Whether in tooth enamel or in nanomaterials made of silicon, the orientation of tiny internal structures often determines the properties of a material. A new X-ray method can even make this nano-order visible when the structures are actually too small to be imaged directly. The method was developed by an international team led by the Helmholtz Center Hereon, and it opens up new possibilities to investigate materials and biological structures. The research is published in the journal Light: Science & Applications.

In medical X-ray imaging, the picture is created by the varying attenuation of X-rays in the body. In order to examine materials or biological tissue in detail, experts use advanced techniques that provide additional information, such as dark-field imaging. This technique exploits the fact that X-rays are scattered, i.e., deflected, at internal interfaces and irregularities. “The scattering reveals a lot about internal structures that are not directly visible in the actual image,” explains Hereon researcher Sami Wirtensohn, first author of the study.

To make these fine structures visible, the dark field method blocks the direct X-ray beam. This allows the detector to capture only the radiation scattered inside the sample. Until now, this method has only been able to show that such structures exist, but not how they are spatially aligned.

Cancer cells frequently develop the ability to expel anticancer drugs before they can work—a phenomenon called multidrug resistance (MDR)—which is one of the leading reasons why chemotherapy fails in patients. Research published in the Journal of Controlled Release addresses that problem with a fundamentally new strategy: instead of simply increasing drug doses or switching drugs, researchers engineered nanoparticles that first disable the cancer cell’s drug-expulsion mechanism, and only then release the anticancer drug.

By combining this sequential drug delivery approach with photothermal therapy (using near-infrared laser light to heat and destroy the tumor), complete tumor elimination and 100% survival in a mouse model of drug-resistant cancer were achieved, with no detectable toxicity to normal tissues.

This remarkable drug delivery system was developed by an international research team led by Professor Eijiro Miyako at Tohoku University, who is also a Visiting Professor at Japan Advanced Institute of Science and Technology, in collaboration with the group of Drs. Alberto Bianco and Cécilia Ménard-Moyon at the French National Center for Scientific Research (CNRS)/University of Strasbourg.