Radioimmunotherapy of prostate cancer.

In recent years, advances in the rational design of radiopharmaceuticals have helped in the introduction of clinically useful therapeutic agents into the clinic. In particular radiolabeled monoclonal antibodies such as (90)Y-ibritumomab and (131)I-tositumomab have shown to be clinically successful. More recently, (177)Lu has emerged as an attractive radionuclide for use in systemic radiotherapy. Like 131I, it has a longer half-live than (90)Y which is more suitable to the pharmacokinetics of monoclonal antibodies, but its chemistry is similar to (90)Y and, when internalized, it is retained by the tumor whereas 131I can be quickly released. Metastatic prostate cancer is an attractive target for radioimmunotherapy since the cornerstone of current therapy is hormonal therapy, which is only palliative. Prostate cancer is also known to metastasize to areas such as the lymph nodes and bone marrow, sites that are readily accessible to circulating monoclonal antibodies. This review will look at recent advances to the treatment of metastatic prostate cancer with radiolabeled antibodies with a specific emphasis on (177)Lu-huJ591, a labeled monoclonal antibody currently under clinical evaluation.

In vitro characterization of radiolabeled monoclonal antibodies specific for the extracellular domain of prostate-specific membrane antigen.

Prostate-specific membrane antigen (PSMA) is a well-characterized cell surface antigen expressed by virtually all prostate cancers (PCas). PSMA has been successfully targeted in vivo with (111)In-labeled 7E11 monoclonal antibody (mAb; ProstaScint; Cytogen, Princeton, NJ), which binds to an intracellular epitope of PSMA. This work reports the in vitro characterization of three recently developed mAbs that bind the extracellular domain of PSMA (PSMAext). Murine mAbs J415, J533, J591, and 7E11 were radiolabeled with 131I and evaluated in competitive and saturation binding studies with substrates derived from LNCaP cells. J415 and J591 were conjugated to 1,4,7,10-tetraazacyclododecane-N,N',N'',N'''-tetraacetic acid labeled with (111)In. The uptake and cellular processing of these antibodies were evaluated in viable LNCaP cells. All four mAbs could be labeled with 131I up to a specific activity of 350 MBq/mg with no or little apparent loss of immunoreactivity. Competition assays revealed that J415 and J591 compete for binding to PSMAext antigen. J533 bound to a region close to the J591 binding epitope, but J533 did not interfere with J415 binding to PSMA. mAb 7E11 did not inhibit the binding of J415, J533, or J591 (or vice versa), consistent with earlier work that these latter mAbs bind PSMAext whereas 7E11 binds the intracellular domain of PSMA. Saturation binding studies demonstrated that J415 and J591 bound with a similar affinity (Kds 1.76 and 1.83 nM), whereas J533 had a lower affinity (Kd, 18 nM). In parallel studies, all four mAbs bound to a similar number of PSMA sites expressed by permeabilized cells (1,000,000-1,300,000 sites/cell). In parallel studies performed with viable LNCaP cells, J415, J533, and J591 bound to a similar number of PSMA sites (i.e., 600,000-800,000 sites/cell), whereas 7E11 bound only to a subpopulation of the available PSMA sites (95,000 sites/cell). This apparent binding of 7E11 to viable cells can be accounted for by a 5-7% subpopulation of permeabilized cells produced when the cells were trypsinized and suspended. Up to five DOTA chelates could be bound to either J415 or J591 without compromising immunoreactivity. A comparison of the cellular uptake and metabolic processing of the 131I- and (111)In-labeled antibodies showed a rapid elimination of 131I from the cell and a high retention of (111)In. All four mAbs recognized and bound to similar numbers of PSMAs expressed by ruptured LNCaP cells (i.e., the exposed intracellular and extracellular domains of PSMA). By comparison to J415 and J591, J533 had a lower binding affinity. Both J415 and J591 recognized and bound to the same high number of PSMAs expressed by intact LNCaP. By contrast, 7E11 bound to fewer sites expressed by intact LNCaP cells (i.e., the exposed extracellular domain of PSMA). Both J415 and J591 are promising mAbs for the targeting of viable PSMA-expressing tissue with diagnostic and therapeutic metallic radionuclides.

New radiopharmaceuticals for receptor scintigraphy and radionuclide therapy.

In vitro data have demonstrated a high amount of receptors for various hormones and peptides on malignant cells of neuroendocrine origin. Among these, binding sites for members of the SST-family (hSSTR1-5) are frequently found, and their expression has led to therapeutic and diagnostic attempts to specifically target these receptors. Receptor scintigraphy using radiolabeled peptide ligands has proven its effectiveness in clinical practice. In addition, initial results have indicated a clinical potential for receptor-targeted radiotherapy. Based on somatostatin (SST) receptor (R) recognition, the novel radiopharmaceuticals 111In/90Y-DOTA-lanreotide developed at the University of Vienna as well as 111In/90Y-DOTA-DPhe1-Tyr3-octreotide (NOVARTIS) both have provided promising data for diagnosis and treatment of hSSTR-positive tumors. SSTR scintigraphy using 111In-DTPA-DPhe1-octreotide has a high positive predictive value for the vast majority of neuroendocrine tumors and has gained its place in the diagnostic work-up as well as follow-up of patients. We have used 111In-DOTA-lanreotide scintigraphy in 166 patients since 1997 and have seen positive results in 93% of patients. In 42 patients with neuroendocrine tumors comparative data were obtained. As opposed to 111In-DTPA-DPhe1-octreotide and 111In-DOTA-DPhe1-Tyr3-octreotide, discrepancies in the scintigraphic results were seen in about one third of patients concerning both the tumor uptake as well as tumor lesion detection. Initial results both with 90Y-DOTA-lanreotide as well as 90Y-DOTA-DPhe1-Tyr3-octreotide has pointed out the clinical potential of radionuclide receptor-targeted radiotherapy. This new therapy could offer palliation and disease control at a reduced cost. The final peptide therapy strategy is most probably cheaper than conventional radiotherapies or prolonged chemotherapies. Overall, receptor-mediated radiotherapy with 90Y-DOTA-lanreotide/90Y-DOTA-DPhe1-Tyr3-octre otide might also be effective in patients refractory to conventional strategies.

New somatostatin analogues for radiotherapy of somatostatin receptor expressing tumours.

Among various newly synthesized chelator-linked octreotide analogues 90Y-[DOTA-DPhe1, Thyr3]-octreotide (90Y-SMT 487) was finally selected for clinical development. In vitro, SMT 487 binds selectively with nanomolar affinity to the somatostatin receptor subtype 2 (IC30 = 0.39 nM +/- 0.02). In vivo, 90Y-[DOTA-DPhe1, Thyr3]-octreotide shows a rapid blood clearance (T1/2 alpha < 5 min) and high accumulation in somatostatin subtype 2 receptor expressing tumours. The in vivo administration of 90Y-[DOTA-DPhe1, Thyr3]-octreotide induces a rapid tumour shrinkage in three different somatostatin receptor positive tumour models: CA20948 rat pancreatic tumours grown in normal rats, AR42J rat pancreatic tumours and NCI-H69 human small cell lung cancer both grown in nude mice. The radiotherapeutic efficacy of 90Y-SMT 487 was enhanced in combination with standard anticancer drugs, such as mitomycin C, which resulted in a tumour decrease of 70% of the initial volume. In the CA 20948 syngeneic rat tumour model, a single treatment with 10 microCi/kg 90Y-SMT 487 resulted in the disappearance of 5 out of 7 tumours. Thus the new radiotherapeutic agent showed its curative potential for the selective treatment of SRIF receptor-expression tumours. Clinical Phase I studies with 90Y-SMT 487 were started in September 1997.

"MAURITIUS": tumour dose in patients with advanced carcinoma.

Radioimaging of various human tumours by means of somatostatin analogues and vasoactive intestinal peptide has been introduced into clinical practice in recent years. The finding that human tumours express various subtypes of somatostatin receptors has led to the development and characterization of a novel peptide tracer, termed MAURITIUS. MAURITIUS identifies a broad range of somatostatin receptors with high binding affinity, and somatostatin receptor 1 with low binding affinity. In order to evaluate patients for tumour radiotherapy with 90Y-MAURITIUS, tumour dose calculation is performed with 111In-MAURITIUS [111In-DOTA-lanreotide]. Treatment is initiated in patients presenting a tumour uptake of > or = 10 Gy/GBq (i.e., standard dose for 1 treatment cycle with 90Y-MAURITIUS). In 25 patients with advanced cancer refractory to conventional antineoplastic treatment 111In-MAURITIUS (approximately 150 MBq; 10 nmol/patient), scintigraphy and dosimetry was performed. Dosimetry data were calculated based on scintigraphic results as well as urine, faeces and blood data. In all patients, at least one tumour site was visualized during the initial few minutes of application. Additional tumour sites not seen on conventional imaging (computerized tomography, magnetic resonance imaging bone scan) could be detected in 6 patients with carcinoids, one patient with prostate cancer and one patient with lymphoma. Liver metastases were visualized in all patients with gastrointestinal cancers, while the primary tumour was not detected in 2 patients with pancreatic, and in 1 patient with rectal, cancer. The calculated radiation dose for tumours and/or metastases ranged between 3-60 Gy/GBq for 90Y-MAURITIUS. MAURITIUS is a universal receptor ligand for a large variety of different human tumours, and is suitable for treatment when labelled with 90Y.

DOTA-lanreotide: a novel somatostatin analog for tumor diagnosis and therapy.

Long acting somatostatin-14 (SST) analogs are used clinically to inhibit tumor growth and proliferation of various tumor types via binding to specific receptors (R). We have developed a 111In-/90Y-labeled SST analog, DOTA-(D)betaNal1-lanreotide (DOTALAN), for tumor diagnosis and therapy. 111In-/90Y-DOTALAN bound with high affinity (dissociation constant, Kd, 1-12 nM) to a number of primary human tumors (n = 31) such as intestinal adenocarcinoma (n = 17; 150-4000 fmol/mg protein) or breast cancer (n = 4; 250-9000 fmol/mg protein). 111In-/90Y-DOTALAN exhibited a similar high binding affinity (Kd, 1-15 nM) for the human breast cancer cell lines T47D and ZR75-1, the prostate cancer cell lines PC3 and DU145, the colonic adenocarcinoma cell line HT29, the pancreatic adenocarcinoma cell line PANC1, and the melanoma cell line 518A2. When expressed in COS7 cells, 111In-DOTALAN bound with high affinity to hsst2 (Kd, 4.3 nM), hsst3 (Kd, 5.1 nM), hsst4 (Kd, 3.8 nM), and hsst5 (Kd, 10 nM) and with lower affinity to hsst1 (Kd, approximately 200 nM). The rank order of displacement of [125I]Tyr11-SST binding to hsst1 was: SST (IC50, 0.5 nM) >> DOTALAN (IC50, 154 nM) > lanreotide (LAN) approximate to Tyr3-octreotide (TOCT) approximate to DOTA-Tyr3-octreotide (DOTATOCT) approximate to DOTA-vapreotide (DOTAVAP; IC50, >1000 nM); that to hsst2 was: DOTATOCT approximate to TOCT approximate to DOTALAN approximate to SST approximately LAN approximate to DOTAVAP (IC50, 1.4 nM); that to hsst3 was: SST (IC50, 1.2 nM) > DOTALAN = LAN (IC50, 15 nM) approximate to TOCT (IC50, 20 nM) approximate to DOTAVAP (IC50, 28 nM) > DOTATOCT (IC50, 73 nM); that to hsst4 was: SST (IC50, 1.8 nM) approximate to DOTALAN (IC50, 2.5 nM) > LAN (IC50, 22 nM) >> DOTATOCT approximate to DOTAVAP approximate to TOCT (IC50, >500 nM); and that to hsst5 was: DOTALAN (IC50, 0.45 nM) > SST (IC50, 0.9 nM) > TOCT (IC50, 1.5 nM) > DOTAVAP (IC50, 5.4 nM) >> LAN (IC50, 21 nM) > DOTATOCT (IC50 260 nM). In Sprague Dawley rats (n = 10), 90Y-DOTALAN was rapidly cleared from the circulation and concentrated in hsst-positive tissues such as pancreas or pituitary. Taken together, our results indicate that 111In-/90Y-DOTALAN binds to a broad range of primary human tumors and tumor cell lines, probably via binding to hsst2-5. We conclude that this radiolabeled peptide can be used for hsst-mediated diagnosis (111In-DOTALAN) as well as systemic radiotherapy (90Y-DOTALAN) of human tumors.

Response to treatment with yttrium 90-DOTA-lanreotide of a patient with metastatic gastrinoma.

1,4,7,10-tetraazacyclododecane-N,N',N",N'''-tetraacetic acid (DOTA)-lanreotide is a universal somatostatin (SST) receptor subtype ligand that binds to a large variety of human tumors. We report the case of a patient with metastatic gastrinoma who was treated with 90Y-DOTA-lanreotide. Before treatment, dosimetry with 111In-DOTA-lanreotide (150 MBq, 10 nmol) indicated a dose of 5.8 mGy/MBq for the recurrent abdominal gastrinoma, and a mean dose of approximately 1.0 mGy/MBq for liver metastases (i.e., 56 and approximately 10 mGy/MBq for 90Y-DOTA-lanreotide, respectively). After four infusions of 90Y-DOTA-lanreotide (each 1 GBq, approximately 30 nmol) over a 6-mo period, the 111In-DOTA-lanreotide scintigraphy of the liver had returned to a nearly normal condition and a remarkably decreased uptake by the recurrent gastrinoma was calculated (approximately 5 mGy/MBq for 90Y-DOTA-lanreotide). The imaging results were well-correlated with a 25% regression of the liver metastases as indicated by CT. Blood, urine and whole-body clearances of 111In-DOTA-lanreotide and 90Y-DOTA-lanreotide were very similar. The DOTA-lanreotide promises to be useful for functional tumor diagnosis (111In-DOTA-lanreotide) and receptor-mediated tumor radiotherapy (90Y-DOTA-lanreotide).

Indium-111-DOTA-lanreotide: biodistribution, safety and radiation absorbed dose in tumor patients.

UNLABELLED: Imaging with radiolabeled somatostatin/vasoactive intestinal peptide analogs has recently been established for the localization diagnosis of a variety of human tumors including neuroendocrine tumors, intestinal adenocarcinomas and lymphomas. This study reports on the biodistribution, safety and radiation absorbed dose of 111In-1,4,7,10-tetraazacyclododecane-N,N',N",N'''-tetraacetic acid (DOTA)-lanreotide, a novel peptide tracer, which identifies hSST receptor (R) subtypes 2 through 5 with high affinity, and hSSTR1 with low affinity. METHODS: The tumor localizing capacity of 111In-DOTA-lanreotide was initially investigated in 10 patients (3 lymphomas, 5 carcinoids and 2 intestinal adenocarcinomas). Indium-111 -DOTA-lanreotide was then administered to 14 cancer patients evaluated for possible radiotherapy with 90Y-DOTA-lanreotide (8 neuroendocrine tumors, 4 intestinal adenocarcinomas, 1 Hodgkin lymphoma and 1 prostate cancer). After intravenous administration of 111In-DOTA-lanreotide (approximately = 150 MBq; 10 nmol/patient), sequential images over one-known tumor site were recorded during the initial 30 min after peptide application. Thereafter, whole-body images were acquired in anterior and posterior views up to 72 hr postinjection. Dosimetry calculations were performed on the basis of scintigraphic data, urine, feces and blood activities. A comparison with 111In-DTPA-D-Phe1-octreotide (111In-OCT) scintigraphy was performed in 8 of the patients. RESULTS: After an initial rapid blood clearance [results of biexponential fits: T(eff1) 0.4 min (fraction a1 80%) and T(eff2) 13 min (fraction a2 14%)], the radioactivity was excreted into the urine and amounted to 42% +/- 3% of the injected dose (%ID) within 24 hr and 62% +/- 6%ID within 72 hr after injection of 111In-DOTA-lanreotide. In all patients, tumor sites were visualized during the initial minutes after injection of 111In-DOTA-lanreotide. The mean radiation absorbed dose amounted to 1.2 (range 0.21-5.8) mGy/MBq for primary tumors and/or metastases. The effective half-lives of 111In-DOTA-lanreotide in the tumors were T(eff1) 4.9 +/- 2.2 and T(eff2) 37.6 +/- 6.6 hr, and the mean residence time tau was 1.8 hr. The highest radiation absorbed doses were calculated for the spleen (0.39 +/- 0.13 mGy/MBq), kidneys (0.34 +/- 0.08 mGy/MBq), urinary bladder (0.21 +/- 0.03 mGy/MBq) and liver (0.16 +/- 0.04 mGy/MBq). The effective dose was 0.11 +/- 0.01 (range 0.09-0.12) mSv/MBq. During the observation period of 72 hr, no side effects were noted after 111In-DOTA-lanreotide application. The 111In-DOTA-lanreotide radiation absorbed tumor dose was significantly higher (ratio 2.25 +/- 0.60, p < 0.01) when directly compared with 111In-OCT. CONCLUSION: Indium-111 -DOTA-lanreotide shows a high tumor uptake for a variety of different human tumor types, has a favorable dosimetry over 111In-OCT and is clinically safe.

The somatostatin receptor-targeted radiotherapeutic [90Y-DOTA-DPhe1, Tyr3]octreotide (90Y-SMT 487) eradicates experimental rat pancreatic CA 20948 tumours.

Somatostatin receptor-expressing tumours are potential targets for therapy with radiolabelled somatostatin analogues. We have synthesized a number of such analogues in the past and identified [DOTA-dPhe1, Tyr3]octreotide (SMT 487) as the most promising candidate molecule because of its advantageous properties in cellular and in vivo tumour models. In the current paper we describe the radiotherapeutic effect of yttrium-90 labelled SMT 487 in Lewis rats bearing the somatostatin receptor-positive rat pancreatic tumour CA 20948. SMT 487 binds with nanomolar affinity to both the human and the rat somatostatin receptor subtype 2 (sst2) (human sst2 IC50=0.9 nM, rat sst2 IC50=0.5 nM). In vivo, 90Y-SMT 487 distributed rapidly to the sst2 expressing CA 20948 rat pancreatic tumour, with a tumour-to-blood ratio of 49.15 at 24 h post injection. A single intravenous administration of 10 mCi/kg 90Y-SMT 487 resulted in a complete remission of the tumours in five out of seven CA 20948 tumour-bearing Lewis rats. No regrowth of the tumours occurred 8 months post injection. Control animals that were treated with 30 microg/kg of unlabelled SMT 487 had to be sacrificed 10 days post injection due to excessive growth or necrotic areas on the tumour surface. Upon re-inoculation of tumour cells into those rats that had shown complete remission, the tumours disappeared after 3-4 weeks of moderate growth without any further treatment. The present study shows for the first time the curative potential of 90Y-SMT 487-based radiotherapy for somatostatin receptor-expressing tumours. Clinical phase I studies with yttrium-labelled SMT 487 have started in September 1997.

Synthesis and characterisation of [90Y]-Bz-DTPA-oct: a yttrium-90-labelled octreotide analogue for radiotherapy of somatostatin receptor-positive tumours.

An investigation into the in vitro behaviour of two yttrium-90-labelled somatostatin analogues was performed. Further in vivo characterisation was performed with the most promising agent. A new DTPA-octreotide analogue (Bz-DTPA-oct) was synthesised by coupling a bifunctional DTPA chelator to the N-terminal amine of the D-Phe1 of Tyr3-octreotide. This new SRIF analogue and DTPA-octreotide (OctreoScan) were radiolabelled with 90Y prior to serum stability being evaluated. Receptor binding assays were also performed on the two radioligands using rat cortex membranes. The [90Y]-Bz-DTPA-oct was further evaluated in vivo using tumour-bearing rats. The first conjugate (DTPA-octreotide) bound with a high affinity to SRIF receptors and the 90Y complex was relatively stable in human serum (t1/2 3.8 d for 90Y lost to serum proteins). The second conjugate (Bz-DTPA-oct) also exhibited a high binding affinity to SRIF receptors, but it demonstrated an even slower loss of 90Y to serum proteins (t1/2 12.1 d). The in vivo evaluation of the more stable [90Y]-Bz-DTPA-oct showed a very rapid and high accumulation in somatostatin receptor-positive tumours, which after 1 h resulted in tumour/nontumour ratios of 3.8, 21, and 4.9 (for blood, muscle, and liver, respectively). These tumour/nontumour ratios increased, and were by 24 h postinjection 138, 285, and 6.1 (for blood, muscle, and liver). Yttrium-90-labelled Bz-DTPa-oct is rapidly and selectively accumulated in somatostatin receptor-positive tissue. Octadentate Bz-DTPA-oct could be ligand for 90Y radiotherapy of somatostatin receptor-positive tumours and their metastases.

Direct synthesis of [DOTA-DPhe1]-octreotide and [DOTA-DPhe1,Tyr3]-octreotide (SMT487): two conjugates for systemic delivery of radiotherapeutical nuclides to somatostatin receptor positive tumors in man.

Direct attachment of unprotected DOTA (1,4,7,10-tetraazacyclododecane-N',N",N"',N""-tetraacetic acid) to partially suitably protected octreotide or [Tyr3]-octreotide leads after deprotection to [DOTA-DPhe1]-octreotide (III) and [DOTA-DPhe1,Tyr3]-octreotide (IV). These DOTA-containing somatostatin analogs, when labeled with a radiotherapeutic nuclide, are useful as antitumor agents. The partially protected peptides are accessible via solid phase peptide synthesis (SPPS) followed by selective cleavage under mild acidic conditions from the resin.

Radiation doses deriving from patients undergoing 111In-DTPA-D-phe-1-octreotide scintigraphy.

The purpose of this study was to estimate the radiation doses to nursing staff, other patients, accompanying persons and family members deriving from patients undergoing 111In-DTPA-d-Phe-1-octreotide (111In-OCT) scintigraphy. Dose rates were measured from 16 patients who had received an intravenous injection of 140+/-40 MBq 111In-OCT. The measurements were performed at three different distances (0.5, 1 and 2 m) at 10-20 min, 5-7 h and 24 h (and in some cases, up to 48 h) after administration of 111In-OCT. The effective half-lives of the biexponential decrease of the dose rates were estimated to be 2.94+/-0.27 h (T1) and 65.17+/-0. 58 h (T2). The calculated maximum dose to other persons in the waiting area was 27.2 microSv, to family members 61.5 microSv, to nursing staff in a ward 24.1 microSv and to neighbouring patients in the ward 69.5 microSv. Our results clearly demonstrate that the calculated maximum radiation exposure to accompanying persons, personnel, family members and other patients is well below the maximum annual dose limit for non-professionally exposed persons.

Inhalation scintigraphy with iodine-123-labeled interferon gamma-1b: pulmonary deposition and dose escalation study in healthy volunteers.

UNLABELLED: Recent studies have suggested that recombinant interferon gamma (IFNg) may be useful in the treatment of various respiratory diseases, such as chronic inflammatory disease. This study was undertaken to investigate the dose response of escalating doses of inhaled 123I-labeled IFNg (123I-IFNg) and its safety, biodistribution and radiation absorbed doses in healthy volunteers. METHODS: IFNg was labeled with 123I to produce a specific activity of 1800 MBq/mg of IFNg. The biological activities of 123I-IFNg, nebulized 123I-IFNg and unlabeled IFNg were evaluated in various functional in vitro tests. Ten healthy volunteers were enrolled in the in vivo dose escalation study (180 MBq of 123I-IFNg diluted with 0.1-2 mg of INFg). Inhalation scintigraphy, using a Pari-Master nebulizer, was performed for up to 37 min, during which dynamic posterior images of the lungs were obtained. Whole-body scanning was performed at various time points up to 24 hr postinjection, for biodistribution and dosimetry purposes. Blood, urine and feces were also collected over this 24-hr period. Lung perfusion scintigraphy with 99mTc-microspheres was performed at the end of the study for attenuation correction. RESULTS: Inhaled nebulized IFNg showed a uniform deposition pattern in the lungs with deposition ratios of 0.74 (central-to-peripheral) and 0.78 (upper-to-lower). The lung deposition of IFNg was time-dependent, with a deposition half-time between 1 and 5 min. Despite a large interindividual variation, the total lung deposition was proportional to the nebulizer charge and was 53 +/- 12% of the inhaled dose and 19 +/- 7% of the initial nebulizer charge (between 0.1 and 2 mg of IFNg). The biological half-life in the lung could be fitted to a biexponential function, with resultant half-lives of 1 and 11 hr. Blood activity was maximal at 3.5 hr after inhalation and was due to free iodine. The radioactivity was excreted through both the urinary and intestinal tracts. Plasma IFNg levels did not significantly increase over time, and no significant HLA-DR induction on peripheral blood cells was detected. The highest radiation absorbed doses of 0.14 and 0.19 mGy/MBq were determined for the trachea and the lower intestines, respectively. The effective dose equivalent was 0.05 mSv/MBq. CONCLUSION: After inhalation with the Pari-Master nebulizer, IFNg deposits normally in the lungs and shows no systemic effects in healthy volunteers.

PET-pharmacokinetics of 18F-octreotide: a comparison with 67Ga-DFO- and 86Y-DTPA-octreotide.

The quantitative uptake kinetics of (2-[18F]fluoropropionyl-(D)phe1)-octreotide (I), a somatostatin (SRIF) receptor-specific tracer, was measured by PET. Conventional organ biodistribution and in vivo stabilities of the tracer as well as in vivo displacement and SRIF receptor blocking were determined. The 18F-fluorinated octreotide was compared with ([67Ga]-DFO-B-succinyl-(D)phe1)-octreotide (II) and ([86Y]-DTPA-(D)phe1)-octreotide (III). Initially, 2-10 MBq of the labeled tracers were injected into male Lewis rats bearing an exocrine pancreatic islet cell tumor. PET measurements were performed dynamically between 0 and 120 min postinjection. Organ distributions were determined 5, 15, 30, 60, and 120 min postinjection. The extent of metabolic degradation was analyzed in serial blood and urine samples as well as in homogenized samples of tumor, liver, and kidney. The uptake of (I) by the tumor was rapid (maximum accumulation at 1-2 min postinjection) and high (about 0.5 +/- 0.2% ID/g), followed by a fast and continuous release with koff = 10 +/- 2. 10(-5) s-1. The tracer was found to remain intact in vivo up to 120 min postinjection. Specific binding of (I) to SRIF receptors in the adrenals, the pancreas, and the pituitary gland was demonstrated in vivo by pretreatment and displacement experiments. Compound (II) also showed a fast uptake by the tumor. Its tumor residence half-life was longer (koff = 3.0 +/- 0.5 . 10(-5) s-1). Compound (II) was also predominantly excreted intact. One hour postinjection, the remaining activity in the blood pool was found to be bound to serum proteins. Early uptake kinetics for compound (III) were also rapid but reached only half the tumor uptake of (II). Compared to (I), the release of 86Y-activity from the tumor was slower (koff = 3.1 +/- 1.3 . 10(-5) s-1). Compared to (II), compound (III) was considerably less stable in vivo. The main critical organs for (II) and (III) are kidneys and bones, whereas (I) is predominantly accumulated in the liver. The in vivo behavior of (I) closely resembles 14C-labeled octreotide. Thus, 18F-labeled octreotide may be of interest in the quantitation and investigation of in vivo properties of somatostatin receptors by PET. However, the short residence of (2-[18F]fluoropropionyl-(D)phe1)-octreotide in tumors and its hepatobiliary excretion may complicate the interpretation of abdominal tumors.

Synthesis, biodistribution and renal handling of various chelate-somatostatin conjugates with metabolizable linking groups.

A series of DTPA-octreotide conjugates, with various linking groups, were synthesised to investigate the effect of different metabolizable linkers on the renal retention of radioactivity. All these newly synthesised octreotide conjugates retained the high binding affinity of octreotide for the somatostatin (SRIF) receptors either when unlabeled or radiolabeled with 111In. Some of the metabolizable linkers were rapidly degraded in vitro when incubated with a kidney homogenate. However, in vivo, all these conjugates displayed a significantly lower uptake in SRIF receptor-positive tissue compared to two conjugates with short, stable linkers. Additionally, the compounds with a potentially metabolizable linker had a higher whole-body retention of activity as opposed to the three metabolically stable compounds. Several of the linkers gave evidence of cleavage while in circulation in the blood, and it is probable that the lower tumour accumulation of most of the compounds tested was low due to the high enzymatic nature of the exocrine pancreatic tumour model used. In short, no increase in the tumour-to-kidney ratio was achieved with the analogues containing a metabolizable linker. The highest target-to-nontarget tissue ratios were obtained for the DTPA-octreotide conjugates that had short, metabolically stable linkers.

Somatostatin analogues for somatostatin-receptor-mediated radiotherapy of cancer.

The aim of the present study was to selectively target a beta-emitter-labelled octreotide analogue to somatostatin (SRIF)-receptor-expressing tumours and to evaluate the feasibility of SRIF-receptor-mediated radiotherapy by delivering a lethal dose of radiation to the tumour. The most promising compound in a series of DTPA-coupled octreotide analogues was DTPA-benzyl-acetamido-D-Phe1, Tyr3-octreotide (SDZ413). In vitro, SDZ413 binds with nanomolar affinity to SRIF-receptors (IC50 = 4.0 nM) and inhibits growth hormone release from primary cultures of rat pituitary cells with an IC50 of 7.2 nM. Biodistribution studies with [90Y]SDZ413 demonstrated a fast and significant SRIF-receptor-specific accumulation of the labelled conjugate (tumour/muscle ratio after 24 h: 52/1). [90Y]SDZ413 was effective in the radiotherapy of SRIF-receptor-positive tumours in a nude mouse model. A single treatment with [90Y]SDZ413 led to a significant decrease (25%) of tumour mass. This effect was mediated by the intact radioligand, since treatment with [90Y]SDZ978, a derivative of SDZ413 which does not bind with high affinity to SRIF-receptors or with the unlabelled SDZ413 alone, failed to affect tumour growth. These results suggest that receptor-targeted radiotherapy with a 90Y-labelled octreotide analogue represents a new strategy for the treatment of SRIF-receptor-positive tumours that have been previously diagnosed with OctreoScan111 (pentetreotide).

Biological characterisation of [67Ga] or [68Ga] labelled DFO-octreotide (SDZ 216-927) for PET studies of somatostatin receptor positive tumors.

Radiolabelled analogues of Somatostatin (SRIF) were demonstrated to be useful for conventional gamma-camera imaging of SRIF receptor-positive tumors and their metastases. To evaluate the feasibility of positron emission tomography (PET) or SRIF receptor-positive tumors deferoxamine (DFO) was conjugated to octreotide via a succinyl linker to form a stable conjugate with the gallium isotopes 67Ga and 68Ga. This new octreotide analog, SDZ 216-927, binds specifically and with high affinity to SRIF receptors in vitro (pKi = 8.94 +/- 0.06) and exhibits SRIF like biological properties as demonstrated by the inhibition of growth hormone (GH) release from cultured pituitary cells. SDZ 216-927 was efficiently labelled with 67Ga without affecting high affinity binding to SRIF receptors. Biodistribution studies revealed that [67Ga]SDZ 216-927 was stable in vivo and rapidly cleared from the circulation, as indicated by the low amount of 67Ga detected in the blood four hours post injection (p.i.). SRIF receptor-positive tumors were clearly visualized 10 minutes p.i. in tumor bearing rats. The specificity of ligand binding in vivo was demonstrated i) by the high tumor/non-tumor ratio 4 hours p.i. (tumor/blood 22.3:1, tumor/muscle 64.5:1, tumor/liver 4.0:1, tumor/spleen 16.8:1) and ii) by a significantly lower uptake of radioactivity in the tumor after pretreatment of tumor bearing animals with an excess of unlabelled SDZ 216-927. SDZ 216-927, when labelled with the positron emitting isotope 68Ga, clearly imaged SRIF receptor-positive tumors using positron emission tomography (PET). Therefore quantitative SRIF receptor imaging with PET seems to be possible using this new radiopharmaceutical.

Gallium-67/gallium-68-[DFO]-octreotide--a potential radiopharmaceutical for PET imaging of somatostatin receptor-positive tumors: synthesis and radiolabeling in vitro and preliminary in vivo studies.

UNLABELLED: When labeled with gamma-emitting radionuclides, somatostatin analogs have the potential to localize somatostatin receptor-positive tumors using gamma camera scintigraphy. We present a somatostatin analog, [DFO]-octreotide (SDZ 216-927), that comprises desferrioxamine B coupled to octreotide via a succinyl linker. This conjugate can be labeled with either 67Ga for gamma scintigraphy or 68Ga for PET imaging. The 67Ga-labeled conjugate is stable in vitro to autoradiolysis over a 24-hr period. METHODS: Rats bearing a somatostatin receptor-positive pancreatic islet cell tumor were injected with 20 MBq of 67Ga[DFO]-octreotide (33 GBq 67Ga/mumole). RESULTS: After 1 hr, the accumulation of 67Ga[DFO]-octreotide was 0.38 +/- 0.08 %ID/g and the tumor-to-nontumor ratios for blood, muscle, liver and intestine were 2.5, 7.4, 1.9 and 1.6, respectively. PET studies with 68Ga[DFO]-octreotide recorded a very rapid accumulation at the tumor and a subsequent residence half-life of about 6 hr. CONCLUSION: Gallium-68-[DFO]-octreotide can be used in PET studies to diagnose receptor-positive tumors such as gastroenteropancreatic, small-cell lung and breast tumors.