Ogut Eren
Department of Anatomy, Faculty of Medicine, Istanbul Medeniyet University, Istanbul 34700, Türkiye.
Clin Pract. 2025 Sep 16;15(9):169. doi: 10.3390/clinpract15090169.
The growing integration of artificial intelligence (AI) into clinical medicine has opened new possibilities for enhancing diagnostic accuracy, therapeutic decision-making, and biomedical innovation across several domains. This review is aimed to evaluate the clinical applications of AI across five key domains of medicine: diagnostic imaging, clinical decision support systems (CDSS), surgery, pathology, and drug discovery, highlighting achievements, limitations, and future directions. A comprehensive PubMed search was performed without language or publication date restrictions, combining Medical Subject Headings (MeSH) and free-text keywords for AI with domain-specific terms. The search yielded 2047 records, of which 243 duplicates were removed, leaving 1804 unique studies. After screening titles and abstracts, 1482 records were excluded due to irrelevance, preclinical scope, or lack of patient-level outcomes. Full-text review of 322 articles led to the exclusion of 172 studies (no clinical validation or outcomes, = 64; methodological studies, = 43; preclinical and in vitro-only, = 39; conference abstracts without peer-reviewed full text, = 26). Ultimately, 150 studies met inclusion criteria and were analyzed qualitatively. Data extraction focused on study context, AI technique, dataset characteristics, comparator benchmarks, and reported outcomes, such as diagnostic accuracy, area under the curve (AUC), efficiency, and clinical improvements. AI demonstrated strong performance in diagnostic imaging, achieving expert-level accuracy in tasks such as cancer detection (AUC up to 0.94). CDSS showed promise in predicting adverse events (sepsis, atrial fibrillation), though real-world outcome evidence was mixed. In surgery, AI enhanced intraoperative guidance and risk stratification. Pathology benefited from AI-assisted diagnosis and molecular inference from histology. AI also accelerated drug discovery through protein structure prediction and virtual screening. However, challenges included limited explainability, data bias, lack of prospective trials, and regulatory hurdles. AI is transforming clinical medicine, offering improved accuracy, efficiency, and discovery. Yet, its integration into routine care demands rigorous validation, ethical oversight, and human-AI collaboration. Continued interdisciplinary efforts will be essential to translate these innovations into safe and effective patient-centered care.
人工智能(AI)与临床医学的融合日益加深,为提高诊断准确性、治疗决策水平以及推动多个领域的生物医学创新开辟了新的可能性。本综述旨在评估人工智能在医学五个关键领域的临床应用:诊断成像、临床决策支持系统(CDSS)、手术、病理学和药物发现,突出其成就、局限性和未来发展方向。我们在PubMed上进行了全面检索,不受语言或出版日期限制,将医学主题词(MeSH)和人工智能的自由文本关键词与特定领域术语相结合。检索结果有2047条记录,其中243条重复记录被剔除,剩下1804项独特研究。在筛选标题和摘要后,1482条记录因不相关、临床前范围或缺乏患者层面的结果而被排除。对322篇文章进行全文审查后,又排除了172项研究(无临床验证或结果,=64;方法学研究,=43;临床前和仅体外研究,=39;无同行评审全文的会议摘要,=26)。最终,150项研究符合纳入标准并进行了定性分析。数据提取集中在研究背景、人工智能技术、数据集特征、比较基准以及报告的结果,如诊断准确性、曲线下面积(AUC)、效率和临床改善情况。人工智能在诊断成像方面表现出色,在癌症检测等任务中达到了专家级准确性(AUC高达0.94)。CDSS在预测不良事件(脓毒症、心房颤动)方面显示出前景,尽管实际结果证据不一。在手术中,人工智能增强了术中指导和风险分层。病理学受益于人工智能辅助诊断和组织学分子推断。人工智能还通过蛋白质结构预测和虚拟筛选加速了药物发现。然而,挑战包括可解释性有限、数据偏差、缺乏前瞻性试验以及监管障碍。人工智能正在改变临床医学,提高了准确性、效率和发现能力。然而,将其整合到常规医疗中需要严格的验证、伦理监督以及人机协作。持续的跨学科努力对于将这些创新转化为以患者为中心的安全有效护理至关重要。
