Kidney dosimetry in ¹⁷⁷Lu and ⁹⁰Y peptide receptor radionuclide therapy: influence of image timing, time-activity integration method, and risk factors

F Guerriero, M E Ferrari, F Botta, F Fioroni, E Grassi, A Versari, A Sarnelli, M Pacilio, E Amato, L Strigari, L Bodei, G Paganelli, M Iori, G Pedroli, M Cremonesi, F Guerriero, M E Ferrari, F Botta, F Fioroni, E Grassi, A Versari, A Sarnelli, M Pacilio, E Amato, L Strigari, L Bodei, G Paganelli, M Iori, G Pedroli, M Cremonesi

Abstract

Kidney dosimetry in (177)Lu and (90)Y PRRT requires 3 to 6 whole-body/SPECT scans to extrapolate the peptide kinetics, and it is considered time and resource consuming. We investigated the most adequate timing for imaging and time-activity interpolating curve, as well as the performance of a simplified dosimetry, by means of just 1-2 scans. Finally the influence of risk factors and of the peptide (DOTATOC versus DOTATATE) is considered. 28 patients treated at first cycle with (177)Lu DOTATATE and 30 with (177)Lu DOTATOC underwent SPECT scans at 2 and 6 hours, 1, 2, and 3 days after the radiopharmaceutical injection. Dose was calculated with our simplified method, as well as the ones most used in the clinic, that is, trapezoids, monoexponential, and biexponential functions. The same was done skipping the 6 h and the 3 d points. We found that data should be collected until 100 h for (177)Lu therapy and 70 h for (90)Y therapy, otherwise the dose calculation is strongly influenced by the curve interpolating the data and should be carefully chosen. Risk factors (hypertension, diabetes) cause a rather statistically significant 20% increase in dose (t-test, P < 0.10), with DOTATATE affecting an increase of 25% compared to DOTATOC (t-test, P < 0.05).

Figures

Figure 1
Figure 1
Examples of observed pharmacokinetic behaviour: with-accumulation (blue line, pt no. 45), single-slope clearance (red line, pt no. 43), two-slope clearance (violet line, pt no. 38).
Figure 2
Figure 2
177Lu (a) and 90Y (b) time-integrated activities a~ in hours for methods TRph, TRexp, BI, MN, MNfix, VIS, FT. Boxes draw the 25th percentile (lower box bound, indicating 25th of data fall below it), 50th percentile (i.e., median value), and 75th percentile (upper box bound). Crosses indicate outliers defined as observations out of 1.5 · (75th percentile value −25th percentile value). Whiskers extend to the most extreme values that are not outliers.
Figure 3
Figure 3
Relative difference of a~ values for 177Lu-DOTATATE between MN and BI methods y=(a~MN-a~BI  )/a~BI plotted against the relative difference of the squared residuals SSE x = (SSEMN − SSEBI)/SSEBI.
Figure 4
Figure 4
177Lu a~FT and a~VIS for the cases in which there was a discrepancy greater than 10% between the visual and the F-test (8 cases for TATE, 11 for TOC).
Figure 5
Figure 5
(a) pt no. 35 177Lu DOTATATE: MNfix and BI obtained with all experimental points (red and violet lines, resp.) and MN and BI skipping the 3 d point (green and blue lines, resp.); (b) pt no. 45 177Lu DOTATOC: MN and BI obtained with all experimental points (red and violet lines, resp.) and BI skipping the 6 h point (blue line).
Figure 6
Figure 6
D and BED in case of 177Lu therapy (upper panels) and 90Y therapy (lower panels). The histograms report mean and 1 SD. 177Lu and 90Y-therapy administer a similar total dose for the specific schemes considered (29.8 GBq in 4 cycles versus 7.4 GBq in 2 cycles, resp.). Conversely, BED is noticeably greater for 90Y because of the lower fractionation. Mean ± SD values are similar, but relevant differences among patients can be found (see also Figure 4).
Figure 7
Figure 7
Time-integrated activity per unit activity a~ for patients with risk factors (RF) (diamonds) and without (NRF) (dots). For each population, the mean value is indicated by the horizontal line, and the box extends to mean ± SD. For DOTATATE, 11 patients were RF and 17 NRF, and the P-values of t-test were 0.05 and 0.06, for 177Lu and 90Y, respectively. For DOTATOC, 12 patients were RF and 17 NRF (one outlier was excluded), and P-values were 0.09 and 0.06, for 177Lu and 90Y, respectively.

References

    1. Kwekkeboom DJ, Kam BL, Van Essen M, et al. Somatostatin receptor-based imaging and therapy of gastroenteropancreatic neuroendocrine tumors. Endocrine-Related Cancer. 2010;17(1):R53–R73.
    1. Glatting G, Kletting P, Reske SN, Hohl K, Ring C. Choosing the optimal fit function: comparison of the Akaike information criterion and the F-test. Medical Physics. 2007;34(11):4285–4292.
    1. Cremonesi M, Botta F, Di Dia A, et al. Dosimetry for treatment with radiolabelled somatostatin analogues. A review. Quarterly Journal of Nuclear Medicine and Molecular Imaging. 2010;54(1):37–51.
    1. Esser JP, Krenning EP, Teunissen JJM, et al. Comparison of [177Lu-DOTA0,Tyr3] octreotate and [177Lu-DOTA0,Tyr3] octreotide: which peptide is preferable for PRRT? European Journal of Nuclear Medicine and Molecular Imaging. 2006;33(11):1346–1351.
    1. Sandström M, Garske U, Granberg D, Sundin A, Lundqvist H. Individualized dosimetry in patients undergoing therapy with 177Lu-DOTA-D-Phe1-Tyr3-octreotate. European Journal of Nuclear Medicine and Molecular Imaging. 2010;37(2):212–225.
    1. Baechler S, Hobbs RF, Boubaker A, et al. Three-dimensional radiobiological dosimetry of kidneys for treatment planning in peptide receptor radionuclide therapy. Medical Physics. 2012;39:6118–6128.
    1. Garkavij M, Nickel M, Sjögreen-Gleisner K, et al. 177Lu-[DOTA0,Tyr3] octreotate therapy in patients with disseminated neuroendocrine tumors: analysis of dosimetry with impact on future therapeutic strategy. Cancer. 2010;116(4):1084–1092.
    1. Konijnenberg M. From imaging to dosimetry and biological effects. Quarterly Journal of Nuclear Medicine and Molecular Imaging. 2011;55(1):44–56.
    1. Larsson M, Bernhardt P, Svensson JB, Wängberg BW, Ahlman H, Forssell-Aronsson E. Estimation of absorbed dose to the kidneys in patients after treatment with 177Lu-octreotate: comparison between methods based on planar scintigraphy. EJNMMI Research. 2012;2:49–53.
    1. Grassi E, Sghedoni R, Asti M, Fioroni F, Salvo D, Borasi G. Radiation protection in 90Y-labelled DOTA-D-Phe1-Tyr3-octreotide preparations. Nuclear Medicine Communications. 2009;30(2):176–182.
    1. Sghedoni R, Grassi E, Fioroni F, et al. Personnel exposure in labelling and administration of 177Lu- DOTA-D-Phe1-Tyr3-octreotide. Nuclear Medicine Communications. 2011;32(10):947–953.
    1. Bodei L, Cremonesi M, Ferrari M, et al. Long-term evaluation of renal toxicity after peptide receptor radionuclide therapy with 90Y-DOTATOC and 177Lu-DOTATATE: the role of associated risk factors. European Journal of Nuclear Medicine and Molecular Imaging. 2008;35(10):1847–1856.
    1. Filice A, Fraternali A, Frasoldati A, et al. Radiolabeled somatostatin analogues therapy in advanced neuroendocrine tumors: a single centre experience. Journal of Oncology. 2012;2012:10 pages.320198
    1. Walrand S, Hanin FX, Pauwels S, Jamar F. Tumour control probability derived from dose distribution in homogeneous and heterogeneous models: assuming similar pharmacokinetics, 125Sn-177Lu is superior to 90Y-177Lu in peptide receptor radiotherapy. Physics in Medicine and Biology. 2012;57(13):4263–4275.
    1. Stabin MG, Sparks RB, Crowe E. OLINDA/EXM: the second-generation personal computer software for internal dose assessment in nuclear medicine. Journal of Nuclear Medicine. 2005;46(6):1023–1027.
    1. Spiess A-N, Neumeyer N. An evaluation of R2 as an inadequate measure for nonlinear models in pharmacological and biochemical research: a monte carlo approach. BMC Pharmacology. 2010;10, article 6
    1. Baechler S, Hobbs RF, Prideaux AR, Wahl RL, Sgouros G. Extension of the biological effective dose to the MIRD schema and possible implications in radionuclide therapy dosimetry. Medical Physics. 2008;35(3):1123–1134.
    1. Wessels BW, Konijnenberg MW, Dale RG, et al. MIRD pamphlet no. 20: the effect of model assumptions on kidney dosimetry and response—implications for radionuclide therapy. Journal of Nuclear Medicine. 2008;49(11):1884–1899.
    1. Hobbs RF, Sgouros G. Calculation of the biological effective dose for piecewise defined dose-rate fits. Medical Physics. 2009;36(3):904–907.
    1. Imhof A, Brunner P, Marincek N, et al. Response, survival, and long-term toxicity after therapy with the radiolabeled somatostatin analogue [90Y-DOTA]-TOC in metastasized neuroendocrine cancers. Journal of Clinical Oncology. 2011;29(17):2416–2423.
    1. Walrand S, Barone R, Pauwels S, Jamar F. Experimental facts supporting a red marrow uptake due to radiometal transchelation in 90Y-DOTATOC therapy and relationship to the decrease of platelet counts. European Journal of Nuclear Medicine and Molecular Imaging. 2011;38(7):1270–1280.
    1. Konijnenberg MW. Is the renal dosimetry for [90Y-DOTA0, Tyr3]octreotide accurate enough to predict thresholds for individual patients? Cancer Biotherapy and Radiopharmaceuticals. 2003;18(4):619–625.
    1. He B, Wahl RL, Sgouros G, et al. Comparison of organ residence time estimation methods for radioimmunotherapy dosimetry and treatment planning-patient studies. Medical Physics. 2009;36(5):1595–1601.
    1. Jackson A, Kutcher GJ, Yorke ED. Probability of radiation-induced complications for normal tissues with parallel architecture subject to non-uniform irradiation. Medical Physics. 1993;20(3):613–625.
    1. Hindorf C, Chittenden S, Causer L, Lewington VJ, Mäcke HR, Flux GD. Dosimetry for 90Y-DOTATOC therapies in patients with neuroendocrine tumors. Cancer Biotherapy and Radiopharmaceuticals. 2007;22(1):130–135.
    1. Lassmann M, Chiesa C, Flux G, Bardiès M. EANM Dosimetry Committee guidance document: good practice of clinical dosimetry reporting. European Journal of Nuclear Medicine and Molecular Imaging. 2011;38(1):192–200.
    1. Kletting P, Kull T, Reske SN, Glatting G. Comparing time activity curves using the Akaike information criterion. Physics in Medicine and Biology. 2009;54(21):N501–N507.
    1. Grassi E, Fioroni F, Sarti MA, et al. Validation of a voxel-based method for dosimetry in radionuclide therapy and comparison with a conventional tridimensional approach. Proceedings of the 25th Annual Meeting of the EANM; October 2012; pp. 27–31.
    1. Svensson J, Hermann R, Larsson M, et al. Impairment in renal function predicts higher mean absorbed kidney doses in peptide receptor radionuclide therapy. Proceedings of the 25th Annual Meeting of the EANM; October 2012; pp. 27–31.

Source: PubMed

Спонсоры и соавторы

Заболевания

Медикаментозные вмешательства

Подписаться