Conventional pressure sensors frequently struggle with accuracy. They have trouble delivering consistent readings, often returning varying results when the same pressure is applied repeatedly and can overlook subtle changes in pressure — all of which can lead to significant errors. They are also typically made from stiff and mechanically inflexible materials.
To address these challenges in pressure sensing, the NUS team drew inspiration from a phenomenon known as the 'lotus leaf effect' — a unique natural phenomenon where water droplets effortlessly roll off the leaf’s surface, made possible by its minuscule, water-repelling structures. Mimicking this effect, the team has engineered a pressure sensor designed to significantly improve the sensing performance. "The sensor, akin to a miniature 'capacity meter', can detect minute pressure changes — mirroring the sensitivity of a lotus leaf to the extremely light touch of a water droplet,§ explained Assoc Prof Tee.
Employing an innovative "air spring" design, the eAir sensor houses a trapped layer of air, forming an air-liquid interface upon contact with the sensor’s liquid. As external pressure increases, this air layer compresses. A surface treatment results in a frictionless movement of the interface within the sensor, triggering a change in electrical signals that accurately reflects the exerted pressure. Using this design, the natural water-repelling capabilities of the lotus leaf have been reimagined as a simple yet elegant pressure-sensing tool. The eAir devices can be made relatively small – at a few millimetres in size – and this comparable to existing pressure sensors.
The real-world applications of this novel technology are wide-ranging. For instance, in laparoscopic surgeries where precise tactile feedback is indispensable, incorporating eAir sensors could lead to safer surgical procedures, ultimately enhancing patient recovery and prognosis. "Conducting surgeries with graspers presents its unique challenges. Precise control and accurate perception of the forces applied are critical, but traditional tools can sometimes fall short, making surgeons rely heavily on experience, and even intuition. The introduction of soft and readily integrable eAir sensors, however, could be a game-changer," said Assoc Prof Tee, who is also from the NUS Department of Materials Science and Engineering.
"When surgeons perform minimally-invasive surgery such as laparoscopic or robotic surgery, we can control the jaws of the graspers, but we are unable to feel what the end-effectors are grasping. Hence, surgeons have to rely on our sense of sight and years of experience to make a judgement call about critical information that our sense of touch could otherwise provide," explained Dr Kaan Hung Leng, Consultant, Department of General Surgery at the National University Hospital, Ng Teng Fong General Hospital and NUS Yong Loo Lin School of Medicine.
Dr Kaan, who is not involved in the research project, elaborated, "The haptic or tactile feedback provided by smart pressure sensors has the potential to revolutionise the field of minimally-invasive surgery. For example, information about whether a tissue that is being grasped is hard, firm or soft provides an additional and important source of information to aid surgeons in making prudent decisions during a surgery. Ultimately, these intra-operative benefits have the potential to translate into improved surgical and patient outcomes."
Additionally, eAir presents an opportunity to improve the process of monitoring intracranial pressure — the pressure within the skull that can influence brain health. Similarly, by offering a minimally invasive solution, the technology could transform patient experiences in the management of brain-related conditions, ranging from severe headaches to potential brain damage.
The NUS team is laying the groundwork for collaborations with key players in the medical field. At the same time, they have filed a patent for the eAir sensor technology in Singapore, and aims to translate the technology for real-world applications. "We want to further refine the eAir sensor to enhance its performance by exploring various new materials and microstructural designs," shared Assoc Prof Tee.
The team envisions the eAir technology being weaved into a diverse tapestry of applications for liquid environments.
MEDICA-tradefair.com; Source: National University of Singapore