- About CTTC
- Invention Disclosure
- News & Events
- Tech Connect
- CTTC MUSE - Blog
- Driving Innovation Forward Newsletter
- Past CTTC Events
Robotic Platform for Transurethral Exploration and Intervention
This technology, developed in Vanderbilt University’s Advanced Robotics and Mechanism Applications Laboratory, uses a minimally invasive telerobotic platform to perform transurethral procedures, such as transurethral resection. This robotic device provides high levels of precision and dexterity that improve patient outcomes in transurethral procedures.
Challenges in Transurethral Procedures
• Visualization in the bladder is difficult with current technologies, and surface imaging is insufficient for locating the margins of tumors with underlying submucosal invasion
• Rigid tools that are currently used have trouble maintaining precision while following the complex curve of the bladder during resection
• Submillimetric precision is required during resection passes to avoid perforation of the bladder
The present robotic system consists of an actuation unit that not only manipulates a central stem that can be extended the length of the urethral channel and into the bladder but also precisely controls a dexterous arm which is inserted through the central stem. The dexterous arm is able to move with the degrees of freedom necessary to perform procedures along the curved walls of the bladder and provide instrumentation channels that allow surgeons to incorporate a variety of surgical tools, such as a camera system, a grasper, or a laser ablation system, suited for the procedure at hand.
Overview of transurethral intervention and surveillance. The instruments access the urinary bladder through the resectoscope, a long, tubular, channel.
This device is useful for a wide range of transurethral procedures, most importantly those involving urinary bladder cancer diagnosis and treatment. Bladder cancer accounts for 1 in every 20 cancer diagnoses and there are over 70,000 new cases each year. According to the National Cancer Institute, the expected number of newly diagnosed bladder cancer patients in 2012 was estimated at 73,510 with an estimated 14,880 associated bladder cancer deaths. Bladder cancer is the most costly cancer to treat per patient partly because of the high recurrence rates of tumors missed during surveillance, inaccurately resected tumors, or new tumor sites seeded during resection. Despite its prevalence and high cost, there are fewer therapies for bladder cancer than most other cancer types and diagnostic tools remain relatively inaccurate, leaving bladder cancer with an unacceptably high rate of recurrence and misdiagnosis. This technology fills this gaping hole in treatment of bladder cancer while also showing promise for future expansion into a wider range of transurethral procedures.
Unique Features and Competitive Advantages
• This robotic device provides the dexterity and precision necessary to operate effectively along the curvature of the bladder
• The dexterous arm is constructed so that several surgical tools can be used simultaneously reducing the time and complexity of a transurethral procedure
• The dexterous arm’s mobility enables visualization of the entire bladder wall, with the use of a camera system, allowing for more effective cancer diagnosis
• The robotic precision of this device allows the surgeon to completely remove a tumor by resection without perforating the bladder, greatly reducing the potential for recurrence
Intellectual Property and Product Development Status
PCT Application has been filed
Publication: Constrained Motion Control of Multisegment Continuum Robots for Transurethral Bladder Resection and Surveillance. Andrea Bajo, Ryan B. Pickens, S. Duke. Herrell, and Nabil Simaan, 2013 IEEE International Conference on Robotics and Automation (ICRA)Karlsruhe, Germany, May 6-10, 2013.
Roger E. Goldman, Andrea Bajo, Lara S. MacLachlan, Ryan Pickens, S. Duke Herrell, Nabil Simaan. Design and Performance Evaluation of a Minimally Invasive Telerobotic Platform for Transurethral Surveillance and Intervention. IEEE Transactions on Biomedical Engineering, 2013; 60 (4): 918
News: Telerobotic System Designed to Treat Bladder Cancer Better http://newsle.com/article/0/68056695/
Technology Video: Telerobotic system designed to treat bladder cancer. http://news.vanderbilt.edu/2013/04/telerobotic-bladder-cancer/
Inventor Bio and Publications: Vanderbilt University A.R.M.A. Lab: http://arma.vuse.vanderbilt.edu/
Inventors:Nabil SimaanRoger GoldmanAndrea BajoLaura SuhRyan PickensStanley Herrell