Radionuclide drug conjugates have emerged as transformative agents that integrate diagnosis and therapy into a single clinical workflow, according to a new review published in the Medical Journal of Peking Union Medical College Hospital. By coupling radioactive isotopes with antibodies, peptides, or small molecules, these advanced pharmaceuticals enable precise tumor targeting, high diagnostic sensitivity, and effective localized radiotherapy, positioning them as a cornerstone technology for achieving precision oncology through theranostic integration.
The review, available through the journal's website at https://xhyxzz.pumch.cn/article/doi/10.12290/xhyxzz.2024-0577, provides an in-depth analysis of 15 years of progress in RDC research conducted by a team from Peking Union Medical College Hospital. The study summarizes current RDC classifications, clinical development trends, and supportive policy frameworks that are shaping the next generation of precision radiopharmaceuticals. It highlights the expanding number of clinical trials, new therapeutic targets, and national-level guidance that are accelerating development in this field.
Structurally, RDCs are categorized into antibody-, peptide-, and small-molecule-based conjugates, each offering unique pharmacological advantages. The review emphasizes the rise of cyclic peptide conjugates, which exhibit low toxicity and high tumor selectivity, making them particularly promising for clinical applications. Policy reforms including technical guidelines issued by regulatory agencies since 2020 have standardized clinical evaluation, non-clinical research, and radiochemical quality control, creating a more predictable environment for innovation and development.
"RDCs represent the only class of therapeutics capable of achieving true integration of diagnosis and treatment," said Prof. Hongyun Wang, senior author of the review. "Despite challenges in radiochemical synthesis, stability, and regulatory alignment, we are witnessing unprecedented enthusiasm and cross-disciplinary collaboration in this field. With continued innovation in targeting ligands and isotope design, RDCs will redefine how we approach tumor detection, treatment monitoring, and personalized therapy."
The importance of this development lies in its potential to transform cancer management by enabling simultaneous imaging, treatment, and response monitoring within a single platform. As aging populations and cancer incidence continue to rise globally, demand for next-generation radiopharmaceuticals will grow substantially. The review underscores the need for stronger innovation capacity, improved isotope supply chains, and streamlined approval processes to support RDC translation from laboratory to clinic. Through coordinated scientific, industrial, and regulatory efforts, RDCs are expected to become a central component of future oncology care, offering patients more accurate diagnoses and safer, more effective treatment pathways that could significantly improve outcomes and quality of life for cancer patients worldwide.
