PURPOSE: ReO(4)(-) has similar kinetics regarding the sodium iodide symporter (NIS) to I(-) and TcO(4)(-) in NIS-expressing tissue. We investigated the therapeutic potential of (186)ReO(4)(-) in NIS-transfected neuroendocrine tumour tissue. METHODS: For experiments, the stably NIS-transfected pancreatic neuroendocrine cancer cell line Bon1C was used. NIS-mediated internalization and externalization experiments in vitro and a biodistribution study in nude mice bearing Bon1C xenografts were performed. A therapy study was also conducted consecutively in nude mice xenografted with Bon1C in which the mice were injected intravenously with Na(186)ReO(4). RESULTS: In vitro studies showed exponential internalization and efflux kinetics of (186)ReO(4)(-) in the cell line. The biodistribution study showed high uptake of (186)ReO(4)(-) in NIS-expressing tumours. Tumour growth inhibition was significant after injection of (186)ReO(4) in two groups of animals treated with activity levels below the determined maximum tolerable activity as compared to controls. CONCLUSION: These results indicate that the use of (186)ReO(4)(-) in the treatment of NIS-expressing neuroendocrine tumours is feasible and support the concept of using NIS as a therapeutic target for (186)ReO(4)(-).
PURPOSE: ReO(4)(-) has similar kinetics regarding the sodium iodide symporter (NIS) to I(-) and TcO(4)(-) in NIS-expressing tissue. We investigated the therapeutic potential of (186)ReO(4)(-) in NIS-transfected neuroendocrine tumour tissue. METHODS: For experiments, the stably NIS-transfected pancreatic neuroendocrine cancer cell line Bon1C was used. NIS-mediated internalization and externalization experiments in vitro and a biodistribution study in nude mice bearing Bon1C xenografts were performed. A therapy study was also conducted consecutively in nude mice xenografted with Bon1C in which the mice were injected intravenously with Na(186)ReO(4). RESULTS: In vitro studies showed exponential internalization and efflux kinetics of (186)ReO(4)(-) in the cell line. The biodistribution study showed high uptake of (186)ReO(4)(-) in NIS-expressing tumours. Tumour growth inhibition was significant after injection of (186)ReO(4) in two groups of animals treated with activity levels below the determined maximum tolerable activity as compared to controls. CONCLUSION: These results indicate that the use of (186)ReO(4)(-) in the treatment of NIS-expressing neuroendocrine tumours is feasible and support the concept of using NIS as a therapeutic target for (186)ReO(4)(-).
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