AI-driven Decision Support Systems for Clinical Diagnosis
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Keywords

AI-driven decision support systems (AI-CDSS)
artificial intelligence (AI)
machine learning (ML)
clinical diagnosis
medical imaging analysis
natural language processing (NLP)
personalized medicine
ethical considerations in AI
explainable AI (XAI)
real-time patient monitoring

How to Cite

[1]
D. F. Z. Zaidan, “AI-driven Decision Support Systems for Clinical Diagnosis: Develops AI-driven decision support systems to aid clinicians in making accurate diagnoses”, Journal of Bioinformatics and Artificial Intelligence, vol. 4, no. 1, pp. 84–95, Jun. 2024, Accessed: Nov. 23, 2024. [Online]. Available: https://biotechjournal.org/index.php/jbai/article/view/18

Abstract

The ever-growing complexity of medical knowledge and the vast amount of patient data pose significant challenges for clinicians in achieving accurate and timely diagnoses. AI-driven decision support systems (AI-CDSS) have emerged as a promising solution, offering the potential to revolutionize clinical diagnosis by leveraging the power of artificial intelligence (AI). This research paper delves into the development and application of AI-CDSS for enhancing diagnostic accuracy and improving patient outcomes.

The paper begins by outlining the limitations of traditional diagnostic methods, highlighting the subjectivity inherent in human decision-making and the potential for information overload. It then explores the fundamental concepts of AI and machine learning (ML) algorithms, particularly focusing on their ability to analyze large datasets and identify complex patterns in patient data. This section details various AI techniques employed in AI-CDSS, including deep learning for image analysis, natural language processing (NLP) for extracting insights from medical records, and decision trees for formulating diagnostic recommendations.

The core of the paper examines the diverse applications of AI-CDSS across various medical disciplines. It discusses how AI algorithms can assist in analyzing medical images like X-rays, MRIs, and histopathology slides, leading to earlier and more precise diagnoses of diseases such as cancer and neurological disorders. The paper further explores the use of AI-CDSS in analyzing patient medical histories, identifying potential risk factors, and suggesting appropriate diagnostic tests. Additionally, it highlights the potential of AI-CDSS in personalized medicine, tailoring diagnostic approaches based on individual patient characteristics and genetic information.

The paper acknowledges the ethical considerations surrounding the integration of AI into clinical decision-making. Issues such as bias in training data, interpretability of AI models, and potential job displacement for healthcare professionals are addressed. Strategies for mitigating these concerns, including ensuring data fairness, promoting model transparency, and fostering human-AI collaboration in diagnosis, are discussed.

The research paper concludes by emphasizing the immense potential of AI-CDSS in transforming clinical diagnosis. It underscores the need for continued research and development to refine AI algorithms, optimize their integration into clinical workflows, and ensure responsible implementation. The paper concludes by outlining future directions in this field, including the exploration of explainable AI (XAI) for fostering trust in AI decision-making, and the development of AI-powered tools for real-time patient monitoring and early disease detection.

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