In situ Generated ²¹²Pb-PSMA Ligand in a ²²⁴Ra-Solution for Dual Targeting of Prostate Cancer Sclerotic Stroma and PSMA-positive Cells

Background: New treatments combating bone and extraskeletal metastases are needed for patients with metastatic castration-resistant prostate cancer. The majority of metastases overexpress prostate-specific membrane antigen (PSMA), making it an ideal candidate for targeted radionuclide therapy.

Objective: The aim of this study was to test a novel liquid 224Ra/212Pb-generator for the rapid preparation of a dual-alpha targeting solution. Here, PSMA-targeting ligands are labelled with 212Pb in the 224Ra-solution in transient equilibrium with daughter nuclides. Thus, natural bone-seeking 224Ra targeting sclerotic bone metastases and 212Pb-chelated PSMA ligands targeting PSMA-expressing tumour cells are obtained.

Methods: Two PSMA-targeting ligands, the p-SCN-Bn-TCMC-PSMA ligand (NG001), specifically developed for chelating 212Pb, and the most clinically used DOTA-based PSMA-617 were labelled with 212Pb. Radiolabelling and targeting potential were investigated in situ, in vitro (PSMA-positive C4-2 human prostate cancer cells) and in vivo (athymic mice bearing C4-2 xenografts).

Results: NG001 was rapidly labelled with 212Pb (radiochemical purity >94% at concentrations of ≥15 µg/ml) using the liquid 224Ra/212Pb-generator. The high radiochemical purity and stability of [212Pb]Pb-NG001 were demonstrated over 48 hours in the presence of ascorbic acid and albumin. Similar binding abilities of the 212Pb-labelled ligands were observed in C4-2 cells. The PSMA ligands displayed comparable tumour uptake after 2 hours, but NG001 showed a 3.5-fold lower kidney uptake than PSMA-617. Radium-224 was not chelated and, hence, showed high uptake in bones.

Conclusion: A fast method for the labelling of PSMA ligands with 212Pb in the 224Ra/212Pb-solution was developed. Thus, further in vivo studies with dual tumour targeting by alpha-particles are warranted.

Radon-220 diffusion from 224Ra-labeled calcium carbonate microparticles: Some implications for radiotherapeutic use

Alpha-particle emitting radionuclides continue to be the subject of medical research because of their high energy and short range of action that facilitate effective cancer therapies. Radium-224 (²²⁴Ra) is one such candidate that has been considered for use in combating micrometastatic disease. In our prior studies, a suspension of ²²⁴Ra-labeled calcium carbonate (CaCO₃) microparticles was designed as a local therapy for disseminated cancers in the peritoneal cavity. The progenies of ²²⁴Ra, of which radon-220 (²²⁰Rn) is the first, together contribute three of the four alpha particles in the decay chain. The proximity of the progenies to the delivery site at the time of decay of the ²²⁴Ra-CaCO₃ microparticles can impact its therapeutic efficacy. In this study, we show that the diffusion of ²²⁰Rn was reduced in labeled CaCO₃ suspensions as compared with cationic ²²⁴Ra solutions, both in air and liquid volumes. Furthermore, free-floating lead-212 (²¹²Pb), which is generated from released ²²⁰Rn, had the potential to be re-adsorbed onto CaCO₃ microparticles. Under conditions mimicking an in vivo environment, more than 70% of the ²¹²Pb was adsorbed onto the CaCO₃ at microparticle concentrations above 1 mg/mL. Further, the diffusion of ²²⁰Rn seemed to occur whether the microparticles were labeled by the surface adsorption of ²²⁴Ra or if the ²²⁴Ra was incorporated into the bulk of the microparticles. The therapeutic benefit of differently labeled ²²⁴Ra-CaCO₃ microparticles after intraperitoneal administration was similar when examined in mice bearing intraperitoneal ovarian cancer xenografts. In conclusion, both the release of ²²⁰Rn and re-adsorption of ²¹²Pb are features that have implications for the radiotherapeutic use of ²²⁴Ra-labeled CaCO₃ microparticles. The release of ²²⁰Rn through diffusion may extend the effective range of alpha-particle dose deposition, and the re-adsorption of the longer lived ²¹²Pb onto the CaCO₃ microparticles may enhance the retention of this nuclide in the peritoneal cavity.

Abstract 3922: Biodistribution of Ra-224 and its daughter Pb-212 after intraperitoneal infusion of Ra-224 labeled microparticles in rats

Introduction: Radium-224 (Ra-224) labeled calcium carbonate (CaCO3) microparticles were developed with the intent to treat micrometastases located in the abdominal cavity. The slowly degradable microparticles act as carriers for the α-emitter Ra-224 and ensure high intraperitoneal (IP) retention of the radioactivity without cellular targeting. This novel α-therapy has a short action range in tissue and is designed to confine the radiation exposure to the IP cavity, treating both linings of the peritoneal surfaces and liquid volumes. The distribution of the Ra-224 labeled microparticles was examined by planar gamma imaging, SPECT and CT. The ex vivo biodistribution of Ra-224 and its progeny Pb-212 was also determined.

Experimental procedures: Fifteen female Wistar rats were infused IP with Ra-224-labeled microparticles (200-400 kBq, 100 mg CaCO3). The injections were performed by use of a perforated catheter (pigtail catheter), followed by a Plasmalyte flush to mimic the planned clinical administration. The Ra-224 labeled microparticles were imaged using both planar gamma imaging, SPECT and CT to evaluate the distribution over time in the abdominal region. Ex vivo biodistribution was performed 2, 24, 96, 168 and 336 hours after particle infusion and organs were harvested for activity measurements. The activity was determined at 2 hours and 48 hours after harvesting for all samples. This allowed differentiation between the biodistribution of Ra-224 and the biodistribution of its progeny Pb-212. Furthermore, 4 rats were injected IP with free Ra-224 and 2 rats were injected intravenously with free Ra-224 to achieve a baseline for the biodistribution. These control animals were euthanized at 24 and 168 hours, and 168 hours, respectively.

Results: Based on both CT and SPECT images, the particles distributed to the entire peritoneum, albeit with local areas of high microparticle concentration. Over the course of the experiment there was, as expected, a modest but evident systemic leakage of Ra-224 from the particles in the peritoneal cavity. The amount was estimated by the bone uptake of radioisotopes Pb-212 and Ra-224, using IP administered free Ra-224 as reference. The retention of Ra-224 in the peritoneal cavity was found to be > 87% at 24 hours and > 77% at 168 hours. Redistribution of the progeny Pb-212 was observed as modest uptake in the kidneys.

Conclusions: High peritoneal retention of both Ra-224 and its progeny Pb-212 after IP injection of Ra-224 labeled CaCO3 microparticles, was found in rats with high translational value to the clinical setting. SPECT imaging supported distribution of the Ra-224 labeled microparticles to the entire peritoneal lumen in the animals. SPECT and CT revealed some clusters of labeled microparticles. Due to the short range of the therapeutic relevant α-particles, the clusters are not expected to have an impact on therapeutic or safety aspects.

Citation Format: Jesper Fonslet, Carsten H. Nielsen, Lotte K. Kristensen, Ida S. Jorstad, Kim Lindland, Roy H. Larsen, Øyvind S. Bruland, Andreas Kjaer, Tina B. Bønsdorff. Biodistribution of Ra-224 and its daughter Pb-212 after intraperitoneal infusion of Ra-224 labeled microparticles in rats [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3922.

Ra-224 labeling of calcium carbonate microparticles for internal α-therapy: Preparation, stability, and biodistribution in mice

Internal therapy with α‐emitters should be well suited for micrometastatic disease. Radium‐224 emits multiple α‐particles through its decay and has a convenient 3.6 days of half‐life. Despite its attractive properties, the use of ²²⁴Ra has been limited to bone‐seeking applications because it cannot be stably bound to a targeting molecule. Alternative delivery systems for ²²⁴Ra are therefore of considerable interest. In this study, calcium carbonate microparticles are proposed as carriers for ²²⁴Ra, designed for local therapy of disseminated cancers in cavitary regions, such as peritoneal carcinomatosis. Calcium carbonate microparticles were radiolabeled by precipitation of ²²⁴Ra on the particle surface, resulting in high labeling efficiencies for both ²²⁴Ra and daughter ²¹²Pb and retention of more than 95% of these nuclides for up to 1 week in vitro. The biodistribution after intraperitoneal administration of the ²²⁴Ra‐labeled CaCO₃ microparticles in immunodeficient mice revealed that the radioactivity mainly remained in the peritoneal cavity. In addition, the systemic distribution of ²²⁴Ra was found to be strongly dependent on the amount of administered microparticles, with a reduced skeletal uptake of ²²⁴Ra with increasing dose. The results altogether suggest that the ²²⁴Ra‐labeled CaCO₃ microparticles have promising properties for use as a localized internal α‐therapy of cavitary cancers.

Therapeutic Effect of α-Emitting 224Ra-Labeled Calcium Carbonate Microparticles in Mice with Intraperitoneal Ovarian Cancer

BACKGROUND: Ovarian cancer patients with chemotherapy-resistant residual microscopic disease in the peritoneal cavity have a considerable need for new treatment options. Alpha-emitting radionuclides injected intraperitoneally may be an attractive therapeutic option in this situation as they are highly cytotoxic, while their short range in tissues can spare surrounding radiosensitive organs in the abdomen. Herein we evaluate the therapeutic efficacy of a novel α-emitting compound specifically designed for intracavitary radiation therapy. METHODS: The α-emitter ²²⁴Ra was absorbed on calcium carbonate microparticles. Immunodeficient, athymic nude mice with human ovarian cancer cells growing intraperitoneally were treated with different activity levels of ²²⁴Ra-microparticles. Tumor growth, survival, and tolerance of the treatment were assessed. Two tumor models based on the cell lines, ES-2 and SKOV3-luc, with different growth patterns were studied. RESULTS: In both models, intraperitoneal treatment with ²²⁴Ra-microparticles gave significant antitumor effect with either considerably reduced tumor volume or a survival benefit. An advantageous discovery was that only a few kilobecquerels per mouse were needed to yield therapeutic effects. The treatment was well tolerated up to a dose of 1000 kBq/kg with no signs of acute or subacute toxicity observed. CONCLUSIONS: Intraperitoneal α-therapy with ²²⁴Ra-microparticles demonstrated a significant potential for treatment of peritoneal micrometastases in ovarian carcinoma.

Preparation of 212Pb-labeled monoclonal antibody using a novel 224Ra-based generator solution

INTRODUCTION

Alpha-emitting radionuclides have gained considerable attention as payloads for cancer targeting molecules due to their high cytotoxicity. One attractive radionuclide for this purpose is ²¹²Pb, which by itself is a β-emitter, but acts as an in vivo generator for its short-lived α-emitting daughters. The standard method of preparing ²¹²Pb-labeled antibodies requires handling and evaporation of strong acids containing high radioactivity levels by the end user. An operationally easier and more rapid process could be useful since the 10.6h half-life of ²¹²Pb puts time constraints on the preparation protocol. In this study, an in situ procedure for antibody labeling with ²¹²Pb, using a solution of the generator nuclide ²²⁴Ra, is proposed as an alternative protocol for preparing ²¹²Pb-radioimmunoconjugates.

METHODS

Radium-224, the generator radionuclide of ²¹²Pb, was extracted from its parent nuclide, ²²⁸Th. Lead-212-labeling of the TCMC-chelator conjugated monoclonal antibody trastuzumab was carried out in a solution containing ²²⁴Ra in equilibrium with progeny. Subsequently, the efficiency of separating the ²¹²Pb-radioimmunoconjugate from ²²⁴Ra and other unconjugated daughter nuclides in the solution using either centrifugal separation or a PD-10 desalting size exclusion column was evaluated and compared.

RESULTS

Radiolabeling with ²¹²Pb in ²²⁴Ra-solutions was more than 90% efficient after only 30min reaction time at TCMC-trastuzumab concentrations from 0.15mg/mL and higher. Separation of ²¹²Pb-labeled trastuzumab from ²²⁴Ra using a PD-10 column was clearly superior to centrifugal separation. This method allowed recovery of approximately 75% of the ²¹²Pb-antibody-conjugate in the eluate, and the remaining amount of ²²⁴Ra was only 0.9±0.8% (n=7).

CONCLUSIONS

The current work demonstrates a novel method of producing ²¹²Pb-based radioimmunoconjugates from a ²²⁴Ra-solution, which may be simpler and less time-consuming for the end user compared with the method established for use in clinical trials of ²¹²Pb-TCMC-trastuzumab.

Evaluation of CD146 as Target for Radioimmunotherapy against Osteosarcoma

BACKGROUND

Osteosarcoma is a rare form of cancer but with a substantial need for new active drugs. There is a particular need for targeted therapies to combat metastatic disease. One possible approach is to use an antibody drug conjugate or an antibody radionuclide conjugate to target the osteosarcoma metastases and circulating tumor cells. Herein we have evaluated a radiolabeled monoclonal antibody targeting CD146 both in vitro and in vivo.

METHODS AND RESULTS

A murine monoclonal anti-CD146 IgG1 isotype antibody, named OI-3, was developed along with recombinant chimeric versions with human IgG1 or human IgG3 Fc sequences. Using flow cytometry, selective binding of OI-3 to human osteosarcoma cell lines OHS, KPDX and Saos-2 was confirmed. The results confirm a higher expression level of CD146 on human osteosarcoma cells than HER2 and EGFR; antigens targeted by commercially available therapeutic antibodies. The biodistribution of 125I-labeled OI-3 antibody variants was compared with 125I-labeled chimeric anti-EGFR antibody cetuximab in nude mice with subcutaneous OHS osteosarcoma xenografts. OI-3 was able to target CD146 expressing tumors in vivo and showed improved tumor to tissue targeting ratios compared with cetuximab. Subsequently, the three OI-3 variants were conjugated with p-SCN-Bn-DOTA and labeled with a more therapeutically relevant radionuclide, 177Lu, and their biodistributions were studied in the nude mouse model. The 177Lu-labeled OI-3 variants were stable and had therapeutically relevant biodistribution profiles. Dosimetry estimates showed higher absorbed radiation dose to tumor than all other tissues after administration of the chimeric IgG1 OI-3 variant.

CONCLUSION

Our results indicate that CD146 can be targeted in vivo by the radiolabeled OI-3 antibodies.

Abstract LB-252: Efficacy and safety results of Betalutin® (177Lu-DOTA-HH1) in a phase I/II study of patients with non-hodgkin B-cell lymphoma (NHL)

CD37 is an internalizing transmembrane antigen highly expressed on most B-cell malignancies, and is a promising therapeutic target. Betalutin® is a novel CD37-binding murine IgG1 antibody (HH1) labelled with the beta-emitter lutetium-177, in a ready-to-use formulation currently in Phase 1/2 clinical development. Following the completion of recruitment into Arms 1 & 2 of this phase I/II study, efficacy and safety data from patients (pts) receiving Betalutin are reported.

Methods: Patients with relapsed incurable NHL of follicular grade I-IIIA, marginal zone, mantle cell, lymphoplasmacytic and small lymphocytic subtypes and with platelet counts ? 150 x109/l were eligible for inclusion in the study. Pts received rituximab (375 mg/m2) on day 1 and 8 to deplete normal B cells. On day 29 pre-dosing with 50mg HH1 (cold CD37 antibody) was administered before Betalutin injection (Arm 1 and phase 2). In Arm 2 Betalutin was administered without HH1 pre-dosing on day 29. The starting doses for Arm 1 and 2 were 10 MBq/kg and 15 MBq/kg respectively. Response was assessed by FDG PET/CT scans.

Results: A total of 18 evaluable pts were enrolled into Arm 1/phase II (n = 15) and Arm 2 (n = 3) with a median age of 68 years and either follicular lymphoma (n = 17), or mantle cell lymphoma (n = 1). The number of prior therapies ranged from 1 to 8. An additional, 3 pts have been enrolled in the phase 2 part of the study, data from these pts will also be presented.

The most common toxicities observed were hematologic with all DLTs being reversible and manageable. In Arm 1, at 20 MBq/kg (n = 3), G 3/4 neutropenia and/or thrombocytopenia were observed in all pts. Platelet transfusions were given to 2 pts. At 15 MBq/kg (n = 6), 2 DLTs were observed: one G 3 thrombocytopenia lasting >14 days and one G 4 neutropenia/ thrombocytopenia lasting >7 days. Both DLTs recovered without intervention. In Arm 2 with 15 MBq/kg (n = 2) G4 thrombocytopenia was observed in both pts and one patient also had G4 neutropenia lasting >7 days. This pt was hospitalised due to sepsis. No DLTs have been reported at 10 MBq/kg in either arm. Eleven serious adverse events (SAEs) were reported by 8 pts: Atrial fibrillation (n = 2) was the only SAE occurring in more than one pt (at 15 MBq/kg in Arm 1). No secondary malignancies or other long-term events were observed.

The overall tumor response rate observed in 17 evaluable pts was 65%, comprising 4/17 complete responses, 7/17 partial responses, 3/17 stable disease and 3/17 progressive disease. In addition, one pt had a confirmed transformed lymphoma at 3 months. One pt is still in remission 3 years after treatment.

Conclusions: Betalutin, a single dose, ready-to-use formulation, has a predictable and manageable safety profile. Most AEs were haematological, all transient and reversible. Promising efficacy and durable responses were observed. Betalutin has the potential to be a novel, safe and effective therapy for B-cell malignancies.

Citation Format: Arne Kolstad, Ulf Madsbu, Matthew Beasley, Michael Bayne, Caroline Stokke, Tore Bach-Gansmo, Ayca Muftuler Løndalen, Jon Erik Holtedahl, Mona Elisabeth Revheim, Øyvind Bruland, Jostein Dahle, Laurie Baylor Curtis, Åse Østengen, Simon Turner, Nils Bolstad, Roy H. Larsen, Signe Spetalen, Martin Erlanson, Stine Nygaard Rudå, Harald Holte. Efficacy and safety results of Betalutin® (177Lu-DOTA-HH1) in a phase I/II study of patients with non-hodgkin B-cell lymphoma (NHL). [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr LB-252.

Targeted Cancer Therapy with a Novel Anti-CD37 Beta-Particle Emitting Radioimmunoconjugate for Treatment of Non-Hodgkin Lymphoma

177Lu-DOTA-HH1 (177Lu-HH1) is a novel anti-CD37 radioimmunoconjugate developed to treat non-Hodgkin lymphoma. Mice with subcutaneous Ramos xenografts were treated with different activities of 177Lu-HH1, 177Lu-DOTA-rituximab (177Lu-rituximab) and non-specific 177Lu-DOTA-IgG1 (177Lu-IgG1) and therapeutic effect and toxicity of the treatment were monitored. Significant tumor growth delay and increased survival of mice were observed in mice treated with 530 MBq/kg 177Lu-HH1 as compared with mice treated with similar activities of 177Lu-rituximab or non-specific 177Lu-IgG1, 0.9% NaCl or unlabeled HH1. All mice injected with 530 MBq/kg of 177Lu-HH1 tolerated the treatment well. In contrast, 6 out of 10 mice treated with 530 MBq/kg 177Lu-rituximab experienced severe radiation toxicity. The retention of 177Lu-rituximab in organs of the mononuclear phagocyte system was longer than for 177Lu-HH1, which explains the higher toxicity observed in mice treated with 177Lu-rituximab. In vitro internalization studies showed that 177Lu-HH1 internalizes faster and to a higher extent than 177Lu-rituximab which might be the reason for the better therapeutic effect of 177Lu-HH1.

177Lu-DOTA-HH1, a novel anti-CD37 radio-immunoconjugate: a study of toxicity in nude mice

BACKGROUND

CD37 is an internalizing B-cell antigen expressed on Non-Hodgkin lymphoma (NHL) and chronic lymphocytic leukemia cells (CLL). The anti-CD37 monoclonal antibody HH1 was conjugated to the bifunctional chelator p-SCN-Bn-DOTA and labelled with the beta-particle emitting radionuclide 177Lu creating the radio-immunoconjugate (RIC) 177Lu-DOTA-HH1 (177Lu-HH1, trade name Betalutin). The present toxicity study was performed prior to initiation of clinical studies with 177Lu-HH1.

METHODOLOGY/PRINCIPAL FINDINGS

Nude mice with or without tumor xenografts were treated with 50 to 1000 MBq/kg 177Lu- HH1 and followed for clinical signs of toxicity up to ten months. Acute, life threatening bone marrow toxicity was observed in animals receiving 800 and 1000 MBq/kg 177Lu-HH1. Significant changes in serum concentrations of liver enzymes were evident for treatment with 1000 MBq/kg 177Lu-HH1. Lymphoid depletion, liver necrosis and atrophy, and interstitial cell hyperplasia of the ovaries were also observed for mice in this dose group.

CONCLUSIONS/SIGNIFICANCE

177Lu-DOTA-HH1 was well tolerated at dosages about 10 times above those considered relevant for radioimmunotherapy in patients with B-cell derived malignancies.The toxicity profile was as expected for RICs. Our experimental results have paved the way for clinical evaluation of 177Lu-HH1 in NHL patients.

Advantage of lutetium-177 versus radioiodine immunoconjugate in targeted radionuclide therapy of b-cell tumors

BACKGROUND

We herein report a comparison of the radiolabels 177Lu and 125I bound to the monoclonal antibody HH1 that targets the CD37 antigen expressed on non-Hodgkin B-cell lymphomas.

MATERIALS AND METHODS

Mixtures of 177Lu and 125I-labeled HH1 antibody were co-injected into nude mice carrying Ramos xenografts and the biodistribution using the paired label format allowing tracer comparisons in each individual mouse.

RESULTS

Products of the two radionuclides had very similar immunoractivity in vitro but showed different properties in vivo. Both products had relevant stability in blood and most normal tissues in nude mice carrying subcutaneous Ramos xenografts. However, both the tumor uptake and retention were significantly higher for 177Lu vs. 125I labeled HH1. The tumor to normal tissue ratios were several-fold improved for 177Lu compared to radioiodine labeled antibodies.

CONCLUSION

The data presented herein support the evaluation of CD37 as a target for clinical 177Lu-based radioimmunotherapy against b-cell malignancies.

Biodistribution and dosimetry of (177)Lu-tetulomab, a new radioimmunoconjugate for treatment of non-Hodgkin lymphoma

The biodistribution of the anti-CD37 radioimmunoconjugate ¹⁷⁷Lu-tetraxetan-tetulomab (¹⁷⁷Lu-DOTA-HH1) was evaluated. Biodistribution of ¹⁷⁷Lu-tetraxetan-tetulomab was compared with ¹⁷⁷Lu-tetraxetan-rituximab and free ¹⁷⁷Lu in nude mice implanted with Daudi lymphoma xenografts. The data showed that ¹⁷⁷Lu-tetulomab had a relevant stability and tumor targeting properties in the human lymphoma model. The half-life of ¹⁷⁷Lu allowed significant tumor to normal tissue ratios to be obtained indicating that ¹⁷⁷Lu-tetraxetan-tetulomab could be suitable for clinical testing. The biological and effective half-life in blood was higher for ¹⁷⁷Lu-tetraxetan-tetulomab than for ¹⁷⁷Lu-tetraxetan-rituximab. The biodistribution of ¹⁷⁷Lu-tetraxetan-tetulomab did not change significantly when the protein dose was varied from 0.01 to 1 mg/kg. Dosimetry calculations showed that the absorbed radiation doses to normal tissues and tumor in mice were not significantly different for ¹⁷⁷Lu-tetraxetan-tetuloma b and ¹⁷⁷Lu-tetraxetan-rituximab. The absorbed radiation doses were extrapolated to human absorbed radiation doses. These extrapolated absorbed radiation doses to normal tissues for ¹⁷⁷Lu-tetraxetan-tetulomab at an injection of 40 MBq/kg were significantly lower than the absorbed radiation doses for 15 MBq/kg Zevalin, suggesting that higher tumor radiation dose can be reached with ¹⁷⁷Lu-tetraxetan-tetulomab in the clinic.

Evaluating antigen targeting and anti-tumor activity of a new anti-CD37 radioimmunoconjugate against non-Hodgkin's lymphoma

The monoclonal antibody against CD20, rituximab, alone, or as part of combination therapies, is standard therapy for non-Hodgkin's B-cell lymphoma. Despite significantly better clinical results obtained for beta-emitting radioimmunoconjugates (RICs), RICs targeting CD20 are not commonly used in medical practice, partly because of competition for the CD20 target. Therefore, novel therapeutic approaches against other antigens are intriguing. Here, the binding properties of a novel antibody against CD37 (tetulomab) were compared with those of rituximab. The therapeutic effect of (177)Lu-tetulomab was compared with (177)Lu-rituximab on Daudi cells in vitro. The biodistribution, therapeutic and toxic effects of (177)Lu-tetulomab and unlabeled tetulomab were determined in SCID mice injected with Daudi cells. The affinity of tetulomab to CD37 was similar to the affinity of rituximab to CD20, but the CD37-tetulomab complex was internalized 10-times faster than the CD20-rituximab complex. At the same concentration of antibody, (177)Lu-tetulomab was significantly more efficient in inhibiting cell growth than was (177)Lu-rituximab, even though the cell-bound activity of (177)Lu-rituximab was higher. Treatment with 50 and 100 MBq/kg (177)Lu-tetulomab resulted in significantly increased survival of mice, compared with control groups treated with tetulomab or saline. The CD37 epitope recognized by tetulomab was highly expressed in 216 out of 217 tumor biopsies from patients with B-cell lymphoma. This work warrants further pre-clinical and clinical studies of (177)Lu-tetulomab.

Assessment of long-term radiotoxicity after treatment with the low-dose-rate alpha-particle-emitting radioimmunoconjugate (227)Th-rituximab

PURPOSE

The anti-CD20 antibody rituximab labelled with the alpha-particle-emitting radionuclide (227)Th is of interest as a radiotherapeutic agent for treatment of lymphoma. Complete regression of human lymphoma Raji xenografts in 60% of mice treated with 200 kBq/kg (227)Th-rituximab has been observed. To evaluate possible late side effects of (227)Th-rituximab, the long-term radiotoxicity of this potential radiopharmaceutical was investigated.

METHODS

BALB/c mice were injected with saline, cold rituximab or 50, 200 or 1,000 kBq/kg (227)Th-rituximab and followed for up to 1 year. In addition, nude mice with Raji xenografts treated with various doses of (227)Th-rituximab were also included in the study. Toxicity was evaluated by measurements of mouse body weight, white blood cell (WBC) and platelet counts, serum clinical chemistry parameters and histological examination of tissues.

RESULTS

Only the 1,000 kBq/kg dosage resulted in decreased body weight of the BALB/c mice. There was a significant but temporary decrease in WBC and platelet count in mice treated with 400 and 1,000 kBq/kg (227)Th-rituximab. Therefore, the no-observed-adverse-effect level (NOAEL) was 200 kBq/kg. The maximum tolerated activity was between 600 and 1,000 kBq/kg. No significant signs of toxicity were observed in histological sections in any examined tissue. There were significantly (p < 0.05), but transiently, higher concentrations of serum bile acids and aspartate aminotransferase in mice treated with either (227)Th-rituximab or non-labelled antibody when compared with control mice. The maximum tolerated dose to bone marrow was between 2.1 and 3.5 Gy.

CONCLUSION

Therapeutically relevant dose levels of (227)Th-rituximab were well tolerated in mice. Bone marrow suppression, as indicated by decrease in WBC count, was the dose-limiting radiotoxicity. These toxicity data together with anti-tumour activity data in a CD20-positive xenograft mouse model indicate that therapeutic effects could be obtained with relatively safe dosage levels of the radioimmunoconjugate.

In vitro cytotoxicity of low-dose-rate radioimmunotherapy by the alpha-emitting radioimmunoconjugate Thorium-227-DOTA-rituximab

PURPOSE

To determine whether the low-dose-rate alpha-particle-emitting radioimmunoconjugate (227)Th-1,4,7,10-p-isothiocyanato-benzyl-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA)-rituximab can be used to inactivate lymphoma cells growing as single cells and small colonies.

METHODS AND MATERIALS

CD20-positive lymphoma cell lines were treated with (227)Th-DOTA-rituximab for 1-5 weeks. To simulate the in vivo situation with continuous but decreasing supply of radioimmunoconjugates from the blood pool, the cells were not washed after incubation with (227)Th-DOTA-rituximab, but half of the medium was replaced with fresh medium, and cell concentration and cell-bound activity were determined every other day after start of incubation. A microdosimetric model was established to estimate the average number of hits in the nucleus for different localizations of activity.

RESULTS

There was a specific targeted effect on cell growth of the (227)Th-DOTA-rituximab treatment. Although the cells were not washed after incubation with (227)Th-DOTA-rituximab, the average contribution of activity in the medium to the mean dose was only 6%, whereas the average contribution from activity on the cells' own surface was 78%. The mean dose rates after incubation with 800 Bq/mL (227)Th-DOTA-rituximab varied from 0.01 to 0.03 cGy/min. The average delay in growing from 10(5) to 10(7) cells/mL was 15 days when the cells were treated with a mean absorbed radiation dose of 2 Gy alpha-particle radiation from (227)Th-DOTA-rituximab, whereas it was 11 days when the cells were irradiated with 6 Gy of X-radiation. The relative biologic effect of the treatment was estimated to be 2.9-3.4.

CONCLUSIONS

The low-dose-rate radioimmunoconjugate (227)Th-DOTA-rituximab is suitable for inactivation of single lymphoma cells and small colonies of lymphoma cells.

Preparation of TH227-labeled radioimmunoconjugates, assessment of serum stability and antigen binding ability

In this study, the feasibility of constructing radioimmunoconjugates by using the novel therapeutic candidate alpha-emitter, (227)Th, was evaluated. By use of the bifunctional chelator, p-SCN-benzyl-DOTA, (227)Th was conjugated to the two monoclonal antibodies, rituximab and trastuzumab. Their stability in 80% fetal bovine serum at 37 degrees C was measured. The immunoreactive fractions were determined by using CD20- and HER/2-positive cells, respectively. The overall labeling yield spanned from 6% to 17%. The radioimmunoconjugates demonstrated a relevant stability in serum and showed appropriate antigen-binding abilities.

Evaluation of the binding of radiolabeled rituximab to CD20-positive lymphoma cells: an in vitro feasibility study concerning low-dose-rate radioimmunotherapy with the alpha-emitter 227Th

Radioimmunotherapy (RIT) with the alpha-emitter 227Th is currently under evaluation. 227Th is conjugated to the chimeric anti-CD20 monoclonal antibody rituximab, using the chelator p-isothiocyanato-benzyl-DOTA. In this study, the binding of 227Th-DOTA-p-benzyl-rituximab to three different CD-20-positive lymphoma cell lines, Raji, Rael, and Daudi, were evaluated. Equilibrium and kinetic binding experiments were used to determine binding parameters, including the association and dissociation rate constants, the equilibrium dissociation constants, and the total number of antigens for Raji, Rael, and Daudi cells. There were significant differences between the cell lines with respect to both Kd and the total number of antigens. Rael cells had more than three times as many antigens as the other two cell lines, and the functional Kd found for Rael cells was significantly higher than that found for Raji and Daudi cells. These results were confirmed using flow cytometry. Rituximab was found to be localized in patches on the cell membrane. The findings indicated that 227Th-labeled rituximab has relevant antigen-targeting properties for radioimmunotherapy.

A one-step method for determining the maximum number of bound antibodies, and the affinity and association rate constants for antibody binding

OBJECTIVE

A reliable analysis of antibody binding may lead to more successful selection of the optimal antibodies. The most important parameters are affinity (equilibrium dissociation constant, Kd), the number of antigen sites on the cells (Bmax) and the on (ka) and off (kd) rate constants of binding. The affinity and the number of cellular binding sites are usually determined by equilibrium binding experiments and subsequent Scatchard analysis. The on and off rate constants are determined by kinetic binding experiments. However, it is necessary to perform two to three different types of experiment in order to determine these parameters.

METHODS

We have developed an alternative one-step method based on a kinetic binding experiment and a mathematical description of antibody binding to antigen. The method was compared with kinetic and equilibrium binding methods.

RESULTS

The results obtained using two different cell lines were in good agreement with results obtained with Scatchard analysis and kinetic binding experiments.

CONCLUSION

An alternative one-step method for determination of parameters describing binding of antibodies to antigens on cells has been developed. The method gives reliable estimates of affinity and number of antigens and in addition gives information on the kinetics of binding.

Targeted cancer therapy with a novel low-dose rate alpha-emitting radioimmunoconjugate

Alpha-emitting radionuclides are highly cytotoxic and are of considerable interest in the treatment of cancer. A particularly interesting approach is in radioimmunotherapy. However, alpha-emitting antibody conjugates have been difficult to exploit clinically due to the short half-life of the radionuclides, low production capability, or limited source materials. We have developed a novel technology based on the low-dose rate alpha-particle-emitting nuclide (227)Th, exemplified here using the monoclonal antibody rituximab. In vitro, this radioimmunoconjugate killed lymphoma cells at Becquerel per milliliter (Bq/mL) levels. A single injection of (227)Th-rituximab induced complete tumor regression in up to 60% of nude mice bearing macroscopic (32-256 mm(3)) human B-lymphoma xenografts at Becquerel per gram (Bq/g) levels without apparent toxicity. Therapy with (227)Th-rituximab was significantly more effective than the control radioimmunoconjugate (227)Th-trastuzumab and the standard beta-emitting radioimmunoconjugate for CD20(+) lymphoma(90)Y-tiuxetan-ibritumomab. Thorium-227 based constructs may provide a novel approach for targeted therapy against a wide variety of cancers.

High-linear energy transfer irradiation targeted to skeletal metastases by the alpha-emitter 223Ra: adjuvant or alternative to conventional modalities?

The bone-seeking, alpha-particle-emitting radiopharmaceutical Alpharadin, 223RaCl2 (half-life=11.4 days), is under clinical development as a novel treatment for skeletal metastases from breast and prostate cancer. This article summarizes the current status of preclinical and clinical research on 223RaCl2. Potential advantages of 223Ra to that of external beam irradiation and registered beta-emitting bone seekers are discussed. Published data of 223Ra dosimetry in mice and a therapeutic study in a skeletal metastases model in nude rats have indicated significant therapeutic potential of bone-seeking alpha-emitters. This article provides short-term and long-term results from the first clinical single dosage trial. We also present data from a repeated dosage study of five consecutive injections of 50 kBq/kg body weight, once every 3rd week, or two injections of 125 kBq/kg body weight, 6 weeks apart. Furthermore, interim results are described for a randomized phase 2 trial involving 64 patients with hormone-refractory prostate cancer and painful skeletal metastases who received four monthly injections of 223Ra or saline as an adjuvant to external beam radiotherapy. Lastly, we present preliminary dose estimates for 223Ra in humans. Results indicate that repeated dosing is feasible and toxicity is low, and that opportunities are available for combined treatment strategies.

First in vivo evaluation of liposome-encapsulated 223Ra as a potential alpha-particle-emitting cancer therapeutic agent

BACKGROUND

Liposomes carrying chemotherapeutics have had some success in cancer treatment and may also be suitable carriers for therapeutic radionuclides. This study was designed to evaluate the biodistribution and to estimate the radiation doses of the alpha emitter 223Ra loaded into pegylated liposomes in selected tissues.

MATERIALS AND METHODS

223Ra was encapsulated in pegylated liposomal doxorubicin (PLD) by ionophore-mediated loading. The biodistribution of liposomal 223Ra was compared to free cationic 223Ra in Balb/C mice.

RESULTS

Liposomal 223Ra circulated in the blood with an initial half-life in excess of 24 hours, which agreed well with that reported for PLD in rodents, while the blood half-life of cationic 223Ra was considerably less than an hour. When liposomal 223Ra was catabolized, the released 223Ra was either excreted or taken up in the skeleton. This skeletal uptake increased up to 14 days after treatment, but did not reach the level seen with free 223Ra. Pre-treatment with non-radioactive PLD 4 days in advance lessened the liver uptake of liposomal 223Ra. Dose estimates showed that the spleen, followed by bone surfaces, received the highest absorbed doses.

CONCLUSION

Liposomal 223Ra was relatively stable in vivo and may have potential for radionuclide therapy and combination therapy with chemotherapeutic agents.

Radiotoxicity of the alpha-emitting bone-seeker 223Ra injected intravenously into mice: histology, clinical chemistry and hematology

BACKGROUND

The alpha-emitter 223Ra, which localizes in osteoblastic active zones, including on skeletal surfaces and in osteoblastic metastases, has recently been introduced as a potential therapeutic agent against skeletal metastases. Here, the adverse effects of high dosages in animals were investigated.

MATERIALS AND METHODS

Balb/c mice received intravenously (i.v.) either 1250, 2500, or 3750 kBq/kg of dissolved 223RaCl2 and were followed in the initial toxicity phase. At the 4-week end-point, the animals were sacrificed and blood samples were collected to study the effects on clinical chemistry and hematological parameters. Selected organs were weighed and tissue samples examined by microscopy.

RESULTS

Treatment with 223Ra caused a dose-related minimal to moderate depletion of osteocytes and osteoblasts in the bones. Furthermore, a dose-related minimal to marked depletion of the hematopoietic cells in the bone marrow, and a minimal to slight extramedullary hematopoiesis in the spleen and in the mandibular and mesenteric lymph nodes were observed. The LD50 for acute toxicity, defined as death within 4 weeks of receiving the substance, was not reached.

CONCLUSION

This study demonstrated that high doses of the bone-seeker 223Ra did not completely inactivate the blood-producing cells. The relatively high tolerance to skeletal alpha doses was probably caused by the surviving pockets of red bone marrow cells beyond the range of alpha particles from the bone surfaces, and the recruitment of peripheral stems cells.

Initial evaluation of 227Th-p-benzyl-DOTA-rituximab for low-dose rate α-particle radioimmunotherapy

Radioimmunotherapy has proven clinically effective in patients with non-Hodgkin's lymphoma. Radioimmunotherapy trials have so far been performed with beta-emitting isotopes. In contrast to beta-emitters, the shorter range and high linear energy transfer (LET) of alpha particles allow for more efficient and selective killing of individually targeted tumor cells. However, there are several obstacles to the use of alpha-particle immunotherapy, including problems with chelation chemistry and nontarget tissue toxicity. The alpha-emitting radioimmunoconjugate (227)Th-DOTA-p-benzyl-rituximab is a new potential anti-lymphoma agent that might overcome some of these difficulties. The present study explores the immunoreactivity, in vivo stability and biodistribution, as well as the effect on in vitro cell growth, of this novel radioimmunoconjugate. To evaluate in vivo stability, uptake in balb/c mice of the alpha-particle-emitting nuclide (227)Th alone, the chelated form, (227)Th-p-nitrobenzyl-DOTA and the radioimmunoconjugate (227)Th-DOTA-p-benzyl-rituximab was compared in a range of organs at increasing time points after injection. The immunoreactive fraction of (227)Th-DOTA-p-benzyl-rituximab was 56-65%. During the 28 days after injection of radioimmunoconjugate only, very modest amounts of the (227)Th had detached from DOTA-p-benzyl-rituximab, indicating a relevant stability in vivo. The half-life of (227)Th-DOTA-p-benzyl-rituximab in blood was 7.4 days. Incubation of lymphoma cells with (227)Th-DOTA-p-benzyl-rituximab resulted in a significant antigen-dependent inhibition of cell growth. The data presented here warrant further studies of (227)Th-DOTA-p-benzyl-rituximab.

First clinical experience with alpha-emitting radium-223 in the treatment of skeletal metastases

PURPOSE

The main goals were to study the safety and tolerability of the alpha-emitter radium-223 (223Ra) in breast and prostate cancer patients with skeletal metastases. In addition, pain palliation was evaluated.

EXPERIMENTAL DESIGN

Fifteen prostate and 10 breast cancer patients enrolled in a phase I trial received a single i.v. injection of 223Ra. Five patients were included at each of the dosages: 46, 93, 163, 213, or 250 kBq/kg and followed for 8 weeks. Palliative response was evaluated according to the pain scale of the European Organization for Research and Treatment of Cancer QLQ C30 questionnaire at baseline and at 1, 4, and 8 weeks after injection.

RESULTS

Weekly blood sampling during follow-up revealed mild and reversible myelosuppression with nadir 2 to 4 weeks after the injection. Importantly, for thrombocytes only grade 1 toxicity was reported. Grade 3 neutropenia and leucopenia occurred in two and three patients, respectively. Mild, transient diarrhea was observed in 10 of the 25 patients. Nausea and vomiting was more frequently observed in the highest dosage group. Serum alkaline phosphatase decreased with nadir averages of 29.5% in females and 52.1% in males. Pain relief was reported by 52%, 60%, and 56% of the patients after 7 days, 4, and 8 weeks, respectively. 223Ra cleared rapidly from blood and was below 1% of initial level at 24 hours. Gamma camera images indicated, in accordance with pretreatment (99m)Tc-MDP scans, accumulation of 223Ra in skeletal lesions. Elimination was mainly intestinal. Median survival exceeded 20 months.

CONCLUSIONS

223Ra was well tolerated at therapeutically relevant dosages. Phase II studies have therefore been initiated.

Preparation and preclinical assessment of folate-conjugated, radiolabelled antibodies

BACKGROUND

The folate receptor (FR) is frequently over-expressed on human cancer cells and may be a suitable target for radiopharmaceuticals. Because of FR expression in the kidneys, the rapidly renal clearing folate is not well suited as a carrier for therapeutic radionuclides. As an alternative, folate-immunoglobulin conjugates were studied as potential carriers for radionuclides.

MATERIALS AND METHODS

Two types of conjugate were evaluated: (i) folate conjugated to osteosarcoma antigen directed murine monoclonal antibodies TP-1 and TP-3 or (ii) folate conjugated to non-specific polyclonal human IgG (HIg6). These constructs were labelled with 211At or 125I.

RESULTS

The folate-HIg6-radionuclide conjugate showed high affinity to immobilized folate binding protein and also to folate receptor-expressing cells. Folate conjugates of TP-1 and TP-3 had a selective binding in vitro to antigen-expressing tumor cells and also to cells expressing FR only, thus the folate antibody constructs possessed dual affinity binding. Comparisons between folate-conjugated and non-folated antibody in Balb/C mice showed that the folate did not markedly change the properties of the radiolabelled antibody.

CONCLUSION

It was demonstrated that folate-conjugated antibodies carrying therapeutic radionuclides have relevant properties for the targeting of tumor cells expressing FR.

Sterically stabilized liposomes as a carrier for alpha-emitting radium and actinium radionuclides

The alpha-particle emitting radionuclides (223)Ra (t(1/2) = 11.4 d), (224)Ra (t(1/2) = 3.6 d), and (225)Ac(t(1/2) = 10.0 d) may have a broad application in targeted radiotherapy provided that they could be linked to vehicles with tumor affinity. The potential usefulness of liposomes as carriers was studied in the present work. Radium and actinium radionuclides could be loaded in good yields into sterically stabilized liposomes. Subsequent coating of the liposomes with a folate-F(ab')(2) construct yielded a product with affinity towards tumor cells expressing folate receptors. Radionuclide loaded liposomes showed excellent stability in serum in vitro.

Thorium and actinium polyphosphonate compounds as bone-seeking alpha particle-emitting agents

The present study explores the use of alpha-particle-emitting, bone-seeking agents as candidates for targeted radiotherapy. Actinium and thorium 1,4,7,10 tetraazacyclododecane N,N',N'',N''' 1,4,7,10-tetra(methylene) phosphonic acid (DOTMP) and thorium-diethylene triamine N,N',N'' penta(methylene) phosphonic acid (DTMP) were prepared and their biodistribution evaluated in conventional Balb/C mice at four hours after injection. All three bone-seeking agents showed a high uptake in bone and a low uptake in soft tissues. Among the soft tissue organs, only kidney had a relatively high uptake. The femur/kidney ratios for 227Th-DTMP, 228-Ac-DOTMP and 227Th-DOTMP were 14.2, 7.6 and 6.0, respectively. A higher liver uptake of 228Ac-DOTMP was seen than for 227Th-DTMP and 227Th-DOTMP. This suggests that some demetallation of the 228Ac-DOTMP complex had occurred. The results indicate that 225Ac-DOTMP, 227Th-DOTMP and 227Th-DTMP have promising properties as potential therapeutic bone-seeking agents.

Targeting of osseous sites with alpha-emitting 223Ra: comparison with the beta-emitter 89Sr in mice

The bone-seeking property and the potential exposure of red marrow by the alpha-particle emitter (223)Ra (half-life, 11.43 d) were compared with those of the beta-emitter (89)Sr (half-life, 50.53 d).

METHODS

The biodistributions of (223)Ra and (89)Sr were studied in mice. Tissue uptake was determined at 1 h, 6 h, 1 d, 3 d, and 14 d after intravenous administration. Radiation absorbed doses were calculated for soft tissues and for bone. Multicellular-level doses were estimated for bone marrow cavities.

RESULTS

Both (89)Sr and (223)Ra selectively concentrated on bone surfaces relative to soft tissues. The measured bone uptake of (223)Ra was slightly higher than that of (89)Sr. At 24 h, the femur uptake of (223)Ra was 40.1% +/- 7.7% of the administered activity per gram of tissue. The uptake in spleen and most other soft tissues was higher for (223)Ra than for (89)Sr. Although predominant clearance of (223)Ra was observed from the soft tissues within the first 24 h, the bone uptake of (223)Ra, which was not significantly different from maximum after only 1 h, was not significantly reduced during the 14 d. Furthermore, little redistribution of (223)Ra daughter products away from bone was found (2% at 6 h and less than 1% at 3 d). Estimates of dose to marrow cavities showed that the (223)Ra alpha-emitter might have a marrow-sparing advantage compared with beta-emitters for targeting osteoid surfaces because the short-range alpha-particles irradiate a significantly lower fraction of the marrow volumes. At the same time, the bone surfaces will receive a therapeutically effective radiation dose.

CONCLUSION

The results of this study indicate that (223)Ra is a promising candidate for high-linear-energy transfer alpha-particle irradiation of cancer cells on bone surfaces. (223)Ra can, together with its daughter radionuclides, deliver an intense and highly localized radiation dose to the bone surfaces with substantially less irradiation of healthy bone marrow compared with standard bone-seeking beta-emitters.

Significant antitumor effect from bone-seeking, alpha-particle-emitting (223)Ra demonstrated in an experimental skeletal metastases model

The therapeutic efficacy of the alpha-particle-emitting radionuclide (223)Ra (t(1/2) = 11.4 days) in the treatment against experimental skeletal metastases in rats was addressed. Biodistribution studies, involving measurement of (223)Ra in bone marrow samples, were performed in rats after i.v. injection. To study the therapeutic effect of (223)Ra, an experimental skeletal metastases model in nude rats was used. Animals that had received 10(6) MT-1 human breast cancer cells were treated with (223)Ra doses in the range of 6-30 kBq after 7 days. The biodistribution experiment demonstrated that (223)Ra was selectively concentrated in bone as compared with soft tissues. The femur content of (223)Ra was 800 +/- 56% of injected dose per gram tissue times gram body weight (b.w.; mean +/- SD) 1 day after the injection and 413 +/- 23% of injected dose per gram tissue times gram b.w. at 14 days. The femur:kidney ratio increased from (5.9 +/- 2.0).10(2) at 1 day to (7.2 +/- 3.0).10(2) at 14 days, whereas the femur:liver ratio increased from (6.2 +/- 0.2).10(2) to (9.1 +/- 6.6).10(2). Femur:spleen ratio increased from (8.1 +/- 0.3).10(2) at 1 day to (6.4 2.2).10(3) at 14 days. The femoral bone:marrow ratio was 6.5 +/- 2.1 after day 1 and larger than 15 at day 14. All of the tumor-bearing control animals had to be sacrificed because of tumor-induced paralysis 20-30 days after injection with tumor cells, whereas the rats treated with > or =10 kBq of (223)Ra had a significantly increased symptom-free survival (P < 0.05). Also 36% (5 of 14) of rats treated with 11 kBq and 40% (2 of 5) of rats treated with 10 kBq were alive beyond the 67-day follow-up period. No signs of bone marrow toxicity or b.w. loss were observed in the groups of treated animals. The significant antitumor effect of (223)Ra at doses that are tolerated by the bone marrow is most likely linked to the intense and highly localized radiation dose from alpha-particles at the bone surfaces. The results of this study indicate that (223)Ra should be additionally studied as a potential bone marrow-sparing treatment of cancers involving the skeleton.

Evaluation of potential chelating agents for radium

The alpha-particle-emitting radionuclide 223Ra (t(1/2) = 11.4 d) is of interest for use in targeted radionuclide therapy. In order to provide radium-labeled monoclonal antibodies, the development of a chelator binding radium in a stable fashion is required. As a part of the search for potentially useful radium chelators, the relative stability of 223Ra-chelates with linear and cyclic chelating agents was evaluated by means of competition extraction experiments.

Radiation doses to non-Hodgkin's lymphoma cells and normal bone marrow exposed in vitro. Comparison of an alpha-emitting radioimmunoconjugate and external gamma-irradiation

PURPOSES

The alpha-emitting radionuclide 211At conjugated to the CD20 targeting chimeric monoclonal antibody rituximab was studied to: (a) Estimate radiation dose components to lymphoma and bone marrow (BM) cells exposed in vitro. (b) Calculate the mean absorbed radiation doses in various normal tissues of mice following intravenous injection.

MATERIALS AND METHODS

B-lymphoma cells (RAEL) and normal human BM cells were incubated with increasing concentrations of the radioimmunoconjugate. Based on binding kinetics and on measured cellular and nuclear diameters, the radiation doses were calculated using microdosimetric methods.

RESULTS

Targeting of 211At-rituximab to RAEL cells was extensive and stable compared with the binding to BM cells. The absorbed radiation doses from cell-bound activity at an initial activity concentration of 10 kBq ml(-1) were 0.645 and 0.021 Gy to RAEL and BM cells, respectively. In comparison, the contribution from unbound conjugate in the medium during 1h exposure was 0.042 and 0.043 Gy. The D(0) value for RAEL cells was 0.55 Gy, but only 0.34 Gy for BM cells, whereas corresponding D(0) values were 0.72 and 1.21 Gy after a single exposure to external 60Co gamma-rays. Mean absorbed doses of 1.31, 0.48 and 0.36 Gy for blood, lungs and heart were calculated in mice injected with 5.4kBq g(-1) of 211At-rituximab.

CONCLUSION

Despite the higher inherent sensitivity of the BM cells to the alpha-irradiation, there was, related to the radioactivity concentrations of 211At-rituximab, several logs greater cell kill in RAEL cells, illustrating the tumour-specific nature of the targeting.

Optimisation of cyclotron production parameters for the 209Bi(alpha, 2n) 211At reaction related to biomedical use of 211At

The cyclotron alpha beam production of 211At and of the contaminant 210At related to beam energy were studied. Radiochemical purification of 211At from the other main contaminant, 210Po, by an extraction procedure was also evaluated. To avoid impurities 28MeV has previously been considered as a maximum beam energy, but by using instead 29.1 MeV as a limit a large increase in EOB yield and sufficient radiochemical purity of extracted 211At were obtained. More cyclotrons could thereby deliver quantities useful for clinical cancer trials.

Demonstration of highly specific toxicity of the alpha-emitting radioimmunoconjugate(211)At-rituximab against non-Hodgkin's lymphoma cells

The ability of an alpha-emitter conjugated to a chimaeric anti-CD20 monoclonal antibody to kill selectively human B-lymphoma cells in vitro is reported. Two B-lymphoma cell lines RAEL and K422, and normal haematopoietic progenitor cells from human bone marrow aspirates were incubated with(211)At-rituximab (Rituxan(R) or MabTheratrade mark) and plated in clonogenic assays for survival analyses. Following 1 h incubation with(211)At-rituximab, in concentrations which gave an initial activity of 50 kBq ml(-1), a high tumour cell to normal bone marrow cell toxicity ratio was obtained; 4.1 to 1.0 log cell kill. Biodistribution studies of(211)At-rituximab in Balb/c mice showed similar stability as that of the iodinated analogue. The data indicate that testing of(211)At-rituximab in human patients is warranted.

Exposure of human osteosarcoma and bone marrow cells to tumour-targeted alpha-particles and gamma-irradiation: analysis of cell survival and microdosimetry

PURPOSE

This study was designed to compare the cytotoxic effects of an alpha-emitting radioimmunoconjugate, which binds to osteosarcoma but not to bone marrow cells, with those of external gamma-irradiation.

MATERIALS AND METHODS

The human osteosarcoma cell line, OHS-s1, and mononuclear cells from bone marrow (BM) harvested from healthy donors, were used for these experiments. Cells in suspension were added to various activity concentrations of the anti-osteosarcoma monoclonal antibody TP-3 radiolabelled with 211At. Following incubation for 1 h, unbound radioactivity was washed off and cell survival was determined from clonogenic assays. Microdosimetry was calculated based on binding and retention kinetics of 211At to the cells, as well as cellular and nuclear diameters. For comparison, cell suspensions were irradiated with a single dose of 60Co gamma-rays.

RESULTS

211At-labelled TP-3 showed heterogeneous binding to OHS-s1 cells, with a considerable variation among experiments. About 78% of the initially bound 211At decayed while associated with the OHS-s1 cells. D0 values estimated by microdosimetry were 0.33 (0.22-0.48, range) Gy and 1.18 (0.89-1.89) Gy for OHS-s1 and BM cells, respectively, whereas D0 values after external beam irradiation were 0.86+/-0.07Gy and 1.71+/-0.22Gy. The relative biological effectiveness (RBE) of 211At-labelled TP-3 at 37% survival was 3.43 for OHS-s1 and 1.55 for BM.

CONCLUSIONS

High-LET targeted alpha-particle exposure killed osteosarcoma cells more effectively than bone marrow cells, although heterogeneous antigen expression among these tumour cells limited the magnitude of this effect.

Influence of pretreatment with 3-amino-1-hydroxypropylidene-1,1-bisphosphonate (APB) on organ uptake of 211At and 125I-labeled amidobisphosphonates in mice

To minimize nontarget organ uptake in animals receiving radiolabeled amidobisphosphonates, the influence of pretreatment with cold 3-amino-1-hydroxypropylidene-1,1-bisphosphonate (APB, pamidronate) was studied. Three groups of animals were given pure 3-[125I]iodobenzamide-N-3-hydroxypropylidene-3,3-bisphosphonate (IBPB) and 3-[211At]astatobenzamide-N-3-hydroxypropylidene-3,3-bisphosphonate (ABPB) (control); co-injection of APB and IBPB/ABPB; and 1 h preinjection of APB followed by IBPB/ABPB, respectively. A significant reduction of uptake in normal tissue was observed, whereas the bone uptake remained constant at 35-50%ID/g tissue. This study suggests that co- or preinjection of pamidronate may reduce the normal organ radiation doses when using these radiohalogenated bisphosphonates for endoradiotherapeutic procedures.

Radiotoxicity of systemically administered 211At-labeled human/mouse chimeric monoclonal antibody: a long-term survival study with histologic analysis

PURPOSE

The antitenascin human/mouse chimeric monoclonal antibody labeled with the alpha-particle-emitting radionuclide 211At is of interest as an endoradiotherapeutic agent for the treatment of brain tumors. To facilitate the investigation of 211At-labeled chimeric 81C6 in patients, the long-term radiotoxicity of this radiopharmaceutical has been evaluated.

METHODS AND MATERIALS

Antibody labeling was performed using N-succinimidyl 3-[211At]astato-benzoate. After an initial dose-finding experiment, a second toxicity study was carried out at 4 dose levels in groups of 30 nonthyroid blocked B6C3F1 mice per group (15 males, 15 females). Male mice received either saline or 15-81 kBq/g and females received either saline or 16-83 kBq/g of 211At-labeled antibody. Ten animals (5 males, 5 females) were followed for 6 months and the remainder for 1 year.

RESULTS

The lethal dose in 10% of animals (LD10) for 211At-labeled chimeric 81C6 was 46 kBq/g in females and 102 kBq/g in males. Toxic effects--perivascular fibrosis of the intraventricular septum of the heart, bone marrow suppression, splenic white pulp atrophy, and spermatic maturational delay--generally were confined to a few animals receiving the highest doses of labeled antibody.

CONCLUSIONS

The LD10 of 211At-labeled chimeric 81C6 in this mouse strain was about half that of [211At]astatide. These results establish the preclinical maximum tolerated dose of 211At-labeled chimeric 81C6 and define in the mouse the target organs for toxicity. These studies will be useful for determining starting doses for clinical studies with 211At-labeled chimeric 81C6.

211At- and 131I-labeled bisphosphonates with high in vivo stability and bone accumulation

Bisphosphonates were synthesized for use as carriers for astatine and iodine radioisotopes to target bone neoplasms.

METHODS

Radiohalogenated activated esters were coupled to the amino group in the side chain of the bisphosphonate. The bisphosphonate 3-amino-1-hydroxypropylidene bisphosphonate was combined with four different acylation agents: N-succinimidyl 3-[211At]astatobenzoate, N-succinimidyl 3-[131I]iodobenzoate, N-succinimidyl-5-[211At]astato-3-pyridinecarboxylate and N-succinimidyl-5-[131I]iodo-5-pyridinecarboxylate. The products, 3-[131I]iodobenzamide-N-3-hydroxypropylidene-3,3-bisphosphonate (IBPB), 3-[211At]astato-benzamide-N-3-hydroxypropylidene-3,3-bisphosphonat e (ABPB), 5-[131I]iodopyridine-3-amide-N-3-hydroxypropylidene-3,3-bisphospho nate (IPPB) and 5-[211At]astatopyridine-3-amide-N-3-hydroxypropylidene-3,3-bisphos phonate (APPB), were injected intravenously into Balb/c mice. MIRD and Monte Carlo methods were used on the basis of cumulated activity calculated from biodistribution data to estimate dose to organs and bone segments.

RESULTS

All 131I- and 211At-labeled analogs were strongly incorporated into osseous tissue and retained there at stable levels, while a rapid clearance from blood was observed. The bone uptake was found to be similar for 211At- and 131I-labeled bisphosphonate when compared in paired label experiments. Bone uptake and bone-to-tissue ratios were better for IBPB compared with IPPB, and ABPB compared with APPB. All four compounds appeared to be highly resistant to in vivo dehalogenation as indicated by low uptake of 131I/211At in the thyroid gland and stomach. According to dosimetric estimates, the bone surface-to-bone marrow ratio was three times higher with 211At than with 131I.

CONCLUSION

Both the beta-particle- and alpha-particle-emitting compounds showed high in vivo stability and excellent affinity for osseous tissue. Further preclinical evaluation is therefore warranted.

Synthesis, purification, and in vitro stability of 211At- and 125I-labeled amidobisphosphonates

A method is described for preparing 211At- and radioiodinated amidobisphosphonates. The active esters N-succinimidyl 3-(tri-methylstannyl) benzoate (ATE) and N-succinimidyl 5-(tri-methylstannyl)-3-pyridinecarboxylate (SPC) were used as precursors. The isolated and purified radiolabeled intermediates were coupled to 3-amino-1-hydroxypropylidene-1,1-bisphosphonate (APB) in high yields ranging from 60% to 97%. The lipophilicity of the compounds was found to depend on the nature of the labeled template and the halogen. High in vitro stability in mouse, fetal calf, and human serum was documented by high performance liquid chromatography.

Blocking [211At]astatide accumulation in normal tissues: preliminary evaluation of seven potential compounds

Normal tissue accumulation of 211At must be minimized during targeted radiotherapy with 211At-labeled compounds. Therefore, we investigated the ability of seven compounds to block normal organ uptake of [211At]astatide in mice: potassium iodide, sodium thiocyanate, sodium perchlorate, sodium periodate, cysteine, 2,3-dimercapto-1-propanesulfonic acid, and meso-2,3-dimercaptosuccinic acid. The monovalent anions I-, SCN-, and ClO4- reduced 211At uptake in stomach and thyroid, while thiocyanate and cysteine were the only compounds to significantly reduce activity levels in lungs and spleen. This study suggests that blocking agents may help reduce normal organ radiation doses in endoradiotherapeutic procedures with 211At-labeled radiopharmaceuticals.

Intratumour injection of immunoglobulins labelled with the alpha-particle emitter 211At: analyses of tumour retention, microdistribution and growth delay

To determine the effects of 211At-labelled antibodies in solid tumour tissue, nude mice carrying OHS human osteosarcoma xenografts received intratumour injections at dosages of 1, 2 or 4 MBq (-1) tumour. The radioisotope was conjugated to either the osteosarcoma-specific monoclonal antibody TP-3 or the non-specific polyclonal antibody hlgGkappa. Tumour retention of injected radioimmunoconjugate (RIC), measured as the percentage of injected activity dosage per gram, was significantly higher for the [211At]TP-3 (203 +/- 93 at 24.1 h post injection) compared with the [211At]hlgGkappa (57 +/- 22 at 23.2 h post injection). The radioactive count rates in body (measured at neck and abdomen) were significantly lower with the TP-3 than with the hlgGkappa. Microautoradiography of the tumour radionuclide distribution was different for the two RICs, i.e. the [211At]TP-3 was to a larger extent concentrated near the injection site, whereas the [211At]hlgGkappa was more evenly distributed all over the tumour. The tumour growth was significantly delayed as a function of the injected activity dosage but without significant difference between the specific and the non-specific RIC. According to this study, it is possible to deliver highly selective radiation doses to solid tumours using intratumour injection of alpha-particle-emitting RICs. Improved tumour retention caused by antigen binding indicates that reduced normal tissue exposure can be obtained with antigen-specific antibodies. The heterogeneous tumour dose distribution observed is, however, a major impediment to the use of alpha-particle emitters against solid tumours.

Cytotoxicity of alpha-particle-emitting astatine-211-labelled antibody in tumour spheroids: no effect of hyperthermia

The high linear energy transfer, alpha-particle-emitting radionuclide astatine-211 (211At) is of interest for certain therapeutic applications; however, because of the 55- to 70-microm path length of its alpha-particles, achieving homogeneous tracer distribution is critical. Hyperthermia may enhance the therapeutic efficacy of alpha-particle endoradiotherapy if it can improve tracer distribution. In this study, we have investigated whether hyperthermia increased the cytotoxicity of an 211At-labelled monoclonal antibody (MAb) in tumour spheroids with a radius (approximately 100 microm) greater than the range of 211At alpha-particles. Hyperthermia for 1 h at 42 degrees C was used because this treatment itself resulted in no regrowth delay. Radiolabelled chimeric MAb 81C6 reactive with the extracellular matrix antigen tenascin was added to spheroids grown from the D-247 MG human glioma cell line at activity concentrations ranging from 0.125 to 250 kBq ml(-1). A significant regrowth delay was observed at 125 and 250 kBq ml(-1) in both hyperthermia-treated and untreated spheroids. For groups receiving hyperthermia, no increase in cytotoxicity was seen compared with normothermic controls at any activity concentration. These results and those from autoradiographs indicate that hyperthermia at 42 degrees C for 1 h had no significant effect on the uptake or distribution of this antitenascin MAb in D-247 MG spheroids.

The cytotoxicity and microdosimetry of astatine-211-labeled chimeric monoclonal antibodies in human glioma and melanoma cells in vitro

The cytotoxicity of alpha-particle-emitting endoradiotherapeutic compounds is of increasing interest because clinical evaluation of these potential therapeutic agents is commencing. Astatine-211 is a radionuclide with a 7.2-h half-life that emits 5.87 and 7.45 MeV alpha particles. In the present work, we have investigated the in vitro cytotoxicity of 211At-labeled chimeric monoclonal antibodies (mAbs) in monolayers of D-247 MG human glioma cells and SK-MEL-28 human melanoma cells. The mAbs studied were 81C6, reactive with the extracellular matrix antigen tenascin, Mel-14, directed against the cell membrane antigen proteoglycan chondroitin sulfate, and a nonspecific control mAb, TPS3.2. Cell uptake increased as a function of activity concentration after a 1-h exposure to the 211At-labeled mAbs. The retention of activity was also measured to calculate cumulative activity associated with the cells and the medium. The clonogenic survival as a function of activity concentration was linear in all cases with no detectable shoulder. Microdosimetric analyses were performed based on measured cell geometry, cumulative activity and Monte Carlo transport of alpha particles. Using 18 kBq/ml activity concentration and 1 h of incubation, a two to five times higher activity bound to the microcolonies was found for the specific mAbs compared to the nonspecific mAb. These calculations indicated that a survival fraction of 0.37 was achieved with 0.24-0.28 Gy for D-247 MG cells and 0.27-0.29 Gy for SK-MEL-28 cells. The microdosimetric cell sensitivity, z0, for D-247 MG cells was significantly lower than for SK-MEL-28 cells (0.08 compared to 0.15 Gy). For both cell lines, reduction in survival to 0.37 required an average of only 1-2 alpha-particle hits to the cell nucleus.

Serological assays for the identification of Oesophagostomum dentatum infections in pigs

Oesophagostomum dentatum antigen preparations of third (L3) or fourth (L4) stage larvae were characterised by Western blotting. Panels of sera obtained from pigs infected with O dentatum and Ascaris suum, respectively, reacted with the same bands of L3 antigen. In contrast high specificity against a characteristic band, was observed when L4 extract was employed as antigen. To establish an enzyme-linked immunosorbent assay (ELISA), a panel of homologous and heterologous sera was tested against O dentatum L4 extract. The best combined specificity and sensitivity was obtained when horseradish peroxidase (HRP) goat anti swine IgG conjugate was used rather than HRP rabbit anti swine Ig conjugate. Testing series of sera from pigs infected with single doses of either 2000, 20,000 or 200,000 infective larvae by the ELISA, a significant dose dependency in the antibody response was observed between the low and high dosage groups. This assay may be useful in future studies of the immune-mechanisms against nodular worm infections in pigs.