Purpose: Irradiation of the arterial wall with beta particles has been shown to be effective in inhibiting neointimal hyperplasia following percutaneous transluminal coronary angioplasty (PTCA). In this study, we describe the use of 188W/188Re generators to obtain 188Re (half-life 16.9 h, maximal beta energy of 2.12 MeV) as a new candidate radioisotope for endovascular irradiation. We have evaluated two [188Re]-compounds as candidates for use as solution-based radiation sources that would allow conventional liquid-filled balloon inflation for delivery of radiation to the vessel wall. While balloon rupture at nominal inflation pressures is a very rare event, (<1 per 10,000 at high pressure), radioisotope release could potentially result in significant dose to radiation-sensitive organs. We have thus evaluated the biodistribution, dosimetry, and kinetics of excretion in rats of two 188Re-labeled compounds that are proposed for intravascular therapy.
Materials and methods: Rhenium-188 was obtained as [188Re]-sodium perrhenate by saline elution of an alumina-based 188W/188Re generator system (>500 mCi). High specific volume solutions of the [188Re]-sodium perrhenate (>50 mCi/ml) were obtained by post-elution concentration of the generator bolus by passage through a tandem silver cation/anion column system. Rhenium-188-labeled benzoylthioacetyltriglycine (MAG3) was prepared by stannous ion reduction of [188Re]-perrhenate in the presence of the benzyl-MAG3 substrate, and was characterized as a single radioactive component. Rhenium-188-perrhenate and [188Re]-MAG3 were administered to separate groups of Fischer rats, which were sacrificed at various times and the tissue distribution of 88Re determined in the major organs. Excretory products were also collected daily from separate groups of rats for each agent over 7 days. The effects of perchlorate and iodide preblocking and postdisplacement of thyroid uptake of [188Re]-perrhenate were also evaluated.
Results: Organ uptake values were modest for both agents [<0.25 % injected dose(ID)/gram of tissue at 6 h] for all organs evaluated except for the thyroid, with the intestines and intestinal contents showing the highest uptake values (0.72-1.97 %ID/gram). Whereas thyroid uptake of 188Re after injection of [188Re]-MAG3 was low (0.16 %ID/gram), uptake after injection of [188Re]-perrhenate was higher and could be blocked by pretreatment with perchlorate (intravenous [IV]) or displaced by perchlorate posttreatment. Also, oral or IV iodide pre- or postadministration could also significantly block or displace thyroid uptake of [188Re]-perrhenate. Both [188Re] agents were excreted primarily via the urinary bladder. The excretion half-life of [188Re]-perrhenate was about 7 h; in contrast, the [188Re]-MAG3 complex showed 50% excretion in less than 2 h. The large intestines received the most significant adsorbed dose, with values of 2.0 cGy/ mCi for [188Re]-perrhenate and 4.6 x 10(-3) cGy/mCi for [188Re]-MAG3.
Conclusions: Rhenium-188-MAG3 shows more rapid urinary bladder excretion in rats than perrhenate and both agents show low organ uptake. Thyroid uptake of free [188Re]-perrhenate can be blocked or displaced with oral perchlorate administration. For the projected use of [188Re]-MAG3 for balloon inflation required for irradiation of the arterial wall, calculated organ dose values are within acceptable limits in the unlikely event of low pressure balloon rupture. Rhenium-188-MAG3 in solution is thus a new candidate for balloon dilation providing uniform endovascular irradiation following PTCA for restenosis therapy.