Distribution of intraperitoneally injected microspheres labeled with the alpha-emitter astatine (211At) compared with phosphorus (32P) and yttrium (90Y) colloids in mice.

The alpha-emitter 211At was bound to polymer microspheres with a diameter of 1.8 microns. The distributions in mice of intraperitoneally injected 211At microspheres, 90Y silicate colloid, and 32P chromic phosphate colloid were compared. The microspheres with 211At spread rapidly in the peritoneal cavity and remained mainly on the intraperitoneal surfaces. Intraperitoneal injection of 90Y colloid resulted in high levels in intraperitoneal fat and the diaphragm, but 1 day after injection 8.5% of the injected dose per gram was found in blood and after 6 days 2.5% was observed in bone. The highest accumulation of 32P was found in liver and spleen. The injection of additional nonradioactive chromic phosphate colloid resulted in an even higher accumulation of 32P in spleen and liver. The same phenomenon was not observed with 211At microspheres. It is suggested that it is not only the particle size which is important in the distribution of intraperitoneally injected colloid, but the amount of colloid, the type of colloid, the addition or presence of other substances such as ascites, and the animal species might also influence the distribution. In conclusion, the intraperitoneal distribution of 211At-labeled microspheres in mice was favorable compared with 90Y and 32P colloid. These data must be viewed cautiously since the distribution might be different in other animal species or humans.

Therapeutic efficacy of the alpha-emitter 211At bound on microspheres compared with 90Y and 32P colloids in a murine intraperitoneal tumor model.

alpha-Emitting radionuclides such as 211At have a number of physical characteristics which make them attractive for the treatment of micrometastases. 211At was bound to polymer microspheres and its efficacy was compared with the beta-emitting 32P and 90Y colloids for the treatment of intraperitoneally growing K13 hybridoma tumors in mice. Single graded doses of 0.1-2.5 MBq 211At microspheres injected intraperitoneally 24 hr after inoculation of the hybridoma cells improved survival and produced higher cure rates than 32P colloid, 90Y colloid, or no treatment. One of the most striking contrasts between 211At microspheres and 90Y or 32P colloids was the ability of relatively low doses 211At to affect cures. When comparing the groups with the highest survival rate for each radionuclide (0.1-1 MBq 211At, 2.5 MBq 90Y, and 2.5 MBq 32P), 211At treatment resulted in an improved survival over that with 32P therapy, but the difference was not significant between 211At and 90Y. Toxicity studies with 211At microspheres showed that dosages up to 17 MBq per mouse were not lethal. In conclusion, the present study suggests that the high-energy transfer and the short-range cytotoxicity of the alpha-emitter 211At might be of benefit for intracavitary radiotherapy.