News Release

Ultra-sensitive robotic “finger” can take patient pulses, check for lumps

Peer-Reviewed Publication

Cell Press

Robotic finger

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Robotic finger

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Credit: Yufeng Wang

Researchers at the University of Science and Technology of China have developed a soft robotic “finger” with a sophisticated sense of touch that can perform routine doctor office examinations, including taking a patient’s pulse and checking for abnormal lumps. This work was published October 9 in the Cell Press journal Cell Reports Physical Science.

Such technology could make it easier for doctors to detect diseases such as breast cancer early on, when they are more treatable. It may also help patients feel at ease during physical exams that can seem uncomfortable and invasive.

“By further development to improve its efficiency, we also believe that a dexterous hand made of such fingers can act as a ‘Robodoctor’ in a future hospital, like a physician,” says Hongbo Wang, a sensing technologies researcher at the University of Science and Technology of China and an author of the study. “Combined with machine learning, automatic robotic examination and diagnosis can be achieved, particularly beneficial for these undeveloped areas where there is a serious shortage in health workers.”

While rigid robotic fingers already exist, experts have raised concerns that these devices might not be up to the delicate tasks required in a doctor’s office setting. Some have pointed to potential safety issues, including a fear that overzealous robotic fingers could rupture lumps during examinations. More recently, scientists have developed lightweight, safe, and low-cost soft robotics that can recreate the movements of human hands. However, these devices haven’t been able to sense the complex properties of objects they touch the way real fingers do.

“Despite the remarkable progress in the last decade, most soft fingers presented in the literature still have substantial gaps compared to human hands,” the authors write, noting that robotic fingers have not been ready to handle “‘real world’ scenarios.”

To overcome this challenge, the researchers developed a simple device that contains conductive fiber coils with two parts—a coil wound on each air chamber of the device’s bending actuators (the parts that enable it to move) and a twisted liquid metal fiber mounted at the fingertip. By measuring properties that affect how the device’s electrical current flows, the team found that they could monitor, in real time, how far the finger bends as it touches an object and the force at the fingertip. In this way, the device could perceive an object’s properties as effectively as human touch.

To test the device, the researchers started by brushing a feather against its fingertip.

“The magnified view clearly shows the resistance change, indicating its high sensitivity in force sensing,” the authors write.

Next, they tapped and pushed the fingertip with a glass rod and repeatedly bent the finger, observing that the device’s sensors accurately perceived the type and quantity of force they applied. To test the finger’s medical chops, they mounted it on a robotic arm and watched as it identified three lumps embedded in a large silicone sheet, pressing on them like a doctor would. While mounted on the robotic arm, the finger also correctly located an artery on a participant’s wrist and took their pulse.

“Humans can easily recognize the stiffness of diverse objects by simply pressing it with their finger,” the authors write. “Similarly, since the [device] has the ability to sense both its bending deformation and the force at the fingertip, it can detect stiffness similar to our human hand by simply pressing an object.”

In addition to taking pulses and examining simulated lumps, the researchers found that the robotic finger can type “like a human hand,” spelling out the word “hello.”

By using additional sensors to create even more flexibility in the robotic finger’s joints, allowing the device to move in multiple directions like a human finger, it may be ready to perform effective and efficient medical examinations in the near future, the authors conclude.

“We hope to develop an intelligent, dexterous hand, together with a sensorized artificial muscle-driven robotic arm, to mimic the unparalleled functions and fine manipulations of the human hands,” said Wang.

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This research was supported by Process Vision Ltd.

Cell Reports Physical Science, Wang et al. “Toward human-like touch sense via a bioinspired soft finger with self-decoupled bending and force sensing” https://www.cell.com/cell-reports-physical-science/fulltext/S2666-3864(24)00518-6

Cell Reports Physical Science (@CellRepPhysSci), published by Cell Press, is a broad-scope, open access journal that publishes cutting-edge research across the spectrum of the physical sciences, including chemistry, physics, materials science, energy science, engineering, and related interdisciplinary work. Visit: https://www.cell.com/cell-reports-physical-science/home. To receive Cell Press media alerts, please contact press@cell.com.


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