Dose response of pancreatic neuroendocrine tumours treated with peptide receptor radionuclide therapy using 177Lu-DOTATATE (original) (raw)
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Journal of nuclear medicine : official publication, Society of Nuclear Medicine, 2015
Peptide receptor radionuclide therapy (PRRT) is a promising treatment for patients with neuroendocrine tumors, giving rise to improved survival. Dosimetric calculations in relation to PRRT have been concentrated to normal organ dosimetry in order to limit side effects. However, the relation between the absorbed dose to the tumor and treatment response has so far not been established. Better knowledge in this respect may improve the understanding of treatment effects, allow for improved selection of those patients who are expected to benefit from PRRT, and avoid unnecessary treatments. The aim of the present work was to evaluate the dose-response relationship for pancreatic neuroendocrine tumors treated with PRRT using (177)Lu-DOTATATE. Tumor-absorbed dose calculations were performed for 24 lesions in 24 patients with metastasized pancreatic neuroendocrine tumors treated with repeated cycles of (177)Lu-DOTATATE at 8-wk intervals. The absorbed dose calculations relied on sequential SP...
Physica Medica
Peptide receptor radionuclide therapy with 177 Lu-DOTATATE has become a standard treatment modality in neuroendocrine tumours (NETs). No consensus has yet been reached however regarding the absorbed dose threshold for lesion response, the absorbed dose limit to organs-at-risk, and the optimal fractionation and activity to be administered. This is partly due to a lack of uniform and comparable dosimetry protocols. The present article details the development of an organ-at-risk dosimetry procedure, which could be implemented and used routinely in a clinical context. Methods: Forty-seven patients with NETs underwent 177 Lu-DOTATATE therapy. Three SPECT/CT images were acquired at 4, 24 and 144-192 h post-injection. Three blood samples were obtained together with the SPECT/CT acquisitions and 2 additional samples were obtained around 30 min and 1 h post-injection. A bi-exponential fit was used to compute the source organ time-integrated activity coefficients. Coefficients were introduced into OLINDA/EXM software to compute organ-at-risk absorbed doses. Median values for all patients were computed for absorbed dose coefficient D A / 0 and for late effective half-life T 1/2eff for kidneys, spleen and red marrow. Results: Dosimetry resulted in a median[interquartile range] of 0.78[0.35], 1.07[0.58] and 0.028[0.010] Gy/ GBq for D A / 0 and of 55[9], 71[9] and 52[18] h for T 1/2eff for kidneys, spleen and red marrow respectively. Conclusions: A dosimetry procedure for organs-at-risk in 177 Lu-DOTATATE therapy based on serial SPECT/CT images and blood samples can be implemented routinely in a clinical context with limited patient burden. The results obtained were in accordance with those of other centres.
Acta Oncologica
Background: Fractionated therapy with 177 Lu-DOTATATE has been reported to be an effective treatment for patients with metastasized neuroendocrine tumors. To optimize the treatment, absorbed doses to risk organs are calculated for the individual patient. For each organ, absorbed dose due to activity in the organ itself (self-dose) and that originating from other organs (cross-dose) are calculated from serial measurements to obtain the activity distribution following treatment. The main aim of the present work were to calculate the cross-dose contribution to the total absorbed kidney dose. Methods: Five hundred patients with neuroendocrine tumors undergoing therapy with 177 Lu-DOTATATE were included. Scintigraphic planar whole body images and single photon emission computed tomography/computed tomography (SPECT/CT) over the abdomen were acquired at 1, 4 and 7 days after treatment. Kidney self-dose was calculated based on radioactivity distribution obtained from SPECT/CT. Cross-dose to kidneys was estimated using organ-based analysis of planar whole body images and cross-fire dose factors from Olinda/EXM 1.1. Results: Cross-dose to kidneys in the majority of patients were less than 2% and almost all cross-doses were less than 10%. Cross-dose exceeded 10% only in rare cases of patients with high tumor burden and low absorbed doses to kidneys. Conclusions: The absorbed dose from 177 Lu-octreotate to solid organs due to cross-fire is generally low and can usually be neglected.
EJNMMI Research
Background: This study's aim was to develop our dosimetric methodology using a commercial workstation for the routine evaluation of the organs at risk during peptide receptor radionuclide therapy (PRRT) with 177 Lu. Methods: First, planar and SPECT sensitivity factors were determined on phantoms. The reconstruction parameters were optimized by SPECT/CT image acquisition using a NEMA IEC phantom containing a 500 ml bottle of 177 Lu, to simulate a kidney. The recovery coefficients were determined on various phantoms. For the red marrow, this was calculated using a NEMA IEC phantom that contained a centrally placed bottle of 80 ml of 177 Lu (to model the L2-L4 red marrow) flanked by two 200 ml bottles with 177 Lu to simulate the kidneys. Then, SPECT/CT images were acquired at 4, 24, 72, and 192 h after injection in 12 patients with neuroendocrine tumors who underwent PRRT with 177 Lu-DOTATATE. SPECT data were reconstructed using the iterative ordered subset expectation maximization (OSEM) method, with six iterations and ten subsets, attenuation, scatter, recovery resolution corrections, and a Gaussian post-filter of 0.11 cm. The liver, spleen, kidneys, and red marrow dose per administered activity (AD/A admin) values were calculated with the Medical Internal Radiation Dose (MIRD) formalism and the residence times (Dosimetry toolkit® application) using standard and CT imaging-based organ masses (OLINDA/EXM® V1.0 software). Results: Sensitivity factors of 6.11 ± 0.01 and 5.67 ± 0.08 counts/s/MBq were obtained with planar and SPECT/CT acquisitions, respectively. A recovery coefficient of 0.78 was obtained for the modeled L2-L4 red marrow. The mean AD/A admin values were 0.43 ± 0.13 mGy/MBq [0.27-0.91] for kidneys, 0.54 ± 0.58 mGy/MBq [0.12-2.26] for liver, 0. 61 ± 0.13 mGy/MBq [0.42-0.89] for spleen, and 0.04 ± 0.02 mGy/MBq [0.01-0.09] for red marrow. The AD/A admin values varied when calculated using the personalized and standard organ mass, particularly for kidneys (p = 1 × 10 −7), spleen (p = 0.0069), and red marrow (p = 0.0027). Intra-patient differences were observed especially in organs close to or including tumor cells or metastases. Conclusions: The obtained AD/A admin values were in agreement with the literature data. This study shows the technical feasibility of patient dosimetry in clinical practice and the need to obtain patient-specific information.
EJNMMI Physics
Background Following each cycle of peptide receptor radionuclide therapy (PRRT), absorbed doses by tumors and normal organs are typically calculated from three quantitative single-photon emission computed tomography (SPECT)/computed tomography (CT) studies acquired at t1 = 24 h, t2 = 96 h, t3 = 168 h after the first cycle of treatment and from a single study at t1 after the subsequent cycles. In the present study, we have assessed the feasibility of a single SPECT/CT study after each PRRT cycle using a trained multiple linear regression (MLR) model for absorbed dose calculation and have evaluated its impact on patient management. Quantitative [177Lu]-DOTA-TATE SPECT/CT data after PRRT of seventy-two consecutive metastatic neuroendocrine tumors patients were retrospectively evaluated. A set of 40 consecutive studies was used to train the MLR model. The two independent variables of the model included the time of imaging after administration of the treatment and the radiopharmaceutical...
European Journal of Nuclear Medicine and Molecular Imaging, 2017
Purpose Peptide receptor radionuclide therapy (PRRT) with 177 Lu-octreotate is commonly administered at empiric, fixed amounts of injected radioactivity (IA). This results in highly variable absorbed doses to critical organs and suboptimal treatment of most patients. The primary aims of this study were to design a personalized PRRT (P-PRRT) protocol based on dosimetry, and to perform a simulation of this protocol in a retrospective cohort of patients with neuroendocrine tumours, in order to assess the potential of P-PRRT to safely increase the absorbed dose to the tumour during a four-cycle induction course. Methods Thirty-six patients underwent 122 fixed-IA 177 Luoctreotate PRRT cycles with quantitative SPECT/CT-based dosimetry. Twenty-two patients completed a four-cycle induction course (29.6 ± 2.4 GBq cumulative IA), with kidney, bone marrow and maximum tumour absorbed doses of 16.2 ± 5.5, 1.3 ± 0.8, and 114 ± 66 Gy, respectively. We simulated a P-PRRT regime in which the renal absorbed dose per IA was predicted by the body surface area and glomerular filtration rate for the first cycle, and by renal dosimetry of the previous cycle(s) for the following cycles. Personalized IA was adjusted at each cycle in order to reach the prescribed renal absorbed dose of 23 Gy over four cycles (with a 25-50% reduction when renal or bone marrow function was impaired). Simulated IA and absorbed doses were based on actual patient characteristics, laboratory values and absorbed doses per IA delivered at each cycle. Results In the P-PRRT regime, cumulative IA could have been increased to 43.7 ± 16.5 GBq over four induction cycles (10.9 ± 5.0 GBq per cycle), yielding cumulative kidney, bone marrow and maximum tumour absorbed doses of 21.5 ± 2.5, 1.63 ± 0.61, and 163.4 ± 85.9 Gy, respectively. This resulted in an average 1.48-fold increase in cumulative maximum tumour absorbed dose over empiric PRRT (range, 0.68-2.64fold; P = 0.0013). Conclusion By standardizing the renal absorbed dose delivered during the induction course, P-PRRT has the potential to significantly increase tumour absorbed dose, thus to augment the therapeutic benefit while limiting toxicity.
European journal of nuclear medicine and molecular imaging, 2018
Peptide receptor radionuclide therapy (PRRT) with Y-labelled and Lu-labelled peptides is an effective strategy for the treatment of metastatic/nonresectable neuroendocrine tumours (NETs). Dosimetry provides important information useful for optimizing PRRT with individualized regimens to reduce toxicity and increase tumour responses. However, this strategy is not applied in routine clinical practice, despite the fact that several dosimetric studies have demonstrated significant dose-effect correlations for normal organ toxicity and tumour response that can better guide therapy planning. The present study reviews the key relationships and the radiobiological models available in the literature with the aim of providing evidence that optimization of PRRT is feasible through the implementation of dosimetry. The MEDLINE database was searched combining specific keywords. Original studies published in the English language reporting dose-effect outcomes in patients treated with PRRT were cho...
Cancer, 2010
BACKGROUND: 177 Lu-(DOTA0,Tyr3) octreotate is a new treatment modality for disseminated neuroendocrine tumors. According to a consensus protocol, the calculated maximally tolerated absorbed dose to the kidney should not exceed 27 Gy. In commonly used dosimetry methods, planar imaging is used for determination of the residence time, whereas the kidney mass is determined from a computed tomography (CT) scan. METHODS: Three different quantification methods were used to evaluate the absorbed dose to the kidneys. The first method involved common planar activity imaging, and the absorbed dose was calculated using the medical internal radiation dose (MIRD) formalism, using CT scan-based kidney masses. For this method, 2 region of interest locations for the background correction were investigated. The second method also included single-photon emission computed tomography (SPECT) data, which were used to scale the amplitude of the time-activity curve obtained from planar images. The absorbed dose was calculated as in the planar method. The third method used quantitative SPECT images converted to absorbed dose rate images, where the median absorbed dose rate in the kidneys was calculated in a volume of interest defined over the renal cortex. RESULTS: For some patients, the results showed a large difference in calculated kidneyabsorbed doses, depending on the dosimetry method. The 2 SPECT-based methods generally gave consistent values, although the calculations were based on different assumptions. Dosimetry using the baseline planar method gave higher absorbed doses in all patients. The values obtained from planar imaging with a background region of interest placed adjacent to the kidneys were more consistent with dosimetry also including SPECT. For the accumulated tumor absorbed dose, the first 2 of the 4 planned therapy cycles made the major contribution. CONCLUSIONS: The results suggested that patients evaluated according to the conventional planar-based dosimetry method may have been undertreated compared with the other methods. Hematology and creatinine did not indicate any restriction for a more aggressive approach, which would be especially useful in patients with more aggressive tumors where there is not time for more protracted therapy. Cancer 2010;116(4 suppl):1084-92.
Calculation of absorbed dose due to the 90Y-DOTATOC peptide receptor radionuclide therapy by MCNP5/X
Nuclear Technology and Radiation Protection, 2018
Strong beta emitters, like 90Y, 177Lu labelled peptide, are used for treatment of neuroendocrine tumours where there is a good expression of somatostatin receptors. In this work, MCNP5/X computer software and ORNL human phantoms were used to calculate absorbed dose due to 90Y labelled DOTATOC in the peptide receptor radionuclide therapy. Tumour was considered as a sources of beta radiation and represented as a sphere with diameter of 1-4 cm and 5 cm in liver, pancreas, and lungs. Results are expressed as absorbed dose per unit of cumulated activity, S ? value in units mGy?(MBq?s)?1. The far largest dose is in tumour itself, then in organ which contains the tumour. Doses in other organs, where the metastasis are the most frequent, due to the bremsstrahlung radiation, are much smaller and could be neglected. The largest dose, 8.66?10?3 mGy?(MBq?s)?1 was obtained for tumour with size of 3 cm.