Evaluation of Ga-DOTA-(D-Asp)n as bone imaging agents: D-aspartic acid peptides as carriers to bone.

67Ga-DOTA-(L-Asp)11 and 67Ga-DOTA-(L-Asp)14, which have been developed as bone imaging agents, showed a high accumulation in bone and a rapid blood clearance in mice. However, peptides composed of D-amino acids are more stable in vivo than those composed of their L-equivalents. In this study, 67Ga-DOTA-(D-Asp)n (n = 2, 5, 8, 11, or 14) were synthesized using the Fmoc-based solid-phase methodology and evaluated. In hydroxyapatite binding assay, binding of 67Ga-DOTA-(D-Asp)n tended to increase with increasing length of the amino acid chain. 67Ga-DOTA-(D-Asp)11 and 67Ga-DOTA-(D-Asp)14 caused a high accumulation of radioactivity in the bones of the mice. However, the results for 67Ga-DOTA-(D-Asp)n and 67Ga-DOTA-(L-Asp)n were comparable. In urine analyses, the proportion of intact complex after injection of 67Ga-DOTA-(D-Asp)14 was significantly higher than that of 67Ga-DOTA-(L-Asp)14. Although 67Ga-DOTA-(D-Asp)14 was more stable than 67Ga-DOTA-(L-Asp)14, the properties of 67Ga-DOTA-(D-Asp)n and 67Ga-DOTA-(L-Asp)n as bone imaging agents may be comparable.

Development of novel radiogallium-labeled bone imaging agents using oligo-aspartic acid peptides as carriers.

(68)Ga (T 1/2 = 68 min, a generator-produced nuclide) has great potential as a radionuclide for clinical positron emission tomography (PET). Because poly-glutamic and poly-aspartic acids have high affinity for hydroxyapatite, to develop new bone targeting (68)Ga-labeled bone imaging agents for PET, we used 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA) as a chelating site and conjugated aspartic acid peptides of varying lengths. Subsequently, we compared Ga complexes, Ga-DOTA-(Asp)n (n = 2, 5, 8, 11, or 14) with easy-to-handle (67)Ga, with the previously described (67)Ga-DOTA complex conjugated bisphosphonate, (67)Ga-DOTA-Bn-SCN-HBP. After synthesizing DOTA-(Asp)n by a Fmoc-based solid-phase method, complexes were formed with (67)Ga, resulting in (67)Ga-DOTA-(Asp)n with a radiochemical purity of over 95% after HPLC purification. In hydroxyapatite binding assays, the binding rate of (67)Ga-DOTA-(Asp)n increased with the increase in the length of the conjugated aspartate peptide. Moreover, in biodistribution experiments, (67)Ga-DOTA-(Asp)8, (67)Ga-DOTA-(Asp)11, and (67)Ga-DOTA-(Asp)14 showed high accumulation in bone (10.5 ± 1.5, 15.1 ± 2.6, and 12.8 ± 1.7% ID/g, respectively) but were barely observed in other tissues at 60 min after injection. Although bone accumulation of (67)Ga-DOTA-(Asp)n was lower than that of (67)Ga-DOTA-Bn-SCN-HBP, blood clearance of (67)Ga-DOTA-(Asp)n was more rapid. Accordingly, the bone/blood ratios of (67)Ga-DOTA-(Asp)11 and (67)Ga-DOTA-(Asp)14 were comparable with those of (67)Ga-DOTA-Bn-SCN-HBP. In conclusion, these data provide useful insights into the drug design of (68)Ga-PET tracers for the diagnosis of bone disorders, such as bone metastases.

Preparation and evaluation of a radiogallium complex-conjugated bisphosphonate as a bone scintigraphy agent.

INTRODUCTION: (68)Ga is a radionuclide of great interest as a positron emitter for positron emission tomography (PET). To develop a new bone-imaging agent with radiogallium, 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA) was chosen as a chelating site and Ga-DOTA complex-conjugated bisphosphonate, which has a high affinity for bone, was prepared and evaluated. Although we are interested in developing (68)Ga-labeled bone imaging agents for PET, in these initial studies (67)Ga was used because of its longer half-life. METHODS: DOTA-conjugated bisphosphonate (DOTA-Bn-SCN-HBP) was synthesized by conjugation of 2-(4-isothiocyanatebenzyl)-1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid to 4-amino-1-hydroxybutylidene-1,1-bisphosphonate (alendronate). (67)Ga-DOTA-Bn-SCN-HBP was prepared by coordination with (67)Ga, and its in vitro and in vivo evaluations were performed. RESULTS: (67)Ga-DOTA-Bn-SCN-HBP was prepared with a radiochemical purity of over 95% without purification. (67)Ga-DOTA-Bn-SCN-HBP had great affinity for hydroxyapatite in binding assay. In biodistribution experiments, (67)Ga-DOTA-Bn-SCN-HBP accumulated in bone rapidly but was hardly observed in tissues other than bone. Pretreatment of an excess amount of alendronate inhibited the bone accumulation of (67)Ga-DOTA-Bn-SCN-HBP. CONCLUSIONS: (67)Ga-DOTA-Bn-SCN-HBP showed ideal biodistribution characteristics as a bone-imaging agent. These findings should provide useful information on the drug design of bone imaging agents for PET with (68)Ga.