日本和台灣醫療人工智慧治理和給付框架的比較研究

中島穂積; Hozumi Nakashima

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102119

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	李達宇	zh_TW
dc.contributor.advisor	JOHN TAYU LEE	en
dc.contributor.author	中島穂積	zh_TW
dc.contributor.author	Hozumi Nakashima	en
dc.date.accessioned	2026-03-13T16:35:17Z	-
dc.date.available	2026-03-14	-
dc.date.copyright	2026-03-13	-
dc.date.issued	2026	-
dc.date.submitted	2026-02-05	-
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Retrieved November 15, 2025, from https://www.hst.org.tw/ 工研院產科國際所. (2025, June 2). Center for Clinical AI Impact Evaluation. Retrieved November 15, 2025, from https://aicenter.mohw.gov.tw/AC/cp-7295-82668-208.html 台灣聯合學習醫療聯盟啟動. (n.d.). Retrieved November 15, 2025, from https://ailabs.tw/news-room/healthcare-201104/ 投資臺灣入口網 Invest Taiwan_產業消息臺灣數位醫療產業發展現況及趨勢. (2025, April 25). Retrieved November 15, 2025, from https://investtaiwan.nat.gov.tw/intelInfoPageCht202504250001jpn?lang=jpn&search=202504250001 標題:【轉載】衛生福利部三大AI中心啟動記者會 (2024). Retrieved November 15, 2025, from https://wwwv.tsgh.ndmctsgh.edu.tw/news/191/102550/33730/12371 經濟部産業技術司. 台灣AI 智慧醫療新紀元關鍵趨勢. (n.d.) 臺灣長期照顧實作指引 (Taiwan Long-Term Care Implementation Guide) v0.4.0. (n.d.). Retrieved November 15, 2025, from https://ltc-ig.fhir.tw/	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102119	-
dc.description.abstract	全球衛生系統正面臨人口快速老化、慢性病負擔加重和醫療支出不斷攀升帶來的日益嚴峻的壓力。這些結構性挑戰在日本和台灣尤為突出，這兩個地區必須在勞動力萎縮和醫療服務需求不斷增長的情況下維持全民健康覆蓋。在此背景下，人工智慧（AI）和醫療器材軟體（SaMD）已成為提高效率、改善臨床品質和支援永續醫療服務的重要工具。然而，兩國在人工智慧醫療技術的監管、審批和報銷方面存在顯著差異。本研究對日本和台灣的醫療人工智慧和醫療器材軟體的治理結構、監管框架、資料基礎設施和報銷機制進行了比較分析。透過對政策文件、政府指南、學術文獻和機構報告進行基於文件的定性回顧，本研究考察了兩國如何管理人工智慧的生命週期——從開發和驗證到實施和上市後監管。本研究重點在於制度化程度、資料標準化、衛生技術評估（HTA）整合以及與HL7 FHIR、GA4GH和歐盟人工智慧法案等國際標準的契合度。研究結果揭示了根本性的結構差異。台灣採用集中式、國家主導的治理模式，並擁有完善的製度安排，包括國家級GPU集群、強制採用FHIR標準、聯邦學習基礎設施、臨床人工智慧驗證中心以及專門負責公平性、透明度和生命週期監控的治理機構。相較之下，日本則依賴以自願性指南為核心、資料系統分散且依賴機構的治理實踐的去中心化模式。儘管日本透過《藥品和醫療器材法案》（PMD Act）和IDATEN系統展現了卓越的技術實力和健全的監管審查機制，但資料互通性、外部驗證和上市後監控方面的局限性阻礙了其在全國範圍內的推廣應用。總之，台灣的基礎設施-治理整合模式為安全、公平且可擴展的人工智慧實施提供了堅實的政策基礎。日本可能需要進一步優先考慮資料標準的製度化、加強外部驗證、開發國家一體化資料平台以及完善生命週期治理，以更好地支援安全有效的AI部署。	zh_TW
dc.description.abstract	Health systems worldwide face mounting pressures from rapid population aging, increasing chronic disease burdens, and escalating medical expenditures. These structural challenges are particularly acute in Japan and Taiwan, where universal health coverage must be sustained despite shrinking workforces and rising demand for medical services. Against this backdrop, artificial intelligence (AI) and Software as a Medical Device (SaMD) have emerged as essential tools for enhancing efficiency, improving clinical quality, and supporting sustainable healthcare delivery. However, the pathways through which AI-enabled medical technologies are governed, approved, and reimbursed differ substantially between the two countries. This study conducts a comparative analysis of Japan and Taiwan’s governance structures, regulatory frameworks, data infrastructures, and reimbursement mechanisms for healthcare AI and SaMD. Using a document-based qualitative review of policy papers, governmental guidelines, academic literature, and institutional reports, the study examines how each country manages the AI lifecycle—from development and validation to implementation and post-market oversight. Particular focus is placed on the degree of institutionalization, data standardization, HTA integration, and alignment with international standards such as HL7 FHIR, GA4GH, and the EU AI Act. The findings reveal a fundamental structural divergence. Taiwan employs a centralized, state-led governance model with strong institutional arrangements, including national GPU clusters, mandatory FHIR adoption, federated learning infrastructure, clinical AI validation centers, and dedicated governance bodies for fairness, transparency, and lifecycle monitoring. In contrast, Japan relies on a decentralized model centered on voluntary guidelines, fragmented data systems, and institution-dependent governance practices. While Japan demonstrates technological excellence and robust regulatory review via the PMD Act and IDATEN system, limitations in data interoperability, external validation, and post-market monitoring impede nationwide scalability. In conclusion, Taiwan’s integrated infrastructure–governance model provides a strong policy foundation for safe, equitable, and scalable AI implementation. Japan may need to further prioritize the institutionalization of data standards, enhancement of external validation, development of integrated national data platforms, and refinement of lifecycle governance to better support safe and effective AI deployment.	en
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dc.description.tableofcontents	Table of Contents Master’s thesis / doctoral dissertation acceptance certificate Acknowledgement ⅰ 中文摘要 ⅱ Abstract ⅲ Table of Content ⅴ List of Figures ⅶ List of Tables ⅶ 1. INTRODUCTION 1 1.1. Modern medicine is under pressure to change. 1 1.2. Definition and Key Technologies of AI in Medicine 3 1.3. Innovation in clinical practice through AI 6 1.4. The impact of AI on medical research and operations. 11 1.5. Challenges, ethical considerations, and future prospects 12 2. A NEW PARADIGM: SOFTWARE AS A MEDICAL DEVICE (SAMD) 15 2.1. Definition of Software as a Medical Device (SaMD) 15 2.2. Shift from hardware-centric to software-centric. 15 2.3. AI and SaMD: The birth of intelligent medical devices 17 2.4. Impact on clinical practice 18 2.5. Global Rise and Background of SaMD - Global Factors Driving Rapid Market Growth 19 2.6. Global market trends 20 3. WHY IS RISK CLASSIFICATION NECESSARY? THE IMDRF FRAMEWORK 21 3.1. The importance of a risk-based approach in SaMD 21 3.2. Two dimensions that determine risk. 21 3.3. Risk Classification Matrix 22 3.4. Specific examples by risk category 23 4. SAMD MARKETING APPROVAL PROCESS – GETTING THROUGH THE REGULATORY GATES 27 4.1. Objectives and principles of marketing authorization 27 4.2. Major Marketing Approval Pathways: The US FDA Example 27 4.3. The concept and role of health technology assessment (HTA) 29 4.4. The role of HTA in the SaMD life cycle 31 5. JAPAN'S POLICY AND REGULATORY FRAMEWORK FOR ARTIFICIAL INTELLIGENCE IN HEALTHCARE 34 5.1. Background and motivation 34 5.2. Policy Background and National Strategy 35 5.3. Regulatory Framework for AI in Healthcare 37 5.4. Approval and Evaluation Process 40 5.5. Comparison of AI medical infrastructure and governance between Japan and Taiwan 51 5.6. Reimbursement and Economic Evaluation 76 5.7. Data Governance and Digital Infrastructure 87 5.8. Public-Private Partnerships and Innovation Ecosystems 106 5.9. Issues and future directions 114 6. JAPAN'S UNIQUENESS – INTEGRATING INTERNATIONAL STANDARDS AND DOMESTIC SYSTEMS 118 6.1. Basic structure of the Japanese model 118 6.2. Similarities in approval processes and differences in reimbursement processes (comparison between countries) 119 7. CHALLENGES FACING AI-SAMD REIMBURSEMENT IN JAPAN 130 7.1. Structural issue: Mismatch with the piecework payment system 130 7.2. Hurdles to building evidence and lack of predictability 131 7.3. Comparison with Taiwan: Concerns shared by both countries with universal health insurance systems 132 8. JAPAN'S POLICY RECOMMENDATIONS – TO PROMOTE INNOVATION 134 8.4. Policy recommendations 134 9. Conclusion: Comparative Study of Japan and Taiwan 137 10. REFLECTION 142 11. REFERENCES 146	-
dc.language.iso	en	-
dc.subject	人工智慧、基於AI的醫療技術、醫療器材軟體、SaMD、治理、報銷、日本、台灣	-
dc.subject	Artificial Intelligence, AI-based medical technologies, Software as a Medical Device, SaMD, Governance, Reimbursement, Japan, Taiwan	-
dc.title	日本和台灣醫療人工智慧治理和給付框架的比較研究	zh_TW
dc.title	Comparative Governance and Reimbursement Framework of Healthcare Artificial Intelligence (AI) in Japan and Taiwan	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	楊銘欽;郭年真;早乙女　周子	zh_TW
dc.contributor.oralexamcommittee	MING-CHIN YANG;Raymond N. Kuo;Chikako Saotome	en
dc.subject.keyword	人工智慧、基於AI的醫療技術、醫療器材軟體、SaMD、治理、報銷、日本、台灣,	zh_TW
dc.subject.keyword	Artificial Intelligence, AI-based medical technologies, Software as a Medical Device, SaMD, Governance, Reimbursement, Japan, Taiwan,	en
dc.relation.page	154	-
dc.identifier.doi	10.6342/NTU202600679	-
dc.rights.note	同意授權(限校園內公開)	-
dc.date.accepted	2026-02-06	-
dc.contributor.author-college	公共衛生學院	-
dc.contributor.author-dept	公共衛生碩士學位學程	-
dc.date.embargo-lift	2026-03-14	-
顯示於系所單位：	公共衛生碩士學位學程

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