Hand and Technology Combine in New Surgical Tool that Enables Superhuman Precision
Even the most skilled and steady surgeons experience minute, almost imperceptible hand tremors when performing delicate tasks. Normally, these tiny motions are inconsequential, but for doctors specializing in fine-scale surgery, such as operating inside the human eye or repairing microscopic nerve fibers, freehand tremors can pose a serious risk for patients.
By harnessing a specialized optical fiber sensor, a new “smart” surgical tool can compensate for this unwanted movement by making hundreds of precise position corrections each second – fast enough to keep the surgeon’s hand on target. Researchers from the Johns Hopkins University Whiting School of Engineering and Johns Hopkins School of Medicine in Baltimore, MD, have combined the Optical Coherence Tomography (OCT) imaging technique as a distance sensor with computer-controlled piezoelectric motors to actively stabilize the tip of a surgical tool.
“Microsurgery relies on excellent motor control to perform critical tasks,” states Cheol Song, a postdoctoral fellow in the Electrical and Computer Engineering Department at Johns Hopkins. “But certain fine micro-manipulations remain beyond the motor control of even the most skilled surgeon.” At its most steady, the human hand naturally trembles, moving on the order of 50-100 microns (about the thickness of a sheet of paper) several times each second.
Various optomechatronics techniques, including robotics, have been developed to help augment stability and minimize the impact of hand tremors. None so far has been able to seamlessly merge simple fiber-optic rapid and fine-grained sensing with handheld automated surgical tools. The major challenge for researchers has been finding a way to precisely measure and compensate for the relative motions of a surgical instrument in relation to the target.
The emerging imaging technique of OCT attracted the attention of the researchers because it has higher resolution (approximately 10 microns) than either MRI or ultrasound. It also uses eye-safe near infrared light to image tissues.
To apply this imaging technique to their work, the research team first had to integrate an OCT-based high-speed high-precision distance sensor directly into a small, handheld surgical device. The device could then hold a variety of surgical instruments at the tip, such as a scalpel or forceps. The well-known fiber-optic based common path optical coherence tomography (CP-OCT) technique provided the essential capability. As its name suggests, the optical signal of this sensor uses the same path, or optical fiber, to both transmit and receive the near infrared light.
Because this single fiber-optic cable is so small and flexible, the researchers could easily integrate it into the front of a tool used for eye surgery. By continually sending and receiving the near infrared laser beams, the high-speed fiber-optic sensor precisely measures the motion of the probe. This information then feeds to a computer that sends signals to small piezoelectric motors integrated into the surgical device to control the position of the tool tip. This creates a series of “station keeping” maneuvers that compensate for the surgeon’s hand tremors.
Combined, the sensor and motors can operate accurately at 500 hertz (500 times each second), which is much higher than the typical tremor frequency of 0-15 hertz.
The researchers compared the effectiveness of the system by testing its ability to compensate for hand tremors during 5- and 30-second intervals. According to the researchers, these time periods were sufficient to determine the different characteristic between short- and long-term hand tremors. “A 30-second time period is enough to evaluate a surgeon’s basic physiological hand tremor characteristics,” said Song. For complete characterization, however, a record of a full surgical procedure, which typically lasts more than 3 hours, will be needed.
For their study, the tests were performed on two targets. The first was a dry “phantom,” a material that has sufficient properties to stand as a proxy for medical research. A more real-world test was also done on a viable chicken embryo, which better simulated a realistic surgical environment because of the unpredictable movements of the live embryo.
During the next few years, the researchers hope to take their instrument from the laboratory to the operating suite, and with additional refinements expand its use to other fine-scale surgeries.
“The main objective of our research has been to make an established surgical tool ‘smarter’ by incorporating fiber-optic sensors and motion control to allow surgeons to maneuver the tool tip precisely and safely,” says Jin U. Kang, another researcher with the Electrical and Computer Engineering department at Johns Hopkins. “SMART, which is capable of fine motion control and sensing, could significantly enhance the surgical performance of doctors and minimize surgical accidents.”