New robotic system helps surgeons treat stroke remotely

　　New robotic system helps surgeons treat stroke remotely

　　Provide patients with endovascular surgery within a critical time window

　　Science and Technology Daily, Beijing, April 18 (Reporter Zhang Mengran) MIT engineers have developed a telerobotic system that can help surgeons perform rapid remote treatment of stroke or aneurysm patients at a critical time to protect their brain function. Safely operate on patients within the window, saving patients' lives.

The results were published in the journal Science Robotics.

　　The robotic system, whose movements are controlled by magnets, is designed to remotely assist in endovascular interventions, an emergency procedure to treat strokes caused by blood clots.

This intervention usually requires the surgeon to manually guide a thin wire into the clot to physically clear the blockage or deliver drugs to break it up.

　　One limitation of this type of surgery is that patients stationed in remote areas, often far from major medical facilities with neurovascular surgeons, are prone to miss the "golden hour" of post-stroke treatment.

　　The robotic system designed by the MIT team can be installed in small hospitals and guided remotely by trained surgeons at large medical centers.

The system includes a medical-grade robotic arm with a magnet attached to its wrist.

Using a joystick and live imaging, the operator can adjust the direction of the magnet and manipulate the arm to guide the soft, thin magnetic wire through arteries and blood vessels.

　　The researchers installed robotic arms in the lab, along with life-size models of silicone blood vessels.

They put joysticks in the control room, along with monitors that show real-time video of the models.

From there, the operator uses the joystick to remotely maneuver the medical wire through the blood vessel while watching the video.

　　The team trained a team of neurosurgeons to use the robotic system.

After an hour of training, each surgeon was able to successfully operate the system, guiding medical leads through complex blood vessels that were difficult to navigate manually.

　　The team also used a robotic system to clear simulated clots in hard-to-reach areas of the model.

They guided the wire through the blood vessel, around sharp corners and turns, to the area where the researchers simulated the clot.

When they guided the guidewire to the clot, the surgeons used standard endovascular methods to thread the microcatheter along the wire into the clot site and successfully resected the clot.