Hydrazino nicotinate (HYNIC) has been shown to produce technetium-99m (99mTc)-labeled proteins and peptides of high stability with high specific activities. However, persistent localization of radioactivity was observed in nontarget tissues such as the liver and kidney after administration of [99mTc]HYNIC-labeled proteins and peptides, which compromises the diagnostic accuracy of the radiopharmaceuticals. Since lysosomes are the principal sites of intracellular catabolism of proteins and peptides, 99mTc-HYNIC-labeled galactosyl-neoglycoalbumin (NGA) was prepared using tricine as a co-ligand to investigate the fate of the radiolabel after lysosomal proteolysis in hepatocytes. When injected into mice, over 90% of the injected radioactivity was accumulated in the liver after 10 min injection. At 24 h postinjection, ca. 40% of the injected radioactivity still remained in liver lysosomes. Size-exclusion HPLC analyses of liver homogenates at 24 h postinjection showed a broad radioactivity peak ranging from molecular masses of 0.5-50 kDa. RP-HPLC analyses of liver homogenates suggested the presence of multiple radiolabeled species. However, most of the radioactivity migrated to lower molecular weight fractions on size-exclusion HPLC after treatment of the liver homogenates with sodium triphenylphosphine-3-monosulfonate (TPPMS). The TPPMS-treated liver homogenates showed a major peak at a retention time similar to that of [[99mTc](HYNIC-lysine)(tricine)(TPPMS)] on RP-HPLC. Similar results were obtained with urine and fecal samples. These findings suggested that the chemical bonding between 99mTc and HYNIC remains stable in the lysosomes and following excretion from the body. The persistent localization of radioactivity in the liver could be attributed to the slow elimination rate of the final radiometabolite, [[99mTc](HYNIC-lysine)(tricine)2], from lysosomes, and subsequent dissociation of one of the tricine co-ligands in the low pH environment of the lysosomes in the absence of excess co-ligands, followed by binding proteins present in the organelles. The findings in this study also suggested that the development of appropriate co-ligands capable of preserving stable bonding with the Tc center is essential to reduce the residence time of radioactivity in nontarget tissues after administration of [99mTc]HYNIC-labeled proteins and peptides.
Renal localization of radiolabeled antibody fragments constitutes a problem in targeted imaging and radiotherapy. Recently, we reported use of a novel radioiodination reagent, 3'-[131I]iodohippuryl N(epsilon)-maleoyl-L-lysine (HML), that liberates m-iodohippuric acid before antibody fragments are incorporated into renal cells. In mice, HML-conjugated Fab demonstrated low renal radioactivity levels from early postinjection times. In this study, renal metabolism of HML-conjugated Fab fragments prepared by different thiolation chemistries and by direct radioiodination were investigated to determine the mechanisms responsible for the low renal radioactivity levels. Fab fragments were thiolated by 2-iminothiolane modification or by reduction of disulfide bonds in the Fab fragments, followed by conjugation with radioiodinated HML to prepare [131I]HML-IT-Fab and [125I]HML-Fab, respectively. In biodistribution studies in mice, both [131I]HML-IT-Fab and [125I]HML-Fab demonstrated significantly lower renal radioactivity levels than those of [125I]Fab. In subcellular distribution studies, [125I]Fab showed migration of radioactivity from the membrane to the lysosomal fraction of the renal cells from 10 to 30 min postinjection. On the other hand, the majority of the radioactivity was detected only in the membrane fraction at the same time points after injection of both [131I]HML-IT-Fab and [125I]HML-Fab. In metabolic studies, while [125I]Fab remained intact at 10 min postinjection, both HML-conjugated Fab fragments generated m-iodohippuric acid as a radiometabolite at the same postinjection time. [131I]HML-IT-Fab registered two radiometabolites (intact [131I]HML-IT-Fab and m-iodohippuric acid), whereas additional radiometabolites were observed with [125I]HML-Fab. This suggested that metabolism of both HML-conjugated Fab fragments would occur in the membrane fractions of the renal cells. The findings of this study reinforced our previous hypothesis that radiochemical design of antibody fragments that liberate radiometabolites that are excreted into the urine by the action of brush border enzymes would constitute a useful strategy to reduce renal radioactivity levels from early postinjection times.
The purpose of this study was to develop an indium-111 (111In)-based residualizing label for estimating the pharmacokinetics of proteins. 1,4,7,10-Tetraazacyclododecane-N,N',N'',N'''-tetraacetic acid (DOTA), which produced a highly stable and hydrophilic 111In chelate, was selected as the chelating site, and the monoreactive DOTA derivative with a tetrafluorophenyl group as the protein binding site (mDOTA) was designed to avoid cross-linkings of proteins. mDOTA was synthesized with an overall yield of 11%. The stability in murine plasma, the radioactivity retention in the catabolic sites of proteins and the radiochemical yields of 111In-labelled proteins via mDOTA were investigated using human serum albumin (HSA), galactosyl-neoglycoalbumin (NGA) and cytochrome c (cyt c) as model proteins. 111In-labelled HSA via mDOTA was highly stable for 5 days after incubation in murine plasma. Long retention of radioactivity in the catabolic sites was observed after injection of 111In-DOTA-NGA in mice, due to the slow elimination of the radiometabolite from the lysosome. At a chelator concentration of 42.2 microM, 111In-DOTA-cyt c was produced with over 91% radiochemical yield. On the other hand, 111In-DOTA-lysine and 111In-DOTA were obtained with high radiochemical yields at lower chelator concentrations. These findings indicated that mDOTA would be an appropriate 111In-labelling agent for estimating protein pharmacokinetics. These findings also suggested that the introduction of a protein binding site at a position distal from the unmodified DOTA structure would be preferable to preparing 111In-DOTA-labelled proteins with higher specific activity.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.