External radiation exposure, excretion, and effective half-life in 177Lu-PSMA-targeted therapies.

BACKGROUND: Prostate-specific membrane antigen (PSMA)-targeted therapy with 177Lu-PSMA-617 is a therapeutic option for patients with metastatic castration-resistant prostate cancer (mCRPC). To optimize the therapy procedure, it is necessary to determine relevant parameters to define radiation protection and safety necessities. Therefore, this study aimed at estimating the ambient radiation exposure received by the patient. Moreover, the excreted activity was quantified. RESULTS: In total, 50 patients with mCRPC and treated with 177Lu-PSMA-617 (mean administered activity 6.3 ± 0.5 GBq) were retrospectively included in a bi-centric study. Whole-body dose rates were measured at a distance of 2 m at various time points after application of 177Lu-PSMA-617, and effective half-lives for different time points were calculated and compared. Radiation exposure to the public was approximated using the dose integral. For the estimation of the excreted activity, whole body measurements of 25 patients were performed at 7 time points. Unbound 177Lu-PSMA-617 was rapidly cleared from the body. After 4 h, approximately 50% and, after 12 h, approximately 70% of the administered activity were excreted, primarily via urine. The mean dose rates were the following: 3.6 ± 0.7 µSv/h at 2 h p. i., 1.6 ± 0.6 µSv/h at 24 h, 1.1 ± 0.5 µSv/h at 48 h, and 0.7 ± 0.4 µSv/h at 72 h. The mean effective half-life of the cohort was 40.5 ± 9.6 h (min 21.7 h; max 85.7 h). The maximum dose to individual members of the public per treatment cycle was ~ 250 ± 55 µSv when the patient was discharged from the clinic after 48 h and ~ 190 ± 36 µSv when the patient was discharged after 72 h. CONCLUSIONS: In terms of the radiation exposure to the public, 177Lu-PSMA is a safe option of radionuclide therapy. As usually four (sometimes more) cycles of the therapy are performed, it must be conducted in a way that ensures that applicable legal requirements can be followed. In other words, the radiation exposure to the public and the concentration of activity in wastewater must be sub-marginal. Therefore, in certain countries, hospitalization of these patients is mandatory.

Role of choline PET/CT in guiding target volume delineation for irradiation of prostate cancer.

Choline PET/CT has shown limitations for the detection of primary prostate cancer and nodal metastatic disease, mainly due to limited sensitivity and specificity. Conversely in the restaging of prostate cancer recurrence, choline PET/CT is a promising imaging modality for the detection of local regional and nodal recurrence with an impact on therapy management. This review highlights current literature on choline PET/CT for radiation treatment planning in primary and recurrent prostate cancer. Due to limited sensitivity and specificity in differentiating between benign and malignant prostatic tissues in primary prostate cancer, there is little enthusiasm for target volume delineation based on choline PET/CT. Irradiation planning for the treatment of single lymph node metastases on the basis of choline PET/CT is controversial due to its limited lesion-based sensitivity in primary nodal staging. In high-risk prostate cancer, choline PET/CT might diagnose lymph node metastases, which potentially can be included in the conventional irradiation field. Prior to radiation treatment of recurrent prostate cancer, choline PET/CT may prove useful for patient stratification by excluding distant disease which would require systemic therapy. In patients with local recurrence, choline PET/CT can be used to delineate local sites of recurrence within the prostatic resection bed allowing a boost to PET-positive sites. In patients with lymph node metastases outside the prostatic fossa and regional metastatic lymph nodes, choline PET/CT might influence radiation treatment planning by enabling extension of the target volume to lymphatic drainage sites with or without a boost to PET-positive lymph nodes. Further clinical randomized trials are required to assess treatment outcomes following choline-based biological radiation treatment planning in comparison with conventional radiation treatment planning.

[[¹¹C]choline as a pharmacodynamic marker for docetaxel therapy. Response assessment in a LNCaP prostate cancer xenograft mouse model]. / Ansprechen auf eine Docetaxeltherapie im LNCaP-Prostatakarzinom-Xenograft-Mausmodell. Untersuchung mit der [¹¹C]Cholin-Kleintier-PET/CT.

UNLABELLED: The AIM of this study was to determine whether [¹¹C]choline can be used for docetaxel therapy response assessment in a LNCaP-prostate cancer xenograft mouse model using [¹¹C]choline small-animal PET/CT. ANIMALS, METHODS: The androgen-dependent human prostate cancer cell line LNCaP was implanted subcutaneously into the left flanks of 17 SCID-mice, 12.5 mg testosterone platelets were implanted in the neck wrinkle. All mice were injected 4-6 weeks after xenograft implantation with 37 MBq [¹¹C]choline via the tail vein. Dynamic imaging was performed for 60 minutes with a small-animal PET/CT scanner. After the first [¹¹C]choline PET/CT imaging 8 mice were subsequently injected intravenously with docetaxel twice (days 1 and 5) at a dose of 3 mg/kg body weight. 8 mice were treated with PBS as a control. [¹¹C]choline PET/CT imaging was performed on day 7, 14 and 21 after treatment. Image analysis was performed using tumor/muscle (T/M) ratios (ROI(T)/ROI(M) = T/M ratio). RESULTS: All LNCaP tumours could be visualized by [¹¹C]choline PET/CT. Before treatment the mean T/M ratio was 2.0 ± 0.2 in the docetaxel-treated group and 1.9 ± 0.2 in the control group (p = 0.837). There was a reduction in the mean [¹¹C]choline uptake after docetaxel treatment of the tumours of the LNCaP cell line as early as 1 week after initiation of therapy (T/M(mean) ratio 1.5 ± 0.2 after one week, 1.3 ± 0.2 after 2 weeks and 1.4 ± 0.2 after 3 weeks). There was no decrease in [¹¹C]choline uptake in the control group. CONCLUSION: Our results show that [¹¹C]choline has the potential for use in the early monitoring of the therapeutic effect of docetaxel in a LNCaP prostate cancer xenograft animal model.

PET/CT and choline: diagnosis and staging.

As prostate cancer is the most prevalent form of cancer in men and constitutes the third most common cause of cancer associated deaths, early diagnosis of primary prostate cancer and accurate staging influencing the appropriate choice of therapy is crucial. PET and PET/CT using [11C]- and [18F]-labelled choline derivates are increasingly being used for imaging primary and recurrent prostate cancer. The value of [11C]- and [18F]choline PET and PET/CT in patients with biochemical recurrence of prostate cancer has been evaluated in many studies and shows an increasing importance. Morphological imaging techniques such as TRUS, CT and MRI (including functional imaging tools) have shown only limited accuracy for the diagnosis of primary prostate cancer. Molecular imaging techniques such as PET and PET/CT may improve the detection rate and localization of primary prostate cancer. The potential of PET/CT using [11C]- and [18F]-labelled choline derivates for the diagnosis of primary prostate cancer has been assessed in a lot of studies with partly controversial results. [11C]- and [18F]choline PET and PET/CT demonstrated moderate sensitivity for the detection of primary prostate cancer, which depends on the tumour configuration. Furthermore the detection rate is limited by a considerable number of microcarcinomas that can often not be visualized due to partial volume effects. Therefore small and in part rind-like tumours can often not be detected. Additionally, specificity of [11C]- and [18F]choline PET and PET/CT is limited as differentiation between benign prostatic changes like prostatitis, prostatic hyperplasia and high-grade intraepithelial neoplasia (HGPIN) is not always possible. At the present time, the routine use of PET/CT with [11C]- and [18F]-labelled choline derivates can not be recommended as a first-line screening procedure for primary prostate cancer in men at risk. However, choline PET and PET/CT may be useful in preparation of a focused re-biopsy in patients suffering from clinically suspected prostate cancer with repeatedly negative prostate biopsies. In the future [11C]- and [18F]choline PET and PET/CT may also be helpful in patient stratification with respect to primary surgery and radiation therapy.

Choline PET and PET/CT in Primary Diagnosis and Staging of Prostate Cancer.

PET and PET/CT using [(11)C]- and [(18)F]-labelled choline derivates is increasingly being used for imaging of primary and recurrent prostate cancer. While PET and PET/CT with [(11)C]- and [(18)F]-labelled choline derivates in patients suffering from biochemical recurrence of prostate cancer has been examined in many studies that demonstrate an increasing importance, its role in the primary staging of prostate cancer is still a matter of debate.Morphological and functional imaging techniques such as CT, MRI and TRUS have demonstrated only limited accuracy for the diagnosis of primary prostate cancer. Molecular imaging with PET and PET/CT could potentially increase accuracy to localize primary prostate cancer. A considerable number of studies have examined the value of PET/CT with [(11)C]- and [(18)F]- labelled choline derivates for the diagnosis of primary prostate cancer with mixed results. Primary prostate cancer can only be detected with moderate sensitivity using [(11)C]- and [(18)F]choline PET and PET/CT. The detection rate depends on the tumour configuration. Detection is also limited by a considerable number of microcarcinomas that cannot be detected due to partial volume effects. Therefore small and in part rind-like tumours can often not be visualized. Furthermore, the differentiation between benign changes like prostatitis, high-grade intraepithelial neoplasia (HGPIN) or prostatic hyperplasia is not always possible. Therefore, at the present time, the routine use of PET/CT with [(11)C]- and [(18)F]-labelled choline derivates cannot be recommended as a first-line screening procedure for primary prostate cancer in men at risk. A potential application of choline PET and PET/CT may be to increase the detection rate of clinically suspected prostate cancer with multiple negative prostate biopsies, for example in preparation of a focused re-biopsy and may play a role in patient stratification with respect to primary surgery and radiation therapy in the future.

[Tracers in oncology - preclinical and clinical evaluation]. / Innovative Tracer in der onkologischen Diagnostik. Präklinische und klinische Evaluierung.

UNLABELLED: In oncology, PET and PET/CT with tracers beyond FDG target more specific biological processes, such as proliferation (18F-3´-fluoro-3´-deoxy-L-thymidine; 18F-FLT), tumour hypoxia (18F-fluoromisonidazol; 18F-FMISO) and phospholipid metabolism (radioactively labelled choline derivates). FLT is a thymidine analogue which can be labelled with 18F. PET with 18F-FLT enables to non-invasively image and to quantify the proliferation fraction of tumours. Proliferation dependent accumulation of FLT has been demonstrated for a variety of solid and haematologic neoplasms including lung cancer, breast cancer, gastric cancer, colorectal cancer and malignant lymphoma. Furthermore, FLT has been suggested as surrogate marker for the assessment of response to treatment, especially when targeted drugs are utilized. PET imaging in particular has emerged as a promising non-invasive tool to accurately characterize tumour oxygenation. The great promise of PET/CT is its potential as a single imaging modality for whole body staging that provides anatomical and biological information on the disease as a whole. It allows a more precise estimation of the hypoxic tumour volume as well as comparisons on a voxel-by-voxel basis (parametric mapping). PET and PET/CT with hypoxia tracers thus offer the potential to optimize and individualize therapy for patients suffering from cancer. PET- and PET/CT-studies using 11C- or 18F-labeled choline derivates recently have shown promising results for re-staging prostate cancer in patients with biochemical recurrence and advanced prostate cancer. In patients with biochemical recurrence of prostate cancer after primary therapy the detection rate of 11C-choline-PET/CT shows a positive relationship with serum PSA-levels. In these patients 11C-choline PET/CT allows not only to diagnose but also to localize recurrent disease with implications on disease management (localised vs. systemic therapy). CONCLUSION: The clinical success of multimodal imaging with PET/CT is expected to promote the combination of MRI and PET in the future.