The Emission of Internal Conversion Electrons Rather Than Auger Electrons Increased the Nucleus-Absorbed Dose for<sup>161</sup>Tb Compared with<sup>177</sup>Lu with a Higher Dose Response for [<sup>161</sup>Tb]Tb-DOTA-LM3 Than for [<sup>161</sup>Tb]Tb-DOTATATE
Kaat Spoormans, Lara Struelens, Koen Vermeulen, Marijke De Saint‐Hubert, Michel Koole, Melissa Crabbé
Abstract
Preclinical data have shown that <sup>161</sup>Tb-labeled peptides targeting the somatostatin receptor are therapeutically more effective for peptide receptor radionuclide therapy than are their <sup>177</sup>Lu-labeled counterparts. To further substantiate this enhanced therapeutic effect, we performed cellular dosimetry to quantify the absorbed dose to the cell nucleus and compared dose–response curves to evaluate differences in relative biological effectiveness in vitro. <b>Methods:</b> CA20948 cell survival was assessed after treatment with [<sup>161</sup>Tb]Tb- and [<sup>177</sup>Lu]Lu-DOTATATE (agonist) and with [<sup>161</sup>Tb]Tb- and [<sup>177</sup>Lu]Lu-DOTA-LM3 (antagonist) via a clonogenic assay. Cell binding, internalization, and dissociation assays were performed up to 7 d to acquire time-integrated activity coefficients. Separate <i>S</i> values for each type of particle emission (Auger/internal conversion [IC] electrons and β<sup>−</sup> particles) were computed via Monte Carlo simulations, while considering spheric cells. Once the absorbed dose to the cell nucleus was calculated, survival curves were fitted to the appropriate linear or linear-quadratic model and corresponding relative biological effectiveness was evaluated. <b>Results:</b> Although the radiopeptide uptake was independent of the radionuclide, [<sup>161</sup>Tb]Tb-DOTATATE and [<sup>161</sup>Tb]Tb-DOTA-LM3 delivered a 3.6 and 3.8 times higher dose to the nucleus, respectively, than their <sup>177</sup>Lu-labeled counterparts on saturated receptor binding. This increased nucleus-absorbed dose was mainly due to the additional emission of IC and not Auger electrons by <sup>161</sup>Tb. When activity concentrations were considered, both [<sup>161</sup>Tb]Tb-DOTATATE and [<sup>161</sup>Tb]Tb-DOTA-LM3 showed a lower survival fraction than did labeling with <sup>177</sup>Lu. When the absorbed dose to the nucleus was considered, no significant difference could be observed between the dose–response curves for [<sup>161</sup>Tb]Tb- and [<sup>177</sup>Lu]Lu-DOTATATE. [<sup>161</sup>Tb]Tb-DOTA-LM3 showed a linear-quadratic dose response, whereas [<sup>161</sup>Tb]Tb-DOTATATE showed only a linear dose response within the observed dose range, suggesting additional cell membrane damage by Auger electrons. <b>Conclusion:</b> The IC, rather than Auger, electrons emitted by <sup>161</sup>Tb resulted in a higher absorbed dose to the cell nucleus and lower clonogenic survival for [<sup>161</sup>Tb]Tb-DOTATATE and [<sup>161</sup>Tb]Tb-DOTA-LM3 than for the <sup>177</sup>Lu-labeled analogs. In contrast, [<sup>161</sup>Tb]Tb-DOTATATE showed no higher dose response than [<sup>177</sup>Lu]Lu-DOTATATE, whereas for [<sup>161</sup>Tb]Tb-DOTA-LM3 an additional quadratic response was observed. Because of this quadratic response, potentially caused by cell membrane damage, [<sup>161</sup>Tb]Tb-DOTA-LM3 is a more effective radiopeptide than [<sup>161</sup>Tb]Tb-DOTATATE for labeling with <sup>161</sup>Tb.