Researcher Thijs Meenink at TU/e has developed a smart eye-surgery robot that allows eye surgeons to operate with increased ease and greater precision on the retina and the vitreous humor of the eye. The system also extends the effective period during which ophthalmologists can carry out these intricate procedures. Meenink will defend his PhD thesis on Monday 31 October for his work on the robot, and intends later to commercialize his system.
Eye operations such as retina repairs or treating a detached retina demands high precision. In most cases surgeons can only carry out these operations for a limited part of their career. “When ophthalmologists start operating they are usually already at an advanced stage in their careers”, says Thijs Meenink. “But at a later age it becomes increasingly difficult to perform these intricate procedures.” The new system can simply filter-out hand tremors, which significantly increases the effective working period of the ophthalmologist.
Same location every time
The robot consists of a ‘master’ and a ‘slave’. The ophthalmologist remains fully in control, and operates from the master using two joysticks. This master was developed in an earlier PhD project at TU/e by dr.ir. Ron Hendrix. Two robot arms (the ‘slave’ developed by Meenink) copy the movements of the master and carry out the actual operation. The tiny needle-like instruments on the robot arms have a diameter of only 0.5 millimeter, and include forceps, surgical scissors and drains. The robot is designed such that the point at which the needle enters the eye is always at the same location, to prevent damage to the delicate eye structures.
Quick instrument change
Meenink has also designed a unique ‘instrument changer’ for the slave allowing the robot arms to change instruments, for example from forceps to scissors, within only a few seconds. This is an important factor in reducing the time taken by the procedure. Some eye operations can require as many as 40 instrument changes, which are normally a time consuming part of the overall procedure.
High precision movements
The surgeon’s movements are scaled-down, for example so that each centimeter of motion on the joystick is translated into a movement of only one millimeter at the tip of the instrument. “This greatly increases the precision of the movements”, says Meenink.
Haptic feedback The master also provides haptic feedback. Ophthalmologists currently work entirely by sight – the forces used in the operation are usually too small to be felt. However Meenink’s robot can ‘measure’ these tiny forces, which are then amplified and transmitted to the joysticks. This allows surgeons to feel the effects of their actions, which also contributes to the precision of the procedure.
The system developed by Meenink and Hendrix also offers ergonomic benefits. While surgeons currently are bent statically over the patient, they will soon be able to operate the robot from a comfortable seated position. In addition, the slave is so compact and lightweight that operating room staff can easily carry it and attach it to the operating table.
New procedures Ophthalmologist prof.dr. Marc de Smet (AMC Amsterdam), one of Meenink’s PhD supervisors, is enthusiastic about the system – not only because of the time savings it offers, but also because in his view the limits of manual procedures have now been reached. “Robotic eye surgery is the next step in the evolution of microsurgery in ophthalmology, and will lead to the development of new and more precise procedures”, de Smet explains.
Both slave and master are ready for use, and Meenink intends to optimize them in the near future. He also plans to investigate the market opportunities for the robot system. Robotic eye surgery is a new development; eye surgery robots are not yet available on the market.
Ir. Thijs Meenink will defend his PhD thesis on Monday 31 October entitled ‘Vitreo-retinal eye surgery robot: sustainable precision’. His primary supervisor is prof.dr.ir. Maarten Steinbuch (TU/e). Ron Hendrix obtained his PhD on 31 March 2011 for his thesis entitled ‘Robotically assisted eye surgery: a haptic master control’. The project was partly funded by financial support from the IOP Precision Technology program of the Ministry of Economic Affairs, Agriculture and Innovation. The slave was developed with the help of the TU/e Equipment & Prototype Center, together with partners including TNO (Netherlands Organisation for Applied Scientific Research).
About Health at Eindhoven University of Technology
Eindhoven University of Technology (TU/e) is a research-driven, design-oriented university of technology with a strong international focus. The university was founded in 1956, and has around 7,200 students and 3000 staff. TU/e has defined strategic areas focusing on the societal challenges in Energy, Health and Smart Mobility. In the Health area, approximately 250 researchers are working on health technology across nine TU/e departments, and the Biomedical Engineering department is even dedicated to this subject. Health at TU/e covers the areas of Smart Environment, Smart Diagnosis and Smart Interventions. Some examples of developments at TU/e are the use of ultrasound and MRI for cancer detection and treatment, a baby-friendly jacket with invisible sensors to monitor premature babies, cultured heart valves and kidney tissue made from autologous cells, and minimally invasive robot surgery.
The Brainport Eindhoven region is the world’s smartest this year; it won the title Intelligent Community of the Year 2011 by the Intelligent Community Forum (ICF).