First completely robot-supported microsurgical operations on humans

Dr. Maximilian Kückelhaus presents the new method in a dry-run training session. The operations robot (right) is networked with a robotic microscope (left).
WWU - Peter Leßmann

A great success for robotic microsurgery not only in Münster but worldwide. A team led by Dr. Maximilian Kückelhaus and Prof. Tobias Hirsch from the Centre for Musculoskeletal Medicine at the University of Münster has carried out the first completely robot-supported microsurgical operations on humans.

It is a great success for robotic microsurgery not only in Münster but worldwide – both for medicine and for science: a team led by scientists Dr. Maximilian Kückelhaus and Prof. Tobias Hirsch from the Centre for Musculoskeletal Medicine at the University of Münster has carried out the first completely robot-supported microsurgical operations on humans. The physicians used an innovative operating method in which a new type of operations robot, designed especially for microsurgery, is networked with a robotic microscope. This approach makes it possible for the operating surgeon to be completely taken out of the operating area. The use of robots for clinical research is undertaken in collaboration with Münster University Hospital and Hornheide Specialist Clinic.

The experts have been using this method for a good two months. So far, five operations have been successfully performed, with many more set to follow. “This new method for operations enables us to work with a much higher degree of delicacy and precision than is possible with conventional operating techniques,” says Maximilian Kückelhaus. “As a result, less tissue is destroyed and patients recover faster.” The specialists use the method for example on patients with breast cancer who need complex breast reconstructions, or after accidents in which patients need tissue transplants. With the aid of the robot and the robotic microscope, the microsurgeons can for example join up again the finest anatomical structures such as blood vessels, nerves or lymphatic vessels, which often have a diameter of only 0.3 millimetres.

During the operation, the robot – the so-called Symani Surgical System – adopts human hand movements via an electromagnetic field and joysticks. The robot carries out the operating surgeon’s movements, reduced in size by up to 20 times, via tiny instruments and, in doing so, completely eliminates any shaking present in (human) hands. A robotic microscope is connected to the operation robot, and this microscope shows the area being operated on via a so-called 3D Augmented Reality Headset with two high-resolution monitors. This headset contains a binoculars which are able to combine the real world with virtual information. In this way, the surgeon’s head movements can be recorded and transferred to the robot, making even complicated viewing angles possible on the area being operated on. In addition, the operating surgeon can access a variety of menus and perform functions with the robot without using his or her hands.

The new technology also has the advantage that operating surgeons can adopt a relaxed posture – whereas they otherwise have to perform operations in a strenuous posture over a period of several hours. “As we can now operate on patients in a remote fashion, we have much better ergonomics,” says Tobias Hirsch, who holds the Chair of Plastic Surgery at Münster University. “This in turn protects us from fatigue, and that means that our concentration can be maintained over a period of many hours. In initial studies involving the systems, before they were used in operations, we were already able to confirm the positive effects on the quality of operations and on ergonomics.” During training with students and established microsurgeons, the physicians were able to demonstrate that, while using the robotic system, the learning curve, the handling of the instruments, and the ergonomics all demonstrated an improvement over conventional operating techniques.

In the coming weeks and months, Maximilian Kückelhaus and Tobias Hirsch will be performing further operations and, in the process, collect data that they will be evaluating in scientific studies. Important issues to be addressed are, in particular, improvements to the quality of operations and to ergonomics. “Our hope is that with this new method we can not only perform operations with a greater degree of precision and safety – but also, in the case of the tiniest structures, go beyond limits imposed by the human body. Not having to be at the operating table can also mean that one day the operating surgeon will no longer have to be physically present. An expert might be able to perform special operations at any one of several locations – without having to travel and be there in person,” says Maximilian Kückelhaus, looking into the future.

Funding
For the development of, and the clinical trials for, this new method of treatment, Maximilian Kückelhaus received funding from the European Union initiative entitled “Recovery Assistance for Cohesion and the Territories of Europe”.

Wissenschaftliche Ansprechpartner:

Dr. Maximilian Kückelhaus
Head of Experimental Plastic Surgery at the Centre for Musculoskeletal Medicine at the University of Münster
Email: maximilian.kueckelhaus@ukmuenster.de
Phone: +49 251 83 51499

Weitere Informationen:

https://www.medizin.uni-muenster.de/en/imm/departments/department-of-plastic-sur… Department of Plastic and Reconstructive Surgery at the Institute of Musculoskeletal Medicine at the University of Münster

Media Contact

Dr. Kathrin Kottke Stabsstelle Kommunikation und Öffentlichkeitsarbeit
Westfälische Wilhelms-Universität Münster

All latest news from the category: Medical Engineering

The development of medical equipment, products and technical procedures is characterized by high research and development costs in a variety of fields related to the study of human medicine.

innovations-report provides informative and stimulating reports and articles on topics ranging from imaging processes, cell and tissue techniques, optical techniques, implants, orthopedic aids, clinical and medical office equipment, dialysis systems and x-ray/radiation monitoring devices to endoscopy, ultrasound, surgical techniques, and dental materials.

Back to home

Comments (0)

Write a comment

Newest articles

Future AR/VR controllers could be the palm of your hand

Carnegie Mellon University’s EgoTouch creates simple interfaces for virtual and augmented reality. The new generation of augmented and virtual reality controllers may not just fit in the palm of your…

‘Game changer’ in lithium extraction

Rice researchers develop novel electrochemical reactor. A team of Rice University researchers led by Lisa Biswal and Haotian Wang has developed an innovative electrochemical reactor to extract lithium from natural…

The blue-green sustainable proteins of seaweed

… may soon be on your plate. The protein in sea lettuce, a type of seaweed, is a promising complement to both meat and other current alternative protein sources. Seaweed…