RT Journal Article
SR Electronic
T1 Dosimetric Analysis of 177Lu-cG250 Radioimmunotherapy in Renal Cell Carcinoma Patients: Correlation with Myelotoxicity and Pretherapeutic Absorbed Dose Predictions Based on 111In-cG250 Imaging
JF Journal of Nuclear Medicine
JO J Nucl Med
FD Society of Nuclear Medicine
SP 82
OP 89
DO 10.2967/jnumed.111.094896
VO 53
IS 1
A1 Alexander B. Stillebroer
A1 Catharina M.L. Zegers
A1 Otto C. Boerman
A1 Egbert Oosterwijk
A1 Peter F.A. Mulders
A1 Joseph A. O'Donoghue
A1 Eric P. Visser
A1 Wim J.G. Oyen
YR 2012
UL http://jnm.snmjournals.org/content/53/1/82.abstract
AB This study aimed to estimate the radiation absorbed doses to normal tissues and tumor lesions during radioimmunotherapy with 177Lu-cG250. Serial planar scintigrams after injection of 111In-cG250 or 177Lu-cG250 in patients with metastasized renal cell carcinoma were analyzed quantitatively. The estimated radiation doses were correlated with observed hematologic toxicity. In addition, the accuracy of the predicted therapeutic absorbed doses, based on diagnostic 111In-cG250 data, were determined. Methods: Twenty patients received a diagnostic tracer activity of 111In-cG250 (185 MBq), followed by radioimmunotherapy with 177Lu-cG250. The administered activity of 177Lu-cG250 was escalated by entering 3 patients at each activity level starting at 1,110 MBq/m2, with increments of 370 MBq/m2. After each diagnostic and therapeutic administration, whole-body scintigraphic images and pharmacokinetic data were acquired. Hematologic toxicity was graded using the Common Toxicity Criteria, version 3.0. Diagnostic 111In-cG250 data were used to simulate 177Lu and 90Y data by correcting for the difference in physical decay. Absorbed doses were calculated for the whole body, red marrow, organs, and tumor metastases for the therapeutic 177Lu-cG250, simulated 177Lu-cG250, and simulated 90Y-cG250 data. Results: Observed hematologic toxicity, especially platelet toxicity, correlated significantly with the administered activity (r = 0.85), whole-body absorbed dose (r = 0.65), and red marrow dose (r = 0.62 and 0.75). An inverse relationship between the mass and absorbed dose of the tumor lesions was observed. Calculated mean absorbed doses were similar for the simulated and measured 177Lu-cG250 data. Absorbed doses (whole body and red marrow) based on the simulated 177Lu-cG250 data correlated with the observed platelet toxicity (r = 0.65 and 0.82). The tumor–to–red marrow dose ratio was higher for radioimmunotherapy with 177Lu-cG250 than for radioimmunotherapy with 90Y-cG250, indicating that 177Lu has a wider therapeutic window for radioimmunotherapy with cG250 than 90Y. Conclusion: In patients with metastasized renal cell carcinoma, hematologic toxicity after treatment with 177Lu-cG250 can be predicted on the basis of administered activity and whole-body and red marrow–absorbed dose. Diagnostic 111In-cG250 data can be used to accurately predict absorbed doses and myelotoxicity of radioimmunotherapy with 177Lu-cG250. These estimations indicate that in these patients, higher radiation doses can be guided to the tumors with 177Lu-cG250 than with 90Y-cG250.