Towards Deep Learning Guided Autonomous Eye Surgery Using Microscope and iOCT Images

TL;DR

This paper presents a real-time autonomous eye surgery system integrating microscope and iOCT imaging, CNN-based detection, and MPC control, demonstrated through successful pig eye subretinal injections with high accuracy and safety.

Contribution

It introduces a unified framework combining microscope and iOCT for real-time autonomous retinal surgery using CNNs and MPC, advancing surgical autonomy and safety.

Findings

30 successful subretinal injections on pig eyes

Average needle accuracy of 26 micrometers

Reduced procedure duration to 55 seconds

Abstract

Recent advancements in retinal surgery have paved the way for a modern operating room equipped with a surgical robot, a microscope, and intraoperative optical coherence tomography (iOCT)- a depth sensor widely used in retinal surgery. Integrating these tools raises the fundamental question of how to effectively combine them to enable surgical autonomy. In this work, we tackle this question by developing a unified framework that facilitates real-time autonomous surgical workflows leveraging these devices. The system features: (1) a novel imaging system that integrates the microscope and iOCT in real-time by dynamically tracking the surgical instrument via a small iOCT scanning region, providing real-time depth feedback; (2) implementation of convolutional neural networks (CNN) that automatically detect and segment task-relevant information for surgical autonomy; (3) intuitive selection of goal waypoints within both the microscope and iOCT views through simple mouse-click interactions; and (4) integration of model predictive control (MPC) for trajectory generation, ensuring patient safety by implementing safety-related kinematic constraints. The system's utility is demonstrated by automating subretinal injection (SI), a challenging procedure with high accuracy and depth perception requirements. We validate our system by conducting 30 successful SI trials on pig eyes, achieving mean needle insertion accuracy of 26 micrometers to various subretinal goals and mean duration of 55 seconds. Preliminary comparisons to a human operator performing SI in robot-assisted mode highlight the enhanced safety of our system. Project website is here: https://sites.google.com/view/eyesurgerymicroscopeoct/home