Population pharmacokinetic dosimetry model using imaging data to assess variability in pharmacokinetics of 177Lu‐PSMA‐617 in prostate cancer patients

Studies to evaluate and optimize [177 Lu]Lu-PSMA treatment focus primarily on individual patient data. A population pharmacokinetic (PK) dosimetry model was developed to explore the potential of using imaging data as input for population PK models and to characterize variability in organ and tumor uptake of [177 Lu]Lu-PSMA-617 in patients with low volume metastatic prostate cancer. Simulations were performed to identify the effect of dose adjustments on absorbed doses in salivary glands and tumors. A six-compartment population PK model was developed, consisting of blood, salivary gland, kidneys, liver, tumor, and a lumped compartment representing other tissue (compartment 1-6, respectively), based on data from 10 patients who received [177 Lu]Lu-PSMA-617 (2 cycles, ~ 3 and ~ 6 GBq). Data consisted of radioactivity levels (decay corrected) in blood and tissues (9 blood samples and 5 single photon emission computed tomography/computed tomography scans). Observations in all compartments were adequately captured by individual model predictions. Uptake into salivary glands was saturable with an estimated maximum binding capacity (Bmax ) of 40.4 MBq (relative standard error 12.3%) with interindividual variability (IIV) of 59.3% (percent coefficient of variation [CV%]). IIV on other PK parameters was relatively minor. Tumor volume was included as a structural effect on the tumor uptake rate constant (k15 ), where a two-fold increase in tumor volume resulted in a 1.63-fold increase in k15 . In addition, interoccasion variability on k15 improved the model fit (43.5% [CV%]). Simulations showed a reduced absorbed dose per unit administered activity for salivary glands after increasing radioactivity dosing from 3 to 6 GBq (0.685 Gy/GBq vs. 0.421 Gy/GBq, respectively). All in all, population PK modeling could help to improve future radioligand therapy research.

[1]  E. Rijkhorst,et al.  The Impact of Peptide Amount on Tumor Uptake to Assess PSMA Receptor Saturation on 68Ga-PSMA-11 PET/CT in Patients with Primary Prostate Cancer , 2022, The Journal of Nuclear Medicine.

[2]  C. Stokke,et al.  EANM dosimetry committee recommendations for dosimetry of 177Lu-labelled somatostatin-receptor- and PSMA-targeting ligands , 2022, European Journal of Nuclear Medicine and Molecular Imaging.

[3]  M. Hofman,et al.  Radiation Dosimetry in 177Lu-PSMA-617 Therapy. , 2021, Seminars in nuclear medicine.

[4]  Steffie M. B. Peters,et al.  Intra-therapeutic dosimetry of [177Lu]Lu-PSMA-617 in low-volume hormone-sensitive metastatic prostate cancer patients and correlation with treatment outcome , 2021, European Journal of Nuclear Medicine and Molecular Imaging.

[5]  Bjoern H Menze,et al.  Tumor Sink Effect in 68Ga-PSMA-11 PET: Myth or Reality? , 2021, The Journal of Nuclear Medicine.

[6]  K. Herrmann,et al.  The salivary glands as a dose limiting organ of PSMA- targeted radionuclide therapy: A review of the lessons learnt so far. , 2021, Nuclear medicine and biology.

[7]  H. Moch,et al.  What’s behind 68Ga-PSMA-11 uptake in primary prostate cancer PET? Investigation of histopathological parameters and immunohistochemical PSMA expression patterns , 2021, European Journal of Nuclear Medicine and Molecular Imaging.

[8]  M. Borre,et al.  Potential synergy between PSMA uptake and tumour blood flow for prediction of human prostate cancer aggressiveness , 2021, EJNMMI Research.

[9]  R. Hicks,et al.  Radiation Dosimetry in 177Lu-PSMA-617 Therapy Using a Single Posttreatment SPECT/CT Scan: A Novel Methodology to Generate Time- and Tissue-Specific Dose Factors , 2019, The Journal of Nuclear Medicine.

[10]  H. Wester,et al.  PSMA-Targeted Radiopharmaceuticals for Imaging and Therapy. , 2019, Seminars in nuclear medicine.

[11]  Daniela A. Ferraro,et al.  First Clinicopathologic Evidence of a Non–PSMA-Related Uptake Mechanism for 68Ga-PSMA-11 in Salivary Glands , 2019, The Journal of Nuclear Medicine.

[12]  E. Chatelut,et al.  Evaluation of the Interaction of Amino Acid Infusion on 177Lu-Dotatate Pharmacokinetics in Patients with Gastroenteropancreatic Neuroendocrine Tumors , 2019, Clinical Pharmacokinetics.

[13]  D. O’Keefe,et al.  A Perspective on the Evolving Story of PSMA Biology, PSMA-Based Imaging, and Endoradiotherapeutic Strategies , 2018, The Journal of Nuclear Medicine.

[14]  G. Glatting,et al.  The Effect of Total Tumor Volume on the Biologically Effective Dose to Tumor and Kidneys for 177Lu-Labeled PSMA Peptides , 2018, The Journal of Nuclear Medicine.

[15]  M. Karlsson,et al.  An automated sampling importance resampling procedure for estimating parameter uncertainty , 2017, Journal of Pharmacokinetics and Pharmacodynamics.

[16]  R. Bundschuh,et al.  Uptake of PSMA-ligands in normal tissues is dependent on tumor load in patients with prostate cancer. , 2017, Oncotarget.

[17]  M. Barras,et al.  Individualised medicine: why we need Bayesian dosing , 2017, Internal medicine journal.

[18]  U. Haberkorn,et al.  The Rise of PSMA Ligands for Diagnosis and Therapy of Prostate Cancer , 2016, The Journal of Nuclear Medicine.

[19]  Tim Holland-Letz,et al.  The Theranostic PSMA Ligand PSMA-617 in the Diagnosis of Prostate Cancer by PET/CT: Biodistribution in Humans, Radiation Dosimetry, and First Evaluation of Tumor Lesions , 2015, The Journal of Nuclear Medicine.

[20]  U. Haberkorn,et al.  Preclinical Evaluation of a Tailor-Made DOTA-Conjugated PSMA Inhibitor with Optimized Linker Moiety for Imaging and Endoradiotherapy of Prostate Cancer , 2015, The Journal of Nuclear Medicine.

[21]  W. Chongruksut,et al.  Correlation and diagnostic performance of the prostate-specific antigen level with the diagnosis, aggressiveness, and bone metastasis of prostate cancer in clinical practice , 2014, Prostate international.

[22]  B. Ristau,et al.  The prostate-specific membrane antigen: lessons and current clinical implications from 20 years of research. , 2014, Urologic oncology.

[23]  D R Mould,et al.  Basic Concepts in Population Modeling, Simulation, and Model-Based Drug Development—Part 2: Introduction to Pharmacokinetic Modeling Methods , 2013, CPT: pharmacometrics & systems pharmacology.

[24]  H. Carter Differentiation of lethal and non lethal prostate cancer: PSA and PSA isoforms and kinetics. , 2012, Asian journal of andrology.

[25]  Brigitte Vollmar,et al.  Regulation of hepatic blood flow: the hepatic arterial buffer response revisited. , 2010, World journal of gastroenterology.

[26]  Wesley E. Bolch,et al.  MIRD Pamphlet No. 21: A Generalized Schema for Radiopharmaceutical Dosimetry—Standardization of Nomenclature , 2009, Journal of Nuclear Medicine.

[27]  D. O’Keefe,et al.  Comparative analysis of prostate‐specific membrane antigen (PSMA) versus a prostate‐specific membrane antigen‐like gene , 2004, The Prostate.

[28]  M. H. Gault,et al.  Prediction of creatinine clearance from serum creatinine. , 1975, Nephron.

[29]  C. Cordon-Cardo,et al.  Prostate-specific membrane antigen expression in normal and malignant human tissues. , 1997, Clinical cancer research : an official journal of the American Association for Cancer Research.