Getting X-rays can be quite uncomfortable. You might need to lie still while experiencing discomfort or as a part of your body is compressed. However, innovative flexible fabrics that enhance X-ray detection could alleviate this issue.

“Picture scanning your child for injuries and conducting a painless breast examination without requiring the child to stay still,” says Li Xu from the Hong Kong Institute of Technology. She and her team have developed a fabric known as X-Wear, which emits light when exposed to X-rays.

X-rays typically utilize scintillation components, which are harder to detect than visible light, in both medical and industrial applications. For example, they can convert rays that penetrate your limbs into visible light, allowing for the creation of images that reveal internal details like fractures. However, the current scintillators are usually rigid, which makes them uncomfortable for use in devices where they are embedded.

To tackle this issue, researchers have reformulated scintillating materials, like reshaping gadolinium oxide sprinkled with europium into fine fibers, which are then integrated into fabrics.

Xu mentions that crafting these fibers to be flexible while ensuring they emit sufficient light for producing high-resolution images when exposed to X-rays poses a technical challenge. Her team has demonstrated that fabrics can be utilized for dental X-rays – in tests, X-Wear adapted to the shape of a clay mouth model and teeth. It has also been used for mammography, where an X-Wear bra was created to eliminate the need for compressing a person’s breasts during imaging, a common current practice.

Imalka Jayawardena from the University of Surrey in the UK emphasizes that X-Wear’s body-compliant nature is a significant advantage over other flexible scintillator designs, which tend to be film-like and inflexible. However, he notes that the light detectors paired with X-Wear are still flat, limiting the fabric’s potential applications.

Currently, researchers can produce about a quarter of a square meter of X-Wear samples, meaning production must be scaled up and adapted for industrial-grade equipment before it can be used widely, according to Xu.

The team is also exploring X-Wear’s potential for industrial use, envisioning small, flexible devices for inspecting electronics and identifying defects in pipelines. Xu also notes that first responders in disaster zones could utilize X-Wear, equipped with smartphones and compact X-ray sources, for conducting on-site scans.