12.01.21
The key to optimal patient diagnostics and lower healthcare costs lies in the early detection of diseases. Excellent image quality plays an essential role. TNO at Holst Centre and Siemens Healthineers have demonstrated a new generation of direct-conversion X-ray detectors, based on ultra-sensitive perovskite materials, that significantly boost resolution while simultaneously reducing the X-ray dose.
In 2019, TNO at Holst Centre and Siemens Healthineers started collaborating on this subject in the framework of the EU project ESSENCE, which was followed by the EU-funded PEROXIS project. The partners that collaborate in this project have recently published an article in Nature Electronics. It describes the technologies they have developed for the next generation of highly sensitive X-ray detectors, enabling faster and better diagnostics and treatment.
“Current X-ray systems mostly use indirect X-ray imaging,” Albert van Breemen, senior scientist TNO at Holst Centre, said. “This imaging method is highly sensitive, but images are captured at moderate resolution. In mammography systems, current direct X-ray imaging enables a higher resolution to create clear images for diagnosis. But the lower sensitivity requires a higher radiation dose, exposing patients to more radiation than preferred. In order to further boost the technology, we had to find a way to combine high sensitivity with a high resolution."
Perovskites are best known for their use in the fastest-advancing solar-cell technology to date. However, they are also promising in the area of direct-conversion X-ray materials that can be applied over large surfaces at low cost.
“Since the technology is 'borrowed' from the solar-panel industry, development is faster and less expensive,” van Breemen said. “In fact, current X-ray imagers can simply be refitted with perovskite-based converters, turning indirect imaging into direct imaging."
The integration of direct X-ray converter layers onto a thin-film transistor backplane can be challenging from a manufacturing perspective.
“Together with TNO at Holst Centre, we have developed a two-step manufacturing process for MAPbI3 X-ray flat-panel detectors,” said Sandro Tedde, senior key expert research scientist at Siemens Healthineers. “This process is based on the mechanical soft-sintering of a freestanding X-ray-absorbing perovskite wafer that does not require high vacuum and/or high temperatures and its easy integration onto an oxide thin-film transistor backplane.”
The development of X-ray detectors with high resolution and high sensitivity can help improve healthcare, as early detection and diagnosis will enable better treatment options, better patient outcomes and lower healthcare costs for medical professionals and patients alike.
In 2019, TNO at Holst Centre and Siemens Healthineers started collaborating on this subject in the framework of the EU project ESSENCE, which was followed by the EU-funded PEROXIS project. The partners that collaborate in this project have recently published an article in Nature Electronics. It describes the technologies they have developed for the next generation of highly sensitive X-ray detectors, enabling faster and better diagnostics and treatment.
“Current X-ray systems mostly use indirect X-ray imaging,” Albert van Breemen, senior scientist TNO at Holst Centre, said. “This imaging method is highly sensitive, but images are captured at moderate resolution. In mammography systems, current direct X-ray imaging enables a higher resolution to create clear images for diagnosis. But the lower sensitivity requires a higher radiation dose, exposing patients to more radiation than preferred. In order to further boost the technology, we had to find a way to combine high sensitivity with a high resolution."
Perovskites are best known for their use in the fastest-advancing solar-cell technology to date. However, they are also promising in the area of direct-conversion X-ray materials that can be applied over large surfaces at low cost.
“Since the technology is 'borrowed' from the solar-panel industry, development is faster and less expensive,” van Breemen said. “In fact, current X-ray imagers can simply be refitted with perovskite-based converters, turning indirect imaging into direct imaging."
The integration of direct X-ray converter layers onto a thin-film transistor backplane can be challenging from a manufacturing perspective.
“Together with TNO at Holst Centre, we have developed a two-step manufacturing process for MAPbI3 X-ray flat-panel detectors,” said Sandro Tedde, senior key expert research scientist at Siemens Healthineers. “This process is based on the mechanical soft-sintering of a freestanding X-ray-absorbing perovskite wafer that does not require high vacuum and/or high temperatures and its easy integration onto an oxide thin-film transistor backplane.”
The development of X-ray detectors with high resolution and high sensitivity can help improve healthcare, as early detection and diagnosis will enable better treatment options, better patient outcomes and lower healthcare costs for medical professionals and patients alike.