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  5. Regulatory Evaluation of New Artificial Intelligence (AI) Uses for Improving and Automating Medical Practices
  1. Medical Device Regulatory Science Research Programs Conducted by OSEL

Regulatory Evaluation of New Artificial Intelligence (AI) Uses for Improving and Automating Medical Practices

Overview

The FDA’s Center for Devices and Radiological Health (CDRH) has a clear regulatory approach for many types of artificial intelligence (AI)-enabled devices, but new clinical indications or new types of AI require novel assessment paradigms (for both non-clinical and clinical testing) to determine safety and effectiveness. AI models intended for rule-out and triage have different practical applications and regulatory implications compared with models intended to help clinicians improve their diagnostic accuracy. Although most AI-enabled devices currently on the market are diagnostic, new devices that are designed for prognosis, treatment response prediction, risk assessment, therapy, improved image acquisition, and multi-class classification require different assessment metrics and reference standards. 

The use of natural language processing and large language models in the development or the operation of medical devices gives rise to new questions in device assessment. New types of AI that combine multiple types of data sources (for example, data from radiology, physiology, pathology, patient demographics, and electronic health record) demand research on questions about data harmonization and missingness. 

Projects

  • Assessment of Video-based Detection AI for Endoscopy
  • Validate a Computer Aided Triage Device (CADt) Time-saving Evaluation Tool (QuCAD) in a Clinical Workflow with Multiple CADt Devices and/or Disease Conditions
  • Multi-omics Prediction of Metastatic Breast Cancer Progression and Drug Response
  • Evaluating Large Language Models in the Generation of Radiology Reports 
A summary plot showing time-saving and diagnostic performance of a CADt device with a hypothetical ROC curve (gray dashed line on the color map).
A summary plot showing time-saving and diagnostic performance of a CADt device with a hypothetical ROC curve (gray dashed line on the color map). The dotted lines indicate the true and false positive rates at the operating point of the device (gray star). The color scale shows the amount of time saved for patients with the time-sensitive condition. The timesaving along the ROC curve is plotted as functions of true and false positive rates in the left and top-most plots. Take large vessel occlusion (LVO) stroke as an example, if 3.9% of stroke patients have less disability for every 15 minutes faster, the timesaving color axis can be mapped to LVO stroke patient outcome metrics (right axes). At the operating point (gray star), the expected time savings is about 40 minutes. This corresponds to roughly 11% increase in the number of stroke patients with better outcome.

Resources

For more information, email OSEL_AI@fda.hhs.gov.

 

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