Science Highlights | U.S. DOE Office of Science (SC)

Images showing mice injected with radioactive antimony. Left panel with TREN-CAM shows how the radioactive antimony will be active longer in the treatment areas. The right panel shows that the antimony without TREN-CAM doesn’t stay in the desired areas.

Progress Towards Unlocking Antimony’s Cancer Treatment Potential

Researchers gain a new understanding of the binding chemistry of radioactive antimony, opening doors for targeted therapy.

Steps in terbium-161 (Tb-161) production. The University of Utah TRIGA reactor induces thermal neutron capture on gadolinium-160 (Gd-160), which decays to Tb-161. Separating the Gd-160 target yields high-purity Tb-161 for cancer therapy and diagnosis.

To Advance Cancer Therapy, University Starts Producing Terbium-161

A University of Utah research team demonstrates that a low power university research reactor can produce terbium-161 at high purity from gadolinium-160.

Improvements to Americium-241 processing can increase yield, decrease the amount of waste generated, and reduce the radiological dose workers receive.

Improving Large-Scale Domestic Production of Americium-241, a Critical Component in Smoke Detectors and Nuclear Batteries

Researchers explore the effects of radiation and harsh chemicals to optimize americium-241 production.

Schematic of the astatine-ketone bond breaking to release free astatine-211.

One Step Closer to a New Class of Radiopharmaceuticals: Astatine as a Cancer Treatment

Researchers gain new insights into a strong bond between the isotope astatine-211 and common chemicals, creating new possibilities for cancer treatment.

Artists’ depiction of a new potential cancer treatment vehicle—an engineered nanometer-size construct that holds a radioactive isotope that can be delivered to destroy cancer cells.

Killing Cancer with Radioactive Nanocrystals

Scientists have developed tiny nanocrystal particles made up of isotopes of the elements lanthanum, vanadium, and oxygen for use in treating cancer.

Conceptual art showing the rare earth element promethium in a vial surrounded by an organic ligand. Scientists have discovered hidden features of promethium, opening a pathway for research on other lanthanide elements.

In an Advance for Promethium Production, Researchers Get a New View of the Element’s Properties

Scientists characterize a promethium coordination complex for the first time, furthering the understanding of difficult-to-study lanthanide elements.

Illustration of an idealized extraction chromatographic resin using DGA or LN extractants. By studying the adsorption properties of terbium on these DGA and LN resins, scientists gain insights into these properties for the entire lanthanide series.

Understanding the Adsorption Properties of Terbium for Future Medical Use

Scientists investigate the adsorption, thermodynamics, and kinetic properties of terbium on two popular resins for lanthanide separations: DGA and LN.

Concept of the automated system for remote dissolution of the irradiated bismuth target and astatine recovery in nitric acid media.

Automation of Nuclear Chemistry Processes Leads to More Efficient Production of Astatine for Cancer Therapy

Researchers developed a remotely controlled device for the safe and efficient purification of astatine using liquid phase chemistry.

This electron microscope image shows spherical bismuth powder. Each particle in the photo is about the diameter of a human hair (approximately 60 micrometers).

Spherical Powders Enable New Applications for Metals

Free-flowing metal powders offer improvements for additive manufacturing, isotope production target fabrication, and more.

Abstract representation of subcooled flow boiling modeled on experimental data collected for the Los Alamos National Laboratory Isotope Production Facility.

Deep Learning Model Overcomes the Challenge of Real-World Measurements of Isotope Production Target Cooling Systems

Researchers develop a framework to predict subcooled flow boiling and critical heat flux.

Student working in the Texas A&M University lab processing astatine-211.

New Understanding of Astatine’s Chemical Properties Will Aid Targeted Alpha Therapy for Cancer

Researchers gain new insights into how the isotope astatine-211 interacts with resins commonly used to purify the isotope for therapeutic use.

Illustration of the structure of the radium compound characterized in this research. Single crystal X-ray diffraction provided detailed information on the bonding of radium in an organic molecule for the first time.

A First Look Inside Radium’s Solid-State Chemistry

Researchers used single crystal X-ray diffraction to learn about the structure and bonding of a highly radioactive radium compound.