Intelligent Medical Imaging: Leveraging Artificial Intelligence for Precision Diagnosis
DOI:
https://doi.org/10.63282/3050-9246.IJETCSIT-V7I1P146Keywords:
Cognitive Aware Medical Imaging, AI Driven Medical Precision Diagnosis, Adaptive deep Learning for Medical Imaging, Hierarchical Cross Modality AttentionAbstract
The modern clinical diagnosis and disease monitoring have become impossible without medical imaging techniques like Magnetic Resonance Imaging (MRI), Computed Tomography (CT) and X-ray. The recent developments in Artificial Intelligence (AI) and especially deep learning have contributed greatly to the automated interpretation of complicated medical images. Although such developments have been made, current AI-based diagnostic systems have been characterized by crucial weaknesses, such as low cross-modality generalization, susceptibility to imaging noise and imaging artifact, as well as little insight into diagnostic judgments. These issues decrease the clinical trust and limit the wide adoption of AI systems in the practical healthcare setting. The rationale behind this study is to come up with a more dependable and smarter diagnostic model that can enhance the precision, strength, and elucidations of AI-run medical imaging models. This paper presents a new Cognitive-Aware Medical Imaging Architecture (CAMIA) that combines the dynamic context-aware learning of features with adaptive diagnostic reasoning. In contrast to traditional methods, the suggested framework proposes Self-Evolving Diagnostic Embedding’s (SEDE) which continually updates the feature representations with the help of multi-scale anatomical patterns. Also, the Hierarchical Cross-Modality Attention Mechanism (HCAM) is introduced to support the simultaneous analysis of heterogeneous imaging modalities. The main contributions of the study are the architecture of a fourth generation smart imaging system, the presentation of self-evolving feature models to adaptive diagnosis and effective cross-modality inference model that provides increased diagnostic accuracy. In experimental assessments, the suggested framework has been shown to have a substantial impact on the reliability of detection and the visibility of decisions made in multidimensional clinical imaging conditions.
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