Integrating Theranostics Into Patient Care Pathways: AJR Expert Panel Narrative Review

Logistics of Adopting 177Lu-Vipivotide Tetraxetan Therapy in a Community-Based Hospital Setting

Prostate cancer is a leading cause of cancer death in men. Advanced disease may progress to metastatic castration-resistant prostate cancer. In March 2022, 177Lu-vipivotide tetraxetan was U.S. Food and Drug Administration-approved for patients with prostate-specific membrane antigen-positive metastatic castration-resistant prostate cancer who have previously received other therapies, including androgen deprivation and taxane therapies. Methods: Although preliminary data for 177Lu-vipivotide tetraxetan has shown extension of overall survival of patients, there is little literature about realistically initiating 177Lu-vipivotide tetraxetan into non-academic-based clinical practices. Results: This article presents a multidisciplinary practice implementation workflow for 177Lu-vipivotide tetraxetan. It also highlights the challenges and considerations for initiating such a theranostics practice. Conclusion: The aim of this work is to help nontertiary medical centers improve patient accessibility for beneficial radiopharmaceutical therapies, specifically 177Lu-vipivotide tetraxetan.

Radiation-Related Thyroid Cancer

Radiation is an environmental factor that elevates the risk of developing thyroid cancer. Actual and possible scenarios of exposures to external and internal radiation are multiple and diverse. This article reviews radiation doses to the thyroid and corresponding cancer risks due to planned, existing, and emergency exposure situations, and medical, public, and occupational categories of exposures. Any exposure scenario may deliver a range of doses to the thyroid, and the risk for cancer is addressed along with modifying factors. The consequences of the Chornobyl and Fukushima nuclear power plant accidents are described, summarizing the information on thyroid cancer epidemiology, treatment, and prognosis, clinicopathological characteristics, and genetic alterations. The Chornobyl thyroid cancers have evolved in time: becoming less aggressive and driver shifting from fusions to point mutations. A comparison of thyroid cancers from the 2 areas reveals numerous differences that cumulatively suggest the low probability of the radiogenic nature of thyroid cancers in Fukushima. In view of continuing usage of different sources of radiation in various settings, the possible ways of reducing thyroid cancer risk from exposures are considered. For external exposures, reasonable measures are generally in line with the As Low As Reasonably Achievable principle, while for internal irradiation from radioactive iodine, thyroid blocking with stable iodine may be recommended in addition to other measures in case of anticipated exposures from a nuclear reactor accident. Finally, the perspectives of studies of radiation effects on the thyroid are discussed from the epidemiological, basic science, and clinical points of view.

DNA Damage by Radiopharmaceuticals and Mechanisms of Cellular Repair

DNA is an organic molecule that is highly vulnerable to chemical alterations and breaks caused by both internal and external factors. Cells possess complex and advanced mechanisms, including DNA repair, damage tolerance, cell cycle checkpoints, and cell death pathways, which together minimize the potentially harmful effects of DNA damage. However, in cancer cells, the normal DNA damage tolerance and response processes are disrupted or deregulated. This results in increased mutagenesis and genomic instability within the cancer cells, a known driver of cancer progression and therapeutic resistance. On the other hand, the inherent instability of the genome in rapidly dividing cancer cells can be exploited as a tool to kill by imposing DNA damage with radiopharmaceuticals. As the field of targeted radiopharmaceutical therapy (RPT) is rapidly growing in oncology, it is crucial to have a deep understanding of the impact of systemic radiation delivery by radiopharmaceuticals on the DNA of tumors and healthy tissues. The distribution and activation of DNA damage and repair pathways caused by RPT can be different based on the characteristics of the radioisotope and molecular target. Here we provide a comprehensive discussion of the biological effects of RPTs, with the main focus on the role of varying radioisotopes in inducing direct and indirect DNA damage and activating DNA repair pathways.