During SNM's 57th Annual Meeting, investigators¹ presented the results of a multidisciplinary（有关各种学问的） study involving the capture of radiation luminescence（发冷光） and radioactive-excited nanoparticles to help detect subtle（微妙的，敏感的） signs of disease. Currently, nuclear medicine agents and imaging technology image the behavior of particles at the cellular², molecular³ and atomic levels, but radioactive materials also emit barely visible light that can be detected with highly sensitive optical imaging technology. This discovery could lead to new, state-of-the-art imaging techniques. "The need for this study became evident with the rise of new molecular imaging research and multimodality（多封性） imaging instruments and probes, which could provide better and earlier diagnosis⁴ for a variety of diseases," said Zhen Cheng, Ph.D., co-author of the study and assistant professor of radiology（放射学） at Stanford University. "The research presented here bridges nuclear imaging and optical imaging. It represents a new avenue for molecular imaging research, and is expected to have many applications for medical and bionanotechnology research as well as clinical imaging."

Study researchers focused on a low-energy window of light from the visible and near-infrared band of the electromagnetic spectrum⁵. This is not visible to the human eye, but can be detected with very precise optical cameras picking up light energy from the charged particles of radioactive sources. Researchers tested commonly employed molecular imaging agents used to detect a range of biological processes within the body. Imaging agents utilized⁶ in the study include fluorine-based 18F-FDG and Na18F, sodium⁷ iodide-based Na131I, yttrium-based 90Y-Cl3, as well as a 90Y labeled peptide（缩氨酸） that specifically target tumors.

Findings indicate that radioactive molecular probes and nano-imaging techniques using radiation luminescence and widely studied fluorescent⁸ （荧光，日光灯）nanoparticles known as "quantum dots" could potentially be used for non-invasive functional⁹ imaging with optical imaging systems. Not only could this have a significant impact on the early detection and diagnosis of disease, but these and resulting techniques could also be applied¹⁰ to future applications in image-guided therapy.