Characterization of Effective Half-Life for Instant Single-Time-Point Dosimetry Using Machine Learning
Carlos Vinícius Gomes, Yizhou Chen, Isabel Rauscher, Song Xue, Andrei Gafita, Jiaxi Hu, Robert Seifert, Lorenzo Mercolli, Julia Brosch-Lenz, Jimin Hong, Marc Ryhiner, Sibylle Ziegler, Ali Afshar‐Oromieh, Axel Rominger, Matthias Eiber, Thiago Lima, Kuangyu Shi
Abstract
Single-time-point (STP) image-based dosimetry offers a more convenient approach for clinical practice in radiopharmaceutical therapy (RPT) compared with conventional multiple-time-point image-based dosimetry. Despite numerous advancements, current STP methods are limited by the need for strict and late timing in data acquisition, posing challenges in routine clinical settings. This study introduces a new concept of instant STP (iSTP) dosimetry, achieved by predicting the effective half-life (<i>T</i><sub>eff</sub>) of organs using machine learning applied on pretherapy patient data (PET and clinical values). <b>Methods:</b> Data from 22 patients who underwent pretherapy <sup>68</sup>Ga-gallium <i>N</i>,<i>N</i>-bis[2-hydroxy-5-(carboxyethyl)benzyl]ethylenediamine-<i>N</i>,<i>N</i>-diacetic acid ([<sup>68</sup>Ga]Ga-PSMA-11) imaging and subsequently [<sup>177</sup>Lu]Lu-PSMA I&T RPT were analyzed. A machine learning model was developed for <i>T</i><sub>eff</sub> predictions for the left and right kidneys, liver, and spleen subsequently used to estimate time-integrated activity and absorbed dose. iSTP results were compared against multiple-time-point and previously proposed Hänscheid methods. Our method comprised 2 different prediction scenarios, using data before each therapy cycle and from the first cycle. <b>Results:</b> The iSTP method introduced early posttherapy time points (2, 20, 43, and 69 h) for the left kidney, right kidney, liver, and spleen. Dosimetry in the first scenario, aggregating 2 and 20 h, achieved mean differences in time-integrated activity below 27% for all organs. To assess the feasibility, these time points were compared with the best results from the Hänscheid method (kidneys, 69 h; liver and spleen, 20 h). At 2 h, a significant difference (<i>P</i> < 0.001) was found for almost all organs except for the spleen (<i>P</i> = 0.1370). However, at 20 h, no significant differences were found for the right kidney, liver, and spleen, apart from the left kidney (<i>P</i> < 0.01). In the scenario using only the initial PET/CT data to predict <i>T</i><sub>eff</sub> for subsequent cycles, iSTP dosimetry achieved no statistical significance (<i>P</i> > 0.05) for all cycles in comparison to results using PET data before each therapy cycle. <b>Conclusion:</b> Our preliminary results prove the concept for prediction of <i>T</i><sub>eff</sub> with pretherapy data and achieving STP shortly and flexibly after the RPT. The proposed method may expedite the application of dosimetry in broader contexts, such as outpatient or short-duration inpatient treatment.