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Artificial Intelligence and Machine Learning Applied at the Point of Care.
Angehrn, Zuzanna; Haldna, Liina; Zandvliet, Anthe S; Gil Berglund, Eva; Zeeuw, Joost; Amzal, Billy; Cheung, S Y Amy; Polasek, Thomas M; Pfister, Marc; Kerbusch, Thomas; Heckman, Niedre M.
Afiliação
  • Angehrn Z; Certara, Princeton, NJ, United States.
  • Haldna L; Certara, Princeton, NJ, United States.
  • Zandvliet AS; Certara, Princeton, NJ, United States.
  • Gil Berglund E; Certara, Princeton, NJ, United States.
  • Zeeuw J; PacMed, Amsterdam, Netherlands.
  • Amzal B; Certara, Princeton, NJ, United States.
  • Cheung SYA; Certara, Princeton, NJ, United States.
  • Polasek TM; Certara, Princeton, NJ, United States.
  • Pfister M; Department of Clinical Pharmacology, Royal Adelaide Hospital, Adelaide, SA, Australia.
  • Kerbusch T; Centre for Medicines Use and Safety, Monash University, Melbourne, VIC, Australia.
  • Heckman NM; Certara, Princeton, NJ, United States.
Front Pharmacol ; 11: 759, 2020.
Article em En | MEDLINE | ID: mdl-32625083
INTRODUCTION: The increasing availability of healthcare data and rapid development of big data analytic methods has opened new avenues for use of Artificial Intelligence (AI)- and Machine Learning (ML)-based technology in medical practice. However, applications at the point of care are still scarce. OBJECTIVE: Review and discuss case studies to understand current capabilities for applying AI/ML in the healthcare setting, and regulatory requirements in the US, Europe and China. METHODS: A targeted narrative literature review of AI/ML based digital tools was performed. Scientific publications (identified in PubMed) and grey literature (identified on the websites of regulatory agencies) were reviewed and analyzed. RESULTS: From the regulatory perspective, AI/ML-based solutions can be considered medical devices (i.e., Software as Medical Device, SaMD). A case series of SaMD is presented. First, tools for monitoring and remote management of chronic diseases are presented. Second, imaging applications for diagnostic support are discussed. Finally, clinical decision support tools to facilitate the choice of treatment and precision dosing are reviewed. While tested and validated algorithms for precision dosing exist, their implementation at the point of care is limited, and their regulatory and commercialization pathway is not clear. Regulatory requirements depend on the level of risk associated with the use of the device in medical practice, and can be classified into administrative (manufacturing and quality control), software-related (design, specification, hazard analysis, architecture, traceability, software risk analysis, cybersecurity, etc.), clinical evidence (including patient perspectives in some cases), non-clinical evidence (dosing validation and biocompatibility/toxicology) and other, such as e.g. benefit-to-risk determination, risk assessment and mitigation. There generally is an alignment between the US and Europe. China additionally requires that the clinical evidence is applicable to the Chinese population and recommends that a third-party central laboratory evaluates the clinical trial results. CONCLUSIONS: The number of promising AI/ML-based technologies is increasing, but few have been implemented widely at the point of care. The need for external validation, implementation logistics, and data exchange and privacy remain the main obstacles.
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Texto completo: 1 Base de dados: MEDLINE Tipo de estudo: Clinical_trials / Prognostic_studies / Risk_factors_studies Idioma: En Ano de publicação: 2020 Tipo de documento: Article

Texto completo: 1 Base de dados: MEDLINE Tipo de estudo: Clinical_trials / Prognostic_studies / Risk_factors_studies Idioma: En Ano de publicação: 2020 Tipo de documento: Article