Abstract

The preferable pharmacokinetics of rhenium-186 (186Re)-monoaminemonoamidedithiol-conjugated or 186Re-mercaptoacetyltriglycine-conjugated bisphosphonates (BPs) suggested that the molecular design would be applicable to other radionuclides such as 68Ga, 99mTc, 153Sm and 177Lu. In this study, a key factor affecting the pharmacokinetics of a chelate-conjugated BP was investigated to estimate the validity and the applicability of molecular design. Chemically inert and well-characterized tricarbonyl[186Re][(cyclopentadienylcarbonyl amino)-acetic acid]rhenium ([186Re]CpTR-Gly) was conjugated with 3-amino-1-hydroxypropylidene-1,1-bisphosphonate and purified by high-performance liquid chromatography (HPLC) to prepare [186Re](1-{3-[tricarbonyl(cyclopentadienylcarbonyl amino)-acetylamido]-1-hydroxy-1-phosphono-propyl}-phosphonic acid)rhenium ([186Re]CpTR-Gly-APD). Plasma stability, plasma protein binding, hydroxyapatite (HA) binding and the pharmacokinetics of [186Re]CpTR-Gly-APD were compared with those of 186Re 1-hydroxyethylidene-1,1-diphosphonate (HEDP). The effect of HEDP coadministration and preadministration on the pharmacokinetics of [186Re]CpTR-Gly-APD was also determined. The HPLC-purified [186Re]CpTR-Gly-APD showed higher plasma stability, higher HA binding, higher bone accumulation and lower plasma protein binding than did 186Re-HEDP. However, HA binding of [186Re]CpTR-Gly-APD decreased to levels slightly higher than that of 186Re-HEDP at similar HEDP concentrations. Bone accumulation of [186Re]CpTR-Gly-APD also decreased to levels similar to that of 186Re-HEDP when [186Re]CpTR-Gly-APD was coinjected with HEDP equivalent to that in 186Re-HEDP. In contrast, HEDP pretreatment did not impair bone accumulation of the two 186Re-labeled compounds. However, a delay in blood clearance and an increase in renal radioactivity levels were observed particularly with 186Re-HEDP. Although 186Re-HEDP possessed HA binding and bone accumulation similar to those of [186Re]CpTR-Gly-APD, the specific activity of 186Re-labeled BPs was found to play a crucial role in bone accumulation and blood clearance. Thus, the molecular design of chelate-conjugated BP would be useful for the development of bone-seeking radiopharmaceuticals with a variety of radionuclides by selecting chelating molecules that provide high specific activities.

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