of oxytocin. While acknowledging the immense potential in this field, the outcome does not evade acknowledging the significant challenges and limitations. Intriguingly, there is a growing emphasis on research and innovation in AI, whereas aspects related to the integration of healthcare processes, such as regulation, acceptance, informed consent, and data security, receive comparatively less attention. Additionally, the integration of these findings into Personalized Medicine (PM) represents a promising yet relatively unexplored area within autism research. This study concludes by encouraging scholars to focus on the critical themes of health domain integration, vital for the routine implementation of these applications.

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“…Artificial intelligence (AI) methods, particularly deep learning models, have brought about ultrasound imaging by automating image processing and enabling the automated diagnosis of disease and detection of abnormalities. Convolutional neural networks (CNNs) have played a vital role in this transformation, demonstrating improvements in various medical imaging modalities [ 4 , 5 , 6 , 7 , 8 , 9 ]. However, the limitations of CNNs in capturing long-range dependencies and contextual information led to the development of vision transformers (ViTs) [ 10 ] in image processing.…”

Section: Introductionmentioning

confidence: 99%

Ultrasound Image Analysis with Vision Transformers—Review

Vafaeezadeh,

Behnam,

Gifani

2024

Diagnostics

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Ultrasound (US) has become a widely used imaging modality in clinical practice, characterized by its rapidly evolving technology, advantages, and unique challenges, such as a low imaging quality and high variability. There is a need to develop advanced automatic US image analysis methods to enhance its diagnostic accuracy and objectivity. Vision transformers, a recent innovation in machine learning, have demonstrated significant potential in various research fields, including general image analysis and computer vision, due to their capacity to process large datasets and learn complex patterns. Their suitability for automatic US image analysis tasks, such as classification, detection, and segmentation, has been recognized. This review provides an introduction to vision transformers and discusses their applications in specific US image analysis tasks, while also addressing the open challenges and potential future trends in their application in medical US image analysis. Vision transformers have shown promise in enhancing the accuracy and efficiency of ultrasound image analysis and are expected to play an increasingly important role in the diagnosis and treatment of medical conditions using ultrasound imaging as technology progresses.

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Recent Advances in Explainable Artificial Intelligence for Magnetic Resonance Imaging

Cited by 16 publications

References 105 publications

Diagnosis of skull-base invasion by nasopharyngeal tumors on CT with a deep-learning approach

Diagnosis of skull-base invasion by nasopharyngeal tumors on CT with a deep-learning approach

An Umbrella Review of the Fusion of fMRI and AI in Autism

Ultrasound Image Analysis with Vision Transformers—Review

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