Paul E. Borchardt

Treatment of Neuroblastoma Meningeal Carcinomatosis with Intrathecal Application of α-Emitting Atomic Nanogenerators Targeting Disialo-Ganglioside GD2

Labeling of specific antibodies with bifunctional chelated Actinium-225 (225Ac; an α generator) allows the formation of new, highly potent and selective α-emitting anticancer drugs. We synthesized and evaluated a radioimmunoconjugate based on 3F8, an IgG3 antibody that specifically binds to ganglioside GD2, which is overexpressed by many neuroectodermal tumors including neuroblastoma. The 225Ac-1,4,7,10-tetra-azacylododecane (DOTA)-3F8 construct was evaluated for radiochemical purity and sterility, immunoreactivity, cytotoxicity in vitro, induction of apoptosis on GD2-positive cells, as well as for pharmacological biodistribution and metabolism of the 225Ac generator and its daughters in a nude mouse xenograft model of neuroblastoma. The 225Ac-3F8 showed an IC50 of 3 Bq/ml (80 pCi/ml) on the neuroblastoma cell line, NMB7, in vitro. Apoptosis of these cells was not observed. Biodistribution in mice showed specific targeting of a subcutaneous tumor; there was redistribution of the 225Ac daughter nuclides mainly from blood to kidneys and to small intestine. Toxicity was examined in cynomolgus monkeys. Monkeys injected with 1 to 3 doses of intrathecal 225Ac-3F8 radioimmunoconjugate (80 to 150 kBq/kg total dose) did not show signs of toxicity based on blood chemistry, complete blood counts, or by clinical evaluations. Therapeutic efficacy of intrathecal 225Ac-3F8 was studied in a nude rat xenograft model of meningeal carcinomatosis. The 225Ac-3F8 treatment improved survival 2-fold from 16 to 34 days (P = 0.01). In conclusion, in vivo α generators targeted by 3F8 warrant additional study as a possible new approach to the treatment of carcinomatous meningitis.

Tumour Therapy with Radiolabelled Antibodies

The promise of radiolabelled immunoglobulin therapy (RIT) for selective, patient friendly, cancer treatment has not yet been fulfilled. Only patients with haematological malignancies show sizable response rates after RIT. With solid tumours, intravenous administration of radiolabelled antibodies does not provide sufficient tumour targeting. However, intracompartmental administration may solve this problem, particularly if tumour reactive IgM is used.Clinical progress in RIT depends on understanding the important RIT variables: antigen, antibody, radioisotope, conjugation chemistry, activity escalation, fractionation and protein dose. These are reviewed and a new translational decision tree/flow diagram is presented that can limit analysis to the most important RIT variables for a particular disease. These variables may differ depending on the type and stage of cancer, but the guiding principles in RIT development remain the same: selectivity and accountability. The proper application of these principles leads to the definition of a new series of phase I, II, III studies. These studies are more appropriate for the clinical exploration of RIT and place an emphasis on therapeutic ratio rather than toxicity.

Intralesional radiolabeled human monoclonal IgM in human tumor xenografts

BACKGROUND AND PURPOSE Intralesional (i.l.) administration of radiolabeled human monoclonal IgM could provide a new method for increasing the radiation dose delivered to a tumor without exceeding normal tissue tolerance. MATERIALS AND METHODS Nude mice with subcutaneous human head and neck squamous cell carcinoma nodules were injected either intralesionally or intravenously with a tumor-reactive human monoclonal IgM (CR4E8) labeled with indium-111 (111In) or yttrium-90 (90Y). Groups of mice were sacrificed at different time points and their tumors and major organs were excised and counted for radioactivity. Additional mice that were treated with i.l. 90Y-labeled CR4E8 were sacrificed at the same time points for tumor autoradiography. Serial whole-body gamma camera images were obtained from additional mice treated with i.l. 111In-labeled CR4E8. Intralesionally administered 111In-labeled irrelevant IgM (CH-1B9) and 90Y-aggregate served as specificity controls. RESULTS Intralesional administration of radiolabeled IgM resulted in prolonged high tumor radioactivity with little normal tissue uptake, with kidney and liver having the highest values. The biodistribution of i.l. CR4E8 was similar whether labeled with 111In or 90Y. Tumor uptake of i.l. irrelevant IgM appeared to be lower and tumor retention appeared to be shorter. Intravenous administration of tumor-reactive IgM resulted in very low tumor radioactivity with high liver and moderate spleen uptake. The i.l. administration of 90Y-aggregate produced prolonged high tumor radioactivity with little normal tissue uptake, with bone having the highest value. Tumor autoradiographs demonstrated that the radiolabeled IgM diffused through the tumor over time while the 90Y-aggregate remained localized at the injection site. Gamma camera scintigraphy corroborated the results of the biodistribution studies. CONCLUSIONS Intralesional but not intravenous administration of 111In- or 90Y-labeled human IgM results in high tumor radioactivity with low normal tissue exposure. Myelotoxicity is not anticipated to be the dose-limiting normal tissue toxicity of this treatment. Further development of human IgM for the i.l. treatment of human malignancies appears to be warranted.

Intralesional Radioimmunotherapy with Yttrium-90-Labeled Human Monoclonal IgM in Nude Mice Bearing Human Tumor Xenografts

UNLABELLED Biodistribution studies demonstrate that intralesional administration of radiolabeled IgM results in high retention of radioactivity with little normal tissue uptake. This study examines the therapeutic potential of this modality. MATERIALS AND METHODS Nude mice bearing subcutaneous human head and neck squamous cell carcinoma xenografts were treated with single intralesional (IL) injections of tumor-reactive human monoclonal IgM (CR4E8) labeled with 25-394 microCi of yttrium-90 (90Y). Untreated mice, mice treated with IL unlabeled immunoconjugate or IL 90Y-aggregate, 160-400 microCi, served as controls. Mice were monitored for tumor growth and toxicity. RESULTS Mice received 80 Gy per 100 microCi of 90Y-labeled IgM and 110 Gy per 100 microCi of 90Y-aggregate. All tumors treated with 90Y-labeled IgM responded. In mice that received > or = 100 microCi, tumors macroscopically disappeared within three weeks from treatment with seventy-six percent tumor-free at 216 days. Acute toxicities associated with high activity 90Y-labeled IgM and 90Y-aggregate were moist skin desquamation and reduced blood counts. Late radiation damage to connective tissue was observed in mice treated with > 100 microCi of 90Y-labeled IgM. CONCLUSIONS Intralesional administration of 90Y-labeled IgM can ablate tumors in nude mice with modest acute or late toxicity. Further development of this modality for loco-regional therapy is warranted.