Abstract
MS stands as a persistent autoimmune condition impacting the central nervous system, leading to inflammation and the loss of myelin. Early and accurate diagnosis of MS is crucial for initiating timely medication and refining patient results. Deep learning, a branch of artificial intelligence, has displayed significant promise across a range of medical uses, encompassing the identification and prognosis of MS. This research aims to delve into the difficulties and prospects surrounding the application of deep learning methods to promptly detect MS. The study delves into the existing scenario of MS diagnosis and the confines of conventional approaches. It delves into the capacity of deep learning algorithms, specifically convolutional neural networks (CNNs), in scrutinizing medical imagery like magnetic resonance imaging (MRI) to pinpoint distinctive MS-related structures and characteristics that might signal the initial stages of the disease. The challenges encountered in leveraging deep learning for MS diagnosis are discussed, including the need for large annotated datasets, the interpretability of deep learning models, and the synthesis of multimodal data sources. The study also addresses concerns related to the generalizability and robustness of deep learning models when applied to diverse patient populations and imaging protocols. Furthermore, the study highlights the opportunities and advancements in deep learning approaches for MS detection, such as transfer learning, data augmentation, and ensemble methods. Additionally, this study discusses the potential clinical implications of deep learning-based MS diagnosis, including the potential for improved early intervention, personalized treatment plans, and monitoring disease progression. Overall, this research contributes to a comprehensive understanding of the challenges and opportunities in utilizing deep learning for the early detection of MS. The results of this study could open doors to creating better diagnostic tools that are both precise and effective, resulting in enhanced patient outcomes and progress in the field of diagnosing and treating multiple sclerosis.
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Mohammed Aarif, K.O., Afroj Alam, Pakruddin, Riyazulla Rahman, J. (2024). Exploring Challenges and Opportunities for the Early Detection of Multiple Sclerosis Using Deep Learning. In: Raza, K., Singh, S. (eds) Artificial Intelligence and Autoimmune Diseases. Studies in Computational Intelligence, vol 1133. Springer, Singapore. https://doi.org/10.1007/978-981-99-9029-0_8
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