Improving radiopeptide pharmacokinetics by adjusting experimental conditions for bombesin receptor-targeted imaging of prostate cancer.

AIM: Prostate cancer (PC) is a major health problem. The Gastrin-Releasing Peptide Receptor (GRPR) offers a promising target for staging and monitoring of PC since it is overexpressed in PC and not in normal prostatic tissue. To improve receptor-mediated imaging we investigated the impact of various experimental conditions on pharmacokinetics using the Indium-111 labelled bombesin (BN) analogue AMBA. Besides frequently used androgen-resistant PC-3 also the clinically more relevant androgen sensitive VCaP celline was used as human PC xenograft in nude mice. METHODS: Non-purified [111In]AMBA was compared with HPLC-purified [111In]AMBA. Effect of specific activity was studied administering 0.1MBq [111In]AMBA supplemented with different amounts of AMBA (1-3000pmol). GRPR was saturated with Tyr4-BN 1 and 4h prior to injection of [111In]AMBA. RESULTS: GRPR-positive tissue showed a significant 2 to 3-fold increase in absolute uptake after HPLC-purification while keeping a stable tumor-to-pancreas ratio. Lowering specific activity resulted in decline in uptake to 43% in tumor, 49% in kidney and 92% in pancreas between 10 and 3000 pmol. Tumor-to-pancreas ratio improved six-fold from 0.1±0 after 10 pmol up to 0.6±0.2 after 3000 pmol (P<0.01). When saturating GRPR 4h prior to [111In]AMBA injection tumor-to-pancreas ratio improved from 0.10±0.3 to 0.22±0.2 (P<0.01) and tumor-to-kidney ratio increased from 0.92±0.16 to 3.45±0.5 (P<0.01). CONCLUSION: Besides specific peptide characteristics also the experimental conditions, such as HPLC-purification, variations in specific activity and saturation of the GRPR prior to [111In]AMBA administration essentially affect radiopeptide pharmacokinetics. Experimental conditions therefore need to be carefully selected in order to compose ideal standardised protocols for optimal targeting.

Gastrin-releasing peptide receptor-based targeting using bombesin analogues is superior to metabolism-based targeting using choline for in vivo imaging of human prostate cancer xenografts.

PURPOSE: Prostate cancer (PC) is a major health problem. Overexpression of the gastrin-releasing peptide receptor (GRPR) in PC, but not in the hyperplastic prostate, provides a promising target for staging and monitoring of PC. Based on the assumption that cancer cells have increased metabolic activity, metabolism-based tracers are also being used for PC imaging. We compared GRPR-based targeting using the (68)Ga-labelled bombesin analogue AMBA with metabolism-based targeting using (18)F-methylcholine ((18)F-FCH) in nude mice bearing human prostate VCaP xenografts. METHODS: PET and biodistribution studies were performed with both (68)Ga-AMBA and (18)F-FCH in all VCaP tumour-bearing mice, with PC-3 tumour-bearing mice as reference. Scanning started immediately after injection. Dynamic PET scans were reconstructed and analysed quantitatively. Biodistribution of tracers and tissue uptake was expressed as percent of injected dose per gram tissue (%ID/g). RESULTS: All tumours were clearly visualized using (68)Ga-AMBA. (18)F-FCH showed significantly less contrast due to poor tumour-to-background ratios. Quantitative PET analyses showed fast tumour uptake and high retention for both tracers. VCaP tumour uptake values determined from PET at steady-state were 6.7 ± 1.4%ID/g (20-30 min after injection, N = 8) for (68)Ga-AMBA and 1.6 ± 0.5%ID/g (10-20 min after injection, N = 8) for (18)F-FCH, which were significantly different (p <0.001). The results in PC-3 tumour-bearing mice were comparable. Biodistribution data were in accordance with the PET results showing VCaP tumour uptake values of 9.5 ± 4.8%ID/g (N = 8) for (68)Ga-AMBA and 2.1 ± 0.4%ID/g (N = 8) for (18)F-FCH. Apart from the GRPR-expressing organs, uptake in all organs was lower for (68)Ga-AMBA than for (18)F-FCH. CONCLUSION: Tumour uptake of (68)Ga-AMBA was higher while overall background activity was lower than observed for (18)F-FCH in the same PC-bearing mice. These results suggest that peptide receptor-based targeting using the bombesin analogue AMBA is superior to metabolism-based targeting using choline for scintigraphy of PC.

Molecular imaging of reduced renal uptake of radiolabelled [DOTA0,Tyr3]octreotate by the combination of lysine and Gelofusine in rats.

AIM: In peptide receptor radionuclide therapy (PRRT) using radiolabelled somatostatin analogues, kidney uptake of radiolabelled compound is the major dose-limiting factor. We studied the effects of Gelofusine (20 mg) and lysine (100 mg) and the combination of both after injection of therapeutic doses of radiolabelled [DOTA0,Tyr3]octreotate (60 MBq 111In or 555 MBq 177Lu labelled to 15 microg peptide) in male Lewis rats. METHODS: Kidney uptake was measured by single photon emission computed tomography (SPECT) scans with a four-headed multi-pinhole camera (NanoSPECT) at 24 h, 5 and 7 days p. i. and was quantified by volume of interest analysis. For validation the activity concentration in the dissected kidneys was also determined ex vivo using a gamma counter and a dose calibrator. RESULTS: Gelofusine and lysine both reduced kidney uptake of [177Lu-DOTA0,Tyr3]octreotate significantly by about 40% at all time points. The combination of Gelofusine and lysine resulted in a 62% inhibition of kidney uptake (p < 0.01 vs. lysine alone). A weak but significant dose-response relationship for Gelofusine, but not for lysine, was found. In a study with [111In-DOTA0,Tyr3]octreotate, conclusions drawn from NanoSPECT data were confirmed by biodistribution data. CONCLUSIONS: We conclude that rat kidney uptake of radiolabelled somatostatin analogues can be monitored for a longer period in the same animal using animal SPECT. Gelofusine and lysine had equal potential to reduce kidney uptake of therapeutic doses of [177Lu-DOTA0,Tyr3]octreotate. The combination of these compounds caused a significantly larger reduction than lysine or Gelofusine alone and may therefore offer new possibilities in PRRT. The NanoSPECT data were validated by standard biodistribution experiments.

Radiolabelled regulatory peptides for imaging and therapy.

Radiolabelled peptides have shown to be an important class of radiopharmaceuticals for imaging and therapy of malignancies expressing receptors of regulatory peptides. These peptides have high affinity and specificity for their receptors. The majority of these receptors are present at different levels in different tissues and tumours. This review focuses on the application of regulatory peptides radiolabelled with (67/68)Ga, (90)Y, (111)In or (177)Lu. Due attention is given to the current status of research, limitations and future perspectives of the application of these radiolabelled peptides for imaging and radiotherapy. It also covers elements of the basic science and preclinical and clinical aspects in general, however, mostly based on somatostatin receptor-mediated imaging and therapy. New analogues, chelators, radionuclides and combinations thereof are discussed.

Practical aspects of peptide receptor radionuclide therapy with [177Lu][DOTA0, Tyr3]octreotate.

Lutetium-177 is increasingly used in patients for receptor-targeted radionuclide therapy with peptides such as [DOTA0,Tyr3]octreotate. In our therapy facility, we are performing yearly 400 treatments with each 7.4 GBq [177Lu][DOTA0,Tyr3]octreotate. Finger dosimetry data during radiolabeling reveal higher doses on the right hands of right-handed workers with the highest equivalent dose for the middle finger (53+/-12 microSv/GBq). Extrapolating dosimetry data, assuming 400 doses of 7.4 GBq per year performed by 4 workers, result in a mean equivalent dose of 23+/-11 mSv and 14+/-6 mSv for finger top and ring dose, respectively. Preparation of 400 doses will result in an effective dose of 0.5-1.5 mSv per year for these 4 workers. The extra radiation dose for workers during the radiolabeling of these doses thus remains below 10% of the legal annual limits, which is in accordance with the ALARA optimization principle. Based on measurements of the maximal radiation level at 1 m distance (7.5+/-3.6 microSv/h), patients treated with 7.4 GBq [177Lu][DOTA0,Tyr3]octreotate can already leave the therapy facility the next day. As radioactive waste streams are based on the half-lives of the used radionuclides, 177Lu-waste (t1/2=6.7 d) was initially collected along with the 131I-waste (t1/2=8 d). According to both manufacturers' specifications, 177Lu contains less than 0.4 kBq 177mLu/MBq 177Lu (at the end of neutron irradiation), when produced by the [176Lu n, gamma 177Lu] reaction via thermal neutron bombardment of enriched lutetium oxide. Unfortunately, because of the huge amounts of 177Lu used, contaminating 177mLu turned out to prevent the quick discharge of this waste, for some containers even after some years of storage. Therefore, a technique for calibrating 177mLu was developed, simultaneously confirming the manufacturer's specifications on the presence of 177mLu in 177Lu. Subsequently a reliable technique was developed to measure 177mLu in waste containers using a beta/gamma-contamination monitor. It is advised to collect 177mLu/177Lu-waste and certainly high-activity lutetium waste separated from 131I according the regulations in the country of use. Apart from the mentioned waste, excreta from patients are collected in decay tanks, where they are stored for 1-2 months before they are discarded into the general sewer within the overall tolerated discharge limit (150 radiotoxicity equivalents/year for our department).

Tissue distribution of octreotide binding receptors in normal mice and strains prone to autoimmunity.

Somatostatin has diverse functions, including immunomodulatory functions. In humans, sites of active inflammation can be visualized by the administration of 111In-DTPA(0)-octreotide, a radiolabelled somatostatin analogue. We wished to establish an animal model for preclinical evaluation of the effects of somatostatin analogues on the immune system. However, most animal models for immunological diseases are murine. This report is a preliminary study of the distribution of somatostatin receptors in mouse tissues, with emphasis on the immune system. Tissue distribution of octreotide binding receptors in normal (BALB/c) mice was determined in vivo by receptor binding of 111In-DTPA(0)-octreotide and in vitro and ex vivo by receptor autoradiography. Additionally, we investigated the tissue distribution of octreotide binding receptors in inflammatory lesions in a murine model of immune mediated disease, i.e. pre-diabetic pancreatic infiltration in the non-obese diabetic mouse strain. High specific uptake of radioactivity was seen in the thymus (range 1-1.7% ID/g) and the pituitary (1-1.6% ID/g) in all mouse strains. Specific uptake was also found in the stomach (0.1-0.7% ID/g), in the adrenal glands (0.1-0.3% ID/g) and in the pancreas (0.1-0.3% ID/g). However, we did not detect increased uptake of radiolabelled octreotide in the pancreas of pre-diabetic NOD mice. Autoradiography on tissue sections confirmed the presence of octreotide binding sites in the tissues that showed specific uptake. Moreover, by using autoradiography we could localize the cortex of the thymus and the anterior part of the pituitary as the localization of specific and high affinity, octreotide binding sites. A high, but not a receptor mediated, uptake of radioactivity was seen in the kidneys and was significantly higher in females than in males (12-19% vs 4% ID/g, respectively). Our results point to profound species differences in the tissue distribution of octreotide binding receptors. Of particular interest is the high uptake of 111In-DTPA(0)-octreotide in the cortex of the mouse thymus. This offers perspectives for the use of this animal in studies concerning the effect of somatostatin analogues on the immune system. To our knowledge, this is the first report on the tissue distribution of octreotide binding receptors in mice.

Tumor response after [(90)Y-DOTA(0),Tyr(3)]octreotide radionuclide therapy in a transplantable rat tumor model is dependent on tumor size.

UNLABELLED: A promising application of radiolabeled somatostatin analogs is peptide receptor-targeted radionuclide therapy of somatostatin receptor-expressing tumors. A suitable radionuclide is (90)Y, which emits high-energy beta-particles with a pathlength of several millimeters in tissue, making it especially promising for treatment of large tumors. METHODS: We investigated the radiotherapeutic effect of different activities (111 and 370 MBq) of [(90)Y-1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid (DOTA)(0),Tyr(3)]octreotide in Lewis rats bearing somatostatin receptor-positive rat pancreatic CA20948 tumors of different size (0.08-15 cm(2)) in their flank. RESULTS: Dose-dependent radiotherapeutic effects of (90)Y-labeled octreotide in this rat tumor model were found. Tumor control (100% complete response) was found in animals bearing tumors of 3-9 cm(2) (mean, 7.8 cm(2)) after intravenous injection of the highest activity (370 MBq [(90)Y-DOTA(0),Tyr(3)]octreotide). In rats bearing tumors of < or =1 cm(2) or > or =14 cm(2), the effects were less pronounced (50% and 0% complete response, respectively). In tumors of < or =1 cm(2) the (90)Y radiation energy will not be absorbed completely in the tumor, whereas in tumors of > or =14 cm(2) the increased number of clonogenic and probably hypoxic tumor cells may explain the failure to reach a cure. CONCLUSION: This study shows the ability of [(90)Y-DOTA(0),Tyr(3)]octreotide to control tumor growth, especially in medium-sized tumors. The effect of radionuclide therapy appeared to be dependent on tumor size at the onset of therapy.

Somatostatin receptor-mediated imaging and therapy: basic science, current knowledge, limitations and future perspectives.

In vivo somatostatin receptor-mediated scintigraphy has proven to be a valuable method for the visualisation of neuroendocrine tumours and their metastases. A new application is the use of radiolabelled analogues for somatostatin receptor-mediated therapy. This paper presents a review on the basic science, historical background and current knowledge of somatostatin receptor subtypes and their expression in neuroendocrine tumours. New somatostatin analogues, new chelators, "new" radionuclides and combinations thereof are also discussed. Due attention is given to limitations and future perspectives of somatostatin receptor-mediated imaging and therapy.

[177Lu-DOTA(0),Tyr3] octreotate for somatostatin receptor-targeted radionuclide therapy.

Receptor-targeted scintigraphy using radiolabeled somatostatin analogs such as octreotate is being used with great success to demonstrate the in vivo presence of somatostatin receptors on various tumors. A new and promising application for these analogs is radionuclide therapy. Radionuclides suitable for this application include the Auger electron-emitter (111)In and the beta-emitters (90)Y (high energy) and (177)Lu (low energy). We investigated [DOTA(0),Tyr(3)]octreotate, labeled with the lanthanide (177)Lu, in biodistribution and radionuclide therapy experiments using male Lewis rats bearing the somatostatin receptor-positive rat CA20948 pancreatic tumor. Biodistribution studies in Lewis rats showed the highest uptake in the rat pancreatic CA20948 tumor and sst(2)-positive organs, which include the adrenals, pituitary and pancreas, of [(177)Lu-DOTA(0),Tyr(3)]octreotate in comparison with (88)Y- and (111)In-labeled analogs. Kidney uptake of [(177)Lu-DOTA(0),Tyr(3)]octreotate could be reduced by approximately 40% by co-injection of 400 mg/kg D-lysine. In radionuclide therapy studies, a 100% cure rate was achieved in the groups of rats bearing small (< or =1 cm(2)) CA20948 tumors after 2 doses of 277.5 MBq or after a single dose of 555 MBq [(177)Lu-DOTA(0),Tyr(3)]octreotate. A cure rate of 75% was achieved after a single administration of 277.5 MBq. In rats bearing larger (> or =1 cm(2)) tumors, 40% and 50% cure rates were achieved in the groups that received 1 or 2 277.5 MBq injections of [(177)Lu-DOTA(0),Tyr(3)]octreotate, respectively. After therapy with [(177)Lu-DOTA(0),Tyr(3)]octreotide in rats bearing small tumors, these data were 40% cure after 1 injection with 277.5 MBq and 60% cure after 2 repeated injections. In conclusion, [(177)Lu-DOTA(0),Tyr(3)]octreotate has demonstrated excellent results in radionuclide therapy studies in rats, especially in animals bearing smaller tumors. This candidate molecule shows great promise for radionuclide therapy in patients with sst(2)-expressing tumors.

Somatostatin receptor imaging, therapy and new strategies in patients with neuroendocrine tumours.

BACKGROUND: Somatostatin receptors have been found on a variety of neuroendocrine tumours, such as carcinoids and paragangliomas, as well as on most pancreatic endocrine and breast tumours. Somatostatin receptor scintigraphy with a radionuclide-labelled somatostatin analogue, [111Indium- diethylenetriaminopenta-acetic acid]octreotide, is a sensitive and specific technique for visualizing in vivo the presence of somatostatin receptors on various tumours. METHODS: Material was identified from previous review articles, references cited in original papers and a Medline search of the literature. Additional material was obtained from recently published abstracts of meetings. RESULTS AND CONCLUSION: Somatostatin receptor imaging of neuroendocrine tumours is essential in the diagnostic evaluation of most of these tumours. The expression of somatostatin receptors in vivo not only predicts the outcome of somatostatin analogue treatment but also opens the possibility of new therapeutic strategies. Because better information about spread of the disease can be obtained, more justifiable options for therapy can be proposed.

Evaluation of a radiolabelled cyclic DTPA-RGD analogue for tumour imaging and radionuclide therapy.

Tumours depend on sufficient blood supply for their growth. They are able to promote new blood vessel formation (neoangiogenesis) via angiogenic factors. Inhibition of this process results in tumour involution or necrosis. RGD (Arg-Gly-Asp) peptides are described to antagonise neoangiogenesis, e.g., by binding to alpha(v)beta(3) receptors on blood vessels. In order to visualise neoangiogenesis in tumours in vitro and in vivo, we introduced and tested an RGD analogue [c(Arg-Gly-Asp-D-Tyr-Lys)], coupled to the chelator diethyleletriamepentaacetic acid (DTPA). This analogue can be radiolabelled with both (111)In and (125)I. In autoradiography and immunohistochemistry studies, the (125)I-labelled analogue appeared to bind specifically and with high affinity to alpha(v)beta(3) receptors on neovascular blood vessel sections of different major human cancers, like prostate and breast cancer, which express these receptors. This radioiodinated radiopharmaceutical also bound to and internalised in human carcinoid Bon cells and rat pancreatic CA20948 tumour cells. Internalisation was receptor-specific and appeared to be time and temperature dependent. In vivo in rats, we investigated administration of different peptide amounts (0.1, 0.5, and 100 microg). The best amount of the radiolabelled analogue to be administered to rats appeared to be 0.1 microg/rat, as uptake decreased with increasing peptide amount. We also found receptor-specific accumulation of the (111)In-labelled analogue in the transplantable pancreatic tumour CA20948. The introduction of the DTPA group in this peptide resulted in renal clearance of the radiopharmaceutical, in contrast to the non-DTPA-conjugated compound that is cleared predominantly via the liver. (111)In emits Auger and conversion electrons besides gamma radiation, therefore, this radiopharmaceutical is suitable not only for tumour scintigraphy but also has potential for radionuclide therapy of major human cancers as well. Moreover, after coupling to the chelator DOTA, the analogue could be radiolabelled in a stable way with beta-emitters, e.g., (90)Y and (177)Lu, enlarging its potential. Int. J. Cancer (Radiat. Oncol. Invest.) 90, 186-198 (2000).

The role of radioactive somatostatin and its analogues in the control of tumor growth.

Peptide receptor scintigraphy with the radioactive somatostatin analogue [111In-DTPA-D-Phe1]octreotide is a sensitive and specific technique to show in vivo the presence and abundance of somatostatin receptors on various tumors. With this technique primary tumors and metastases of neuroendocrine cancers as well as of many other cancer types can be localized. This technique is currently used to assess the possibility of peptide receptor radionuclide therapy with repeated administration of high doses of [111In-DTPA-D-Phe1]octreotide. 111In emits Auger and conversion electrons, having a tissue penetration of 0.02-10 microns and 200-500 microns, respectively. Thirty end-stage patients with mostly neuroendocrine progressing tumors were treated with [111In-DTPA-D-Phe1]octreotide, up to a maximal cumulative patient dose of about 74 GBq, in a phase-I trial. There were no major clinical side effects after up to 2 years of treatment, except that in a few patients a transient decline in platelet counts and lymphocyte subsets occurred. Promising beneficial effects on clinical symptoms, hormone production, and tumor proliferation were found. Of the 21 patients who received a cumulative dose of more than 20 GBq, eight showed stabilization of disease and six others a reduction in tumor size. There is a tendency towards better results in patients whose tumors have a higher accumulation of the radioligand. Peptide receptor radionuclide therapy is also feasible with 111In as the radionuclide. Theoretically, depending on the homogeneity of distribution of tumor cells expressing peptide receptors and the size of the tumor, beta-emitting radionuclides, e.g., 90Y, labeled to DOTA-chelated peptides may be more effective than 111In for peptide receptor radionuclide therapy. The first peptide receptor radionuclide therapy trials with [90Y-DOTA-Tyr3]octreotide started recently.

Use of the rat pancreatic CA20948 cell line for the comparison of radiolabelled peptides for receptor-targeted scintigraphy and radionuclide therapy.

We have evaluated the usefulness of the rat pancreatic CA20948 tumour as an in vitro cell culture model and as an in vivo model in Lewis rats comparing different radiolabelled peptides for receptor-targeted scintigraphy. In vitro the receptor-specific uptake and internalization of different radiolabelled analogues of somatostatin, bombesin, substance P and cholecystokinin were demonstrated. Analogues were selected based on high-affinity binding to their respective receptors. Their uptake and internalization in CA20948 cells were compared to these processes in AR42J cells, a well-known rat pancreatic tumour cell line used for peptide-receptor studies. Receptor-specific internalization, which was blocked by excess unlabelled peptide analogue, was found in both the CA20948 and AR42J cells for all the peptide analogues tested. This indicates specific receptor expression for all the different peptides, making these cells highly suitable for peptide studies. Internalization of the different peptides was as follows, in increasing order: [111In-DOTA0]CCK < [111In-DTPA0,Arg1]substance P < [111In-DTPA0]octreotide < [111In-DTPA0,Pro1,Tyr4]bombesin. Internalization appeared to be time and temperature dependent. In accordance with the in vitro experiments, receptor-specific uptake of all the peptide analogues was also found in vivo in the solid CA20948 tumour. The in vivo tumour uptake of [111n-DTPA0]octreotide was the highest amongst the peptides tested, the order of tumour uptake being [111In-DTPA0]octreotide >[111In-DTPA0,Pro1,Tyr4]bombesin >[111In-DTPA0,Arg1]substance P > [111In-DOTA0]CCK, which is different from the in vitro findings and points to either different receptor numbers on the tumour cells for the different peptide receptors in vitro and in vivo or to differences between the peptides with regard to metabolic stability. It can be concluded that the CA20948 tumour, both in cell culture and as a solid tumour in rats, is a very useful model for peptide receptor scintigraphy and radionuclide therapy studies.

Scintigraphy and radionuclide therapy with [indium-111-labelled-diethyl triamine penta-acetic acid-D-Phe1]-octreotide.

Peptide receptor scintigraphy with [111In-DTPA-D-Phe1]-octreotide is a sensitive and specific technique to show in vivo the presence and abundance of somatostatin receptors on various tumours. With this technique primary tumours and metastases of neuroendocrine cancers as well as of many other cancer types can be localised. This technique is currently used to assess the possibility of peptide receptor radionuclide therapy with repeated administrations of high doses of [111In-DTPA-D-Phe1]-octreotide. 111In emits Auger and conversion electrons having a tissue penetration of 0.02 to 10 microns and 200 to 500 microns, respectively. Twenty end-stage patients, mostly with neuroendocrine progressing tumours, were treated with [111In-DTPA-D-Phe1]-octreotide, up to a maximal cumulative patient dose of about 74 GBq, in a phase I trial. Results showed there were no major clinical side-effects after up to 2 years treatment, except that in a few patients a transient decline in platelet counts and lymphocyte subsets occurred. Promising beneficial effects on clinical symptoms, hormone production and tumour proliferation were found. Of the 16 patients who received a cumulative dose of more than 20 GBq, 5 patients showed stabilisation of disease and 5 other patients a reduction in size of tumours. There is a tendency towards better results in patients whose tumours have a higher accumulation of the radioligand. In conclusion, peptide receptor radionuclide therapy is feasible, also with 111In as radionuclide. Theoretically, depending on the homogeneity of distribution of tumour cells expressing peptide receptors, beta-emitting radionuclides, e.g. 90Y, labelled to DOTA-chelated peptides may be more effective than 111In for peptide receptor radionuclide therapy. The first peptide receptor radionuclide therapy trials with [90Y-DOTA-Tyr3]-octreotide started recently.

Pre-clinical evaluation of [(111)In-DTPA-Pro(1), Tyr(4)]bombesin, a new radioligand for bombesin-receptor scintigraphy.

Bombesin (BN) is a 14-amino-acid neuropeptide with a high affinity for the gastrin-releasing peptide receptor. This receptor has been found to be expressed in a variety of tumours, including lung, breast, prostate and pancreas. A newly synthesized BN analogue, [DTPA-Pro(1),Tyr(4)]BN, was shown to be a high-affinity BN-receptor (BNR) agonist, stimulating prolactin secretion from 7315b cells with an IC(50) of 8 nM. The (111)In-labelled analogue was found to bind with high affinity to rat BNR in vitro and in vivo. The radioligand is internalized by BNR-expressing cells, in contrast to DTPA-conjugated BN antagonists. Therefore, we further studied the biodistribution of i.v. injected [(111)In-DTPA-Pro(1),Tyr(4)]BN in rats. High and specific uptake was found in tissues of the gastrointestinal tract, notably pancreas. Uptake of radioactivity was blocked by pre- or co-injection of 100 microgram [Tyr(4)]BN, but not when this was administered 30 min after the radioligand. This suggests BNR-mediated internalization of the radioligand within 30 min. The percentage injected dose (ID) taken up by BNR-positive tissues was a bell-shaped function of the amount (0.01-0.1 microgram) of injected ligand. Next to the pancreas, highest uptake was observed in the kidneys, which was not blocked by excess [Tyr(4)]BN. Dynamic gamma camera studies showed rapid clearance of radioactivity from the blood compartment. Urinary excretion amounted to about 35% ID after 1 hr and to 70% ID after 24 hr, with a total body retention of 10% ID. Specific uptake was found in the BNR-positive CA20948 pancreas tumour and CC531 colon carcinoma in tumour-bearing rats. The CA20948 tumour, inoculated in the hindleg, was also visualized scintigraphically. [(111)In-DTPA-Pro(1), Tyr(4)]BN appears to be a promising radioligand for scintigraphy of BNR-expressing tumours.

Somatostatin receptor imaging and therapy of pancreatic endocrine tumors.

Somatostatin receptors (SS-Rs) have been found on a variety of neuroendocrine tumors like carcinoids, paragangliomas, as well as on brain and breast tumors. SS-Rs are also present on most pancreatic endocrine tumors, while previous in vitro studies indicate the absence of these receptors on pancreatic duct cancers. Somatostatin receptor scintigraphy with a radionuclide labeled somatostatin analogue, [111In-DTPA0]-octreotide, is a sensitive and specific technique to visualize in vivo the presence of SS-Rs on various tumors. The purpose of this article is to review the somatostatin receptor imaging of pancreatic endocrine tumors and to illustrate the impact of SS-R expression for therapeutic strategies.

Tumour uptake of the radiolabelled somatostatin analogue [DOTA0, TYR3]octreotide is dependent on the peptide amount.

Radiolabelled tumour receptor-binding peptides can be used for in vivo scintigraphic imaging. Recently, the somatostatin analogue [Tyr3]octreotide (D-Phe-c(Cys-Tyr-D-Trp-Lys-Thr-Cys)-Thr(ol)) was derivatized with the chelator DOTA (tetra-azacyclododecane-tetra-acetic acid), enabling stable radiolabelling with both the high-energy beta particle-emitter yttrium-90 and the Auger electron-emitter indium-111. The thus produced radiolabelled compounds are promising for peptide receptor radionuclide therapy. Our previous in vitro and in vivo (rat) experiments with these radiolabelled compounds showed favourable binding and biodistribution characteristics with high uptake and retention in the target organs. We also demonstrated receptor-specific, time- and temperature-dependent internalization of radiolabelled [DOTA0,Tyr3]octreotide in somatostatin receptor subtype 2 (sst2)-positive rat pancreatic tumour cell lines. In this study we have investigated the effects of differences in the amount of injected peptide on tissue distribution of 111In-labelled [DOTA0, Tyr3]octreotide in normal, i.e. non-tumour-bearing, and CA20948 tumour-bearing rats. This was done in order to find the amount of peptide at which the highest uptake in target tissues is achieved, and thereby to increase the potential of radionuclide therapy while simultaneously ensuring the lowest possible radiotoxicity in normal organs. Uptake of radiolabelled [DOTA0,Tyr3]octreotide in sst2-positive organs showed different bell-shaped functions of the amount of injected peptide, being highest at 0.05 (adrenals), 0.05-0. 1 (pituitary and stomach) and 0.25 (pancreas) microg. Uptake in the tumour was highest at 0.5 microg injected peptide. The highest uptake was found at peptide amounts that were lower than those reported for [111In-DTPA0]octreotide ((D-Phe-c(Cys-Phe-D-Trp-Lys-Thr-Cys)-Thr(ol), DTPA = diethylene-triamine-penta-acetic acid), consistent with the higher receptor affinity of the first compound. Our observations of mass-dependent differences in uptake of radiolabelled [DOTA0, Tyr3]octreotide, being the resultant of a positive effect of increasing amounts of peptide on, for example, receptor clustering and a negative effect of receptor saturation, are of consequence for rat radionuclide therapy studies with radiolabelled peptides and may also be of consequence for human radionuclide therapy studies with this compound.

Radiolabelled somatostatin analogue(s) for peptide receptor scintigraphy and radionuclide therapy.

BACKGROUND: Peptide receptor scintigraphy with the radioactive somatostatin analogue, [111In-DTPA0]octreotide, is a sensitive and specific technique to show in vivo the presence and abundance of somatostatin receptors on various tumours. AIM: With this technique primary tumours and metastases of neuroendocrine cancers as well as of many other cancer-types can be localised. This technique is currently used to assess the possibility of peptide receptor radionuclide therapy (PRRT) with repeated administrations of high doses of [111In-DTPA0)octreotide. 111In emits Auger and conversion electrons having a tissue penetration of 0.02-10 microns and 200 to 500 microns, respectively. PATIENTS AND METHODS: Thirty end-stage patients with mostly neuroendocrine progressing tumours were treated with [111In-DTPA0]octreotide, up to a maximal cumulative patient dose of about 74 GBq, in a phase I trial. RESULTS: There were no major clinical side effects after up to two years treatment, except that in a few patients a transient decline in platelets counts and lymphocyte subsets occurred. Promising beneficial effects on clinical symptoms, hormone production and tumour proliferation were found. Of the 21 patients who received a cumulative dose of more than 20 GBq, eight patients showed stabilisation of disease and six other patients a reduction in size of tumours. There is a tendency towards better results in patients whose tumours have a higher accumulation of the radioligand. CONCLUSIONS: PRRT is feasible, also with 111In as radionuclide. Depending on the homogeneity of distribution of tumour cells expressing peptide receptors and the size of the tumour, beta-emitting radionuclides, e.g., 90Y, labelled to DOTA-chelated peptides, are also attractive candidates for PRRT. The first PRRT trials with [90Y-DOTA0,Tyr3]octreotide started recently.

Anti-proliferative effect of radiolabelled octreotide in a metastases model in rat liver.

Most neuroendocrine tumours and several other tumours, such as breast carcinoma and malignant lymphoma, express somatostatin receptors (SS-Rs). Lesions expressing these receptors can be visualised by receptor scintigraphy using a low radioactive dose of the radiolabelled SS analogue [111In-DTPA0]octreotide. This radioligand is internalised and transported to the lysosomes with a long residence time of 111In. The aim of this experimental study in rats was to investigate whether the same agent, given in a high radioactive dose, can be used for therapy of hepatic metastases of different tumour cell lines. The development of hepatic metastases was determined 21 days after direct injection of SS-R-positive or -negative tumour cells into the vena porta in rats. On day 1 and/or 8, animals were treated with 370 MBq (0.5 microg) [111In-DTPA0]octreotide. In one experiment, using SS-R-positive tumour cells, animals were pre-treated with a high dose of cold octreotide to block the SS-R by saturation. The number of SS-R-positive liver metastases was significantly decreased after treatment with [111In-DTPA0]octreotide. Blocking the SS-R by octreotide substantially decreased the efficacy of treatment with [111In-DTPA0]octreotide, suggesting that the presence of SS-R is mandatory. This was confirmed by the finding that the number of SS-R-negative liver metastases was not affected by treatment with [111In-DTPA0]octreotide. Therefore, we conclude that (i) high radioactive doses of [111In-DTPA0]octreotide for PRRT (peptide receptor radionuclide therapy) can inhibit the growth of SS-R-positive liver metastases in an animal model, (ii) PRRT is effective only if SS-Rs are present on the tumours, (iii) the effect of PRRT with [111In-DTPA0]octreotide can be reduced by pre-treatment with cold octreotide, which indicates that receptor binding is essential for PRRT. Our data suggest that PRRT with radiolabelled octreotide might be a new promising treatment modality for SS-R-positive tumours.

Evaluation of radiolabelled bombesin analogues for receptor-targeted scintigraphy and radiotherapy.

The 14-aminoacid peptide bombesin (BN) has a high affinity for the gastrin-releasing peptide receptor which is expressed by a variety of tumours. Thus, radiometal-labelled DTPA-BN derivatives are potentially useful radioligands for receptor-targeted scintigraphy and radiotherapy of BN receptor-expressing tumours. A number of such DTPA-BN analogues, [DTPA-D-Tyr6]BN(6-13)NHEt (Et=ethyl), [DTPA-Tyr5,D-Phe6]BN(5-13)NHEt, [DTPA-D-Phe6,Leu13psiPhe14]BN(6-14), [DTPA-Tyr5,D-Phe6,Leu13psiPhe14]BN(5-14), [DTPA-Pro1,Tyr4]BN and [DTPA-Pro1,Tyr4,Nle14]BN, were synthesized and studied for their binding characteristics to the BN receptor on 7315b rat pituitary tumour cell membranes in competition with [125I-Tyr4]BN. The effects of the BN analogues were determined on basal and BN-stimulated prolactin secretion by 7315b cells to distinguish between their agonistic and antagonistic characteristics. Internalization of selected (111)In-labelled BN analogues was studied using the BN receptor-positive 7315b pituitary tumour and the CA20948 and AR42J exocrine pancreas tumour cell lines. The tissue distribution of these (111)In-labelled BN analogues was investigated in 7315b tumour-bearing rats. Two DTPA-conjugated analogues, the antagonist [DTPA-Tyr5,D-Phe6]BN(5-13)NHEt and the agonist [DTPA-Pro1,Tyr4]BN showed the highest affinity for the BN receptor on 7315b cell membranes. Despite similar affinity for the BN receptor, the (111)In-labelled agonist, but not the antagonist, was internalized by the BN receptor-positive tumour cells. Consonant with this observation, the agonist [(111)In-DTPA-Pro1,Tyr4]BN showed much higher specific uptake in BN receptor-positive tissues and tumour than the antagonist [(111)In-DTPA-Tyr5,D-Phe6]BN(5-13)NHEt, with concordant target to background ratios. We conclude that [(111)In-DTPA-Pro1,Tyr4]BN has promising characteristics for applications in nuclear medicine.