A research team at the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) has developed a radiopharmaceutical molecule marker that can visualize tumors that carry the cell surface protein Nectin-4. This primarily occurs in the body in cases of urothelial carcinoma, a common form of bladder cancer.

In pre-clinical trials, the drug candidate, NECT-224, proved stable and was successfully used in humans for the first time. As the team has now reported in the Journal of Medicinal Chemistry, in the future, it could be used to better identify patients who would benefit from Nectin-4-targeted therapies.

Many modern cancer drugs only work when the target structure to which they are supposed to bind is also present on the tumor cells. In the case of urothelial carcinoma, the cell surface protein Nectin-4 lends itself to this purpose. It serves as a “door sign” for antibody-coupled agents that are able to eliminate tumor cells in a targeted fashion. But not every tumor produces the same amount of Nectin-4.

A team from the Universitat Politècnica de València (UPV) has led the development of a new sensor capable of quickly and easily detecting scopolamine, one of the substances most commonly used in crimes of chemical submission, especially in sexual assaults. The sensor detects the presence of this drug in less than five minutes with high sensitivity. The research is published in the journal Angewandte Chemie International Edition.

“Scopolamine is a substance that is difficult to detect using conventional methods, especially when found in drinks. For this reason, our group from the IDM Institute at the UPV set out to develop new, simple tools that can immediately alert us to its presence,” says Vicente Martí Centelles, a researcher at the Interuniversity Research Institute for Molecular Recognition and Technological Development (IDM) at the UPV.

The fungal compound verticillin A, discovered more than 50 years ago, has long been regarded for its potential cancer-fighting capabilities. S cientists have now managed to artificially synthesize the compound for the first time, meaning they can study it in more detail and potentially develop new cancer treatments.

Being able to produce verticillin A on demand in the lab is a major step forward. In nature, it’s found only in small amounts in a microscopic fungus and is very difficult to extract.

Before now, the complex chemical structure and inherent instability of verticillin A made it tricky to synthesize, but researchers from MIT and Harvard Medical School have overcome both problems.