Biomedical Engineering
MORPHing metamaterials into biomarker-detection powerhouses
Molecular diagnostics get a shot in the arm with hydrogelbased metamaterials, enhancing precision and speed in identifying critical biomarkers for disease monitoring.
Smart materials, from sunlight-responsive windows to shape-shifting alloys in medical devices to self-powered light sensors, play an increasingly integral role in our everyday lives due to their ability to react to various external stimuli such as light, temperature or moisture.
Among smart materials, metamaterials stand out for their engineered structures with unique properties not commonly found in nature. With rationally designed patterns, these materials work in unison to offer precise control and unprecedented functionalities. This characteristic renders them versatile across many applications, ranging from advanced optics to medical technologies, through the manipulation of energy and signals in novel ways.
At the College of Design and Engineering, National University of Singapore, researchers have achieved a breakthrough in biomolecule profiling by designing a hydrogel-based metamaterial specially engineered to visually detect the presence of extracellular vesicles in patient samples, with potential applications in disease diagnosis and monitoring.
Led by Associate Professor Shao Huilin, the team’s research was published in Nature Biomedical Engineering on 27 October 2022.
Unlocking the biomedical potential of metamaterials
Mechanical metamaterials have recently garnered interest in biomedicine for applications in diagnostics and treatments as they can dramatically alter an object’s mechanical response through their structured composition.
Take, for instance, metamaterials with a lattice structure. Such materials have a negative Poisson’s ratio — meaning they expand laterally when stretched, in contrast to most that tend to contract. This makes them highly valuable in crafting impact-resistant materials and in the design of medical implants.
Yet, the full potential of these materials in medical applications remains largely untapped. A key challenge in harnessing mechanical metamaterials for biomedical purposes lies in their limited response range, especially when considering hydrogels.
While hydrogels are responsive to environmental changes, their structural flexibility during preparation can compromise the precision required for biomedical applications. They also react rather slowly. Molecules within a hydrogel network interact with one another via gradual diffusion, which limits its ability to detect changes swiftly and accurately in different areas.