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System And Method For Automated Image Guided Robotic Intraocular Surgery

Technology Benefits

Automated surgical lens extraction only requires review and adjustment from surgeon  Real-time monitoring allows for assessment of lens removal  Robot-guided motion prevents inadvertent contact of tool to new artificial lens  Optical tomography is a non-contact and precise 3D imaging tool

Technology Application

Automated cataract removal

Detailed Technology Description

Professor Tsao and coworkers have developed a robotic surgical platform that incorporates optical tomography for autonomous cataract removal. Highly accurate 3D models are generated and used to automate cataract lens removal, with real-time monitoring and potential intervention by a supervising surgeon. Evaluation of progress can be achieved at regular intervals to ensure complete cataract removal and robot-guided motion prevents inadvertent contact of the tool tip to the artificial lens capsule, minimizing the most common surgical complications.

Others

State Of Development

Model has been developed and demonstrated using porcine eyes.

Background

More than 3.5 million cataract surgeries are performed every year in the United States, with the market estimated at over $7 billion in 2016. While many surgical steps of cataract surgery have been partially or fully automated, the critical step of cataract lens extraction remains a manual operation. This step is also associated with the most common complications of cataract surgery, which are incomplete lens removal and a tear in the capsule holding the new artificial lens. Automation of lens removal using visualization tools and allowing for real-time surgeon feedback would decrease these complications and significantly improve cataract outcomes.

Related Materials

J.T. Wilson, T.-C. Tsao, J.-P. Hubschman, and S. Schwartz, Evaluating remote centers of motion for minimally invasive surgical robots by computer vision, IEEE/ASME International Conference on Advanced Intelligent Mechatronics, 2010.
J. T. Wilson, M. J. Gerber, S. W. Prince, C.-W. Chen, S. D. Schwartz, J.-P. Hubschman, and T.-C. Tsao, Intraocular robotic interventional surgical system (IRISS): Mechanical design, evaluation, and master-slave manipulation, Int. J. Med. Robot. Comput. Assist. Surg. 2017.

Additional Technologies by these Inventors

• Robotic Microsurgery System
• Spark And Compression Ignition (SI-CI) Internal Combustion Engine
• Laser-Assisted Intraocular Surgical Alignment
• An MR-Compatible System for Motion Emulation
• Rapid And Precise Tool Exchange Mechanism For Intraocular Robotic Surgical Systems
• Docking System To Stabilize Eyeball During Intraocular Surgery
• Fully Actuated Propeller Mount Design For Unmanned Aerial Vehicles

Tech ID/UC Case

29436/2018-214-0

Related Cases

2018-214-0

*Abstract

UCLA researchers in the Departments of Mechanical Engineering and Ophthalmology have developed a system and method for automated optical surgery.

*Principal Investigator

Name: Cheng-Wei Chen

Department:

Name: Matthew Gerber

Department:

Name: Jean-Pierre Hubschman

Department:

Name: Yu-Hsiu Lee

Department:

Name: Tsu-Chin Tsao

Department:

Country/Region

USA