Guiding Policymakers Toward Better AI Ethics Integration in Healthcare Regulation—Lessons from Singapore
Abstract
1. Introduction
2. Analysis
3. Recommendations
3.1. Involve Patient Perspectives in the Development and Implementation of AI in Health
3.2. Indicate That AI-Based Tools May Be Evaluated Based on Their Justifiability If They Are Not Explainable
3.3. Developers and Implementers Should, Depending on the Context of Use, Warn Users Against the Tendency to Anthropomorphize AI-Based Tools
3.4. Provide Guiding Tools for Ethical Analysis of Proportionality in Data Collection and Making Ethical Trade-Offs in General
3.5. Publish Approved AI/ML-Enabled Devices for Medical Use
3.6. Extend Personal Data Protection Beyond Identified Data
3.7. Clarify the Distribution of Liability Between Healthcare Professionals, Implementers and Developers
3.8. Clarify How Implementers Should Deliberate the Appropriate Amount of Human Oversight of AI Appropriate by Weighing Risks and Benefits of Full Automation
3.9. Require Calibration of Tools to Be Culturally Sensitive
3.10. Clarify When and How, If Ever, Professionals May Still Use a Biased AI
3.11. Clarify the Scope of Patient Rights in Relation to the Use of AI-Based Tools
3.12. Guiding Documents Regarding the Doctor–Patient Relationship on Their Rights and/or Duties with Respect to AI Use in Healthcare
3.13. Account for the Risks of Automation or Technology Bias
3.14. Clarify the Suitable Level of Critical Review by Professionals on AI Outputs to Avoid Deskilling
4. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A. Definitions for Key Stakeholder Groups
Appendix B
Common Ethical Themes
| Common Gaps
|
Appendix C. List of 9 Documents
- HSA Regulatory Guidelines for Software Medical Devices—A Life Cycle Approach. This document provides guidance on managing software medical devices throughout their life cycle, from design and development to post-market surveillance. The guidelines emphasize the importance of ensuring the safety, performance, and cybersecurity of software medical devices, including AI-based Medical Devices (AI-MDs). It is relevant to stakeholders who are involved in software medical device development and/or supplying such devices in Singapore, mainly developers and implementers.
- MOH Artificial Intelligence in Healthcare Guidelines (AIHGle). AIHGle accompanies the HSA Health Products Act and its subsidiary legislation and guidance documents. It provides a set of good practices for developers and implementers involved with AI in healthcare. The primary aim is to improve clinical and public trust in AI by encouraging the safe development and implementation of primarily AI-MDs and other AI applications. It is relevant to developers and implementers.
- Regulatory Guidelines for Telehealth Products. This document provides regulatory guidance for telehealth products classified as medical devices, including mobile apps. It follows two approaches: risk-based regulation and confidence-based regulation to ensure safe and efficient delivery of the products. It is relevant to developers and implementers.
- ACE Overview for New and Emerging Technologies. This document is a rapid overview by the ACE (Agency for Care Effectiveness), summarizing the current state, clinical applications, regulatory considerations, and implementation challenges of AI in healthcare, specifically within the context of Singapore. This document only comments on the above topics and cannot in itself be used to guide or regulate professionals. It does, however, point out gaps in existing regulations and guidelines on ethical considerations related to the use of AI in healthcare. Thus, this document informs the identification of such gaps in our analysis.
- SMC Ethical Code and Ethical Guidelines (2002 and 2016 editions) and Handbook on Medical Ethics (2016 edition). Developed by the Singapore Medical Council, this set of documents presents the fundamental tenets of medical ethics that inform the standards of professional conduct for doctors in Singapore. It is relevant for Individuals (healthcare professionals).
- SDC Ethical Code and Ethical Guidelines (updated 2019). This document captures the set of ethical codes and guidelines for dentists. Relevant to the Individuals (healthcare professionals) group.
- Allied Healthcare Professionals Code of Professional Conduct. This document captures the set of ethical codes and guidelines for allied healthcare professionals in Singapore. It is relevant to the Individuals (healthcare professionals) group.
- SPC Code of Ethics. This document captures the set of ethical codes and guidelines for pharmacists in Singapore. It is relevant to the Individuals (healthcare professionals) group.
- Nurses and Midwives Code. This document captures the set of ethical codes and guidelines for nurses and midwives in Singapore. It is relevant to the Individuals (healthcare professionals) group.
Appendix D
International Comparison of Key Regulatory AI Frameworks
| Jurisdiction | Key Regulatory Frameworks | Ethical Considerations |
| USA | Food and Drug Administration (FDA) oversees AI/ML-based medical devices under the Software as a Medical Device (SaMD) framework. The 2021 Action Plan includes a lifecycle approach. Other guiding documents include the Blueprint for Trustworthy AI and Good Machine Learning Practice. The AI Bill of Rights also explains the roles and rights of the public, including patients. | Fairness, transparency, and managing risks of bias in AI development. Trustworthiness and explainability emphasized. |
| UK | SaMD is regulated by the Medicines and Healthcare products Regulatory Agency (MHRA). The Software and AI as a Medical Device Change Program in 2021 addresses post-market evaluation. The MHRA roadmap in 2022 also covers manufacturer vigilance. | Focus on patient safety, reducing bias, explainability, and ensuring transparency throughout the AI lifecycle. |
| EU | EU AI Act (2024) [8] introduced a risk-based classification with stringent regulations for high-risk systems, such as AI in healthcare, requiring conformity assessments, human oversight, and transparency. It also mandates registration of high-risk systems for public transparency, and sets strict rules for general purpose AI. | Emphasize fairness, non-discrimination, and privacy protection. Strong focus on transparency, human oversight, and bias reduction in healthcare applications. |
| Australia | The Therapeutic Goods Administration regulates SaMDs with a risk-based approach. Safe and Responsible AI in Healthcare Legislation and Regulation Review was launched in September 2024 for this purpose. | Emphasize minimizing bias, ensuring reliability, and maintaining safety in AI healthcare applications. |
| China | The National Medical Products Administration oversees AI with a focus on lifecycle management, cybersecurity, and risk factors. There are stricter regulations for AI in healthcare. | Concerns around transparency, data security, managing algorithmic bias, and ensuring explainability. |
| Brazil | Draft AI Law classifies healthcare AI as high-risk, requiring impact assessments and strict liability for AI damages. | Ethical considerations include accountability, transparency, and ensuring patient safety in high-risk systems. |
| Japan | SaMD are regulated by Pharmaceuticals and Medical Devices Act, Guidelines on the Applicability of Programs as Medical Devices, Digital Transformation Action Strategies in Healthcare for SaMD, and Next Generation Medical Infrastructure Act. | Focus on safety, accountability, reducing bias, ensuring trust and data privacy while keeping up with the updates of the devices. |
| Singapore | AI is regulated under the SaMD framework. The AIHGle guidelines emphasize good practices for developers and implementers, including quality management. Various other documents, such as the PDPA, may have implications for AI in healthcare but do not directly address AI in healthcare. | Focus on patient-centricity, transparency, reducing bias, and ensuring trust and accountability. |
Appendix E
| Recommendation | Priority | Cost | Implementation Feasibility | Who Has Authority | Risk of Legal Incompatibility | Note on Implementation Beyond Singapore |
|---|---|---|---|---|---|---|
| Involve patient perspectives in the development and implementation of AI in health | High | Medium | Variable: feasible for developers with established Voice of the Customer teams, and for projects backed by the government with established public engagement avenues, less so for those without. | Developers and implementers may take charge; regulators may set up guidelines (though not hard laws) to incentivize patient-centric AI. | Low | Regulators may account for the presence/absence and quality of public/patient engagement when assessing AI medical device or software for approval. However, jurisdictions may adopt a laissez-faire approach to AI at their own discretion (this holds for all subsequent recommendations). |
| Indicate that AI-based tools may be evaluated based on their justifiability if they are not explainable | Low | Low | High | Regulators | Low | Regulators may include statements to such effect in their AI policy documents. |
| Developers and implementers should, depending on the context of use, warn users against the tendency to anthropomorphize AI-based tools | Medium | Low | High | Developers and implementers | Low | Regulators may include statements to such effect in their AI policy documents. |
| Provide guiding tools for ethical analysis of proportionality in data collection and making ethical trade-offs in general | Medium | Low | Variable: users need training to conduct ethical analysis effectively. This is feasible for states with established ethics training infrastructure for medical and allied health professionals like Singapore, but less so for those without. | The state needs to standardize such tools if centralized ethics training is provided; otherwise, implementers like hospitals and clinics may take charge | Low | Regulators in low-resource settings may tolerate some inconsistency in ethical capacity across medical institutions by, for instance, requiring ethical accreditation for higher-tier hospitals. |
| Publish approved AI/ML enabled devices for medical use | Low | Low | Variable: feasible for regulators with close oversight of medical devices, less so for the more laissez-faire regulators. | Regulators | Low | - |
| Extend personal data protection beyond identified data | High | Low | Variable: data custodians and ethics review board members need training to be informed about the risk of re-identification with AI tools. This is feasible for states with established clinical and research ethics training infrastructure, but less so for those without. | Regulators | Low: privacy laws should have already accounted for potential technological advancements (e.g., the EU GDPR Recital 26 posits that assessment of data identifiability should account for “all the means reasonably likely to be used”, which should include the latest AI tools). | - |
| Clarify the distribution of liability between healthcare professionals, implementers and developers | High | Low | High | Regulators | Medium: existing laws may already lay out rules for liability attribution; regulators must avoid clashing with those laws. | Regulators may include statements to such effect in their AI policy documents and/or doctor/nurse/dentist ethical codes. |
| Clarify how implementers should deliberate the appropriate amount of human oversight of AI appropriate by weighing risks and benefits of full automation | Medium | Low | High | Regulators | Low | Regulators may include statements to such effect in their AI policy documents. |
| Require calibration of tools to be culturally sensitive | High | Medium | Variable: feasibility may be constrained by the (un)availability of relevant training data. | Developers and implementers may take charge; regulators may set up guidelines (though not hard laws) to incentivize culturally sensitive AI. | Low | Regulators may include statements to such effect in their AI policy documents. |
| Clarify when and how, if ever, professionals may still use a biased AI | Low | Low | High | Regulators | Low | Regulators may include statements to such effect in their AI policy documents and/or doctor/nurse/dentist ethical codes. |
| Clarify the scope of patient rights in relation to the use of AI-based tools | High | Low | High | Regulators | Low | Regulators may include statements to such effect in their AI policy documents. |
| Guiding documents regarding the doctor-patient relationship on their rights and/or duties with respect to AI use in healthcare | High | Low | High | Developers and implementers may take charge; regulators may make recommendations (though not hard laws). | Low | Regulators may include statements to such effect in their AI policy documents and/or doctor/nurse/dentist ethical codes. |
| Clarify the suitable level of critical review by professionals on AI outputs to avoid deskilling | High | Low | High | Developers and implementers may take charge; regulators may make recommendations (though not hard laws). | Low | Regulators may include statements to such effect in their AI policy documents and/or doctor/nurse/dentist ethical codes. |
Appendix F
Case Study 1: AI for Screening and Referrals for Diabetic Retinopathy (DLSDR)
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| Risk | Description |
|---|---|
| Effectiveness, Reliability, and Evaluation | While pharmaceuticals require strict evaluation via clinical trials, this is not always feasible or necessary for the evaluation of AI tools. Instead, assessment is needed in the context in which the AI is actually being deployed, which introduces risks surrounding how humans will use the tool in practice. |
| Justice, Inequality, Bias, Discrimination, and Fairness | Bias in the social context interacts with algorithmic and statistical bias in AI, risking the exacerbation of health disparities. |
| Privacy and Confidentiality | AI systems require big data and risk breaches of privacy and confidentiality, raising concerns regarding consent, anonymization, and proper data management. |
| Machine Paternalism and Respect for Autonomy | AI may risk undermining patient autonomy by making decisions without considering patients’ values. |
| Accommodating Value Pluralism and Disagreement | Diversity of patient values and preferences requires accommodating differing views without imposing any one approach over another. |
| Responsibility | In the event of errors or harm, ensuring accountability among developers, clinicians, and healthcare institutions is complex. |
| Trust | A relationship of trust should be upheld among all stakeholders in the deployment of an AI tool such that each party can rely on and feel confident in the system’s ethical use. |
| Need for Explanation and Justification | Explainable AI ensures clinicians and patients understand how decisions are made, fostering trust and informed consent, but explainability may not always be necessary. Instead, justification of AI decisions better serves to uphold patient well-being and autonomy. |
| Obsolescence, Dehumanization, and Deskilling | AI systems should seek to keep a level of human oversight such that there is not a loss of human interaction in care. Healthcare professionals should remain skilled in their craft and not be over-reliant on new technologies. |
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Share and Cite
Nord-Bronzyk, A.; Ng, B.; Lan, T.; Schaefer, G.O.; Takahashi, S. Guiding Policymakers Toward Better AI Ethics Integration in Healthcare Regulation—Lessons from Singapore. J. Clin. Med. 2026, 15, 3576. https://doi.org/10.3390/jcm15103576
Nord-Bronzyk A, Ng B, Lan T, Schaefer GO, Takahashi S. Guiding Policymakers Toward Better AI Ethics Integration in Healthcare Regulation—Lessons from Singapore. Journal of Clinical Medicine. 2026; 15(10):3576. https://doi.org/10.3390/jcm15103576
Chicago/Turabian StyleNord-Bronzyk, Alexa, Bryson Ng, Tianxiang Lan, G. Owen Schaefer, and Shizuko Takahashi. 2026. "Guiding Policymakers Toward Better AI Ethics Integration in Healthcare Regulation—Lessons from Singapore" Journal of Clinical Medicine 15, no. 10: 3576. https://doi.org/10.3390/jcm15103576
APA StyleNord-Bronzyk, A., Ng, B., Lan, T., Schaefer, G. O., & Takahashi, S. (2026). Guiding Policymakers Toward Better AI Ethics Integration in Healthcare Regulation—Lessons from Singapore. Journal of Clinical Medicine, 15(10), 3576. https://doi.org/10.3390/jcm15103576

