Preparation and preliminary evaluation of technetium-99m-labeled fragment E1 for thrombus imaging.

Fragment E1 labeled with 123I has been previously shown to permit imaging of thrombi in patients within as little as 20 min after injection. Because of the relatively rapid localization and blood disappearance of this protein, 99mTc would be the most clinically acceptable radionuclide for labeling Fragment E1. In this study, human fragment E1 was derivatized with a hydrazino nicotinate function to permit radiolabeling with reduced technetium. The modification reaction was carried out while the fragment E1 was protected in a complex, so that the modification occurred in nonfunctional regions of the fragment E1 molecule. After radiolabeling with 99mTc, the modified fragment E1 retained its functional activity, as judged by its binding to fragment DD in vitro. The ability of 99mTc-fragment E1 to produce images of venous thrombi was demonstrated in animal models. Images were focally positive within 20 min to 1 hr after injection. Thrombus-to-blood ratios exceeded those from 125I-fibrinogen in the same animals. This method of labeling appears to provide an alternative radiolabel to 123I without compromising the function of fragment E1.

Preparation of hydrazino-modified proteins and their use for the synthesis of 99mTc-protein conjugates.

The syntheses and protein linking properties of succinimidyl 4-hydrazinobenzoate hydrochloride (SHBH) and succinimidyl 6-hydrazinonicotinate hydrochloride (SHNH), two new heterobifunctional linkers which lead to hydrazino-modified proteins, are described. SHBH-modified proteins are unstable due to the presence of the phenylhydrazine moiety. This problem was overcome by synthesizing the hydrazinopyridine analogue SHNH, and the conjugates derived from this linker are stable. Tc(V) oxo precursors readily add to hydrazinopyridine-modified proteins to yield the desired 99mTc-radiolabeled protein. 99mTc-hydrazinopyridine-polyclonal IgG conjugates are useful agents for the imaging of focal sites of infection.

Technetium-99m-human polyclonal IgG radiolabeled via the hydrazino nicotinamide derivative for imaging focal sites of infection in rats.

The biologic behavior of human polyclonal immunoglobulin (IgG) radiolabeled with technetium-99m (99mTc) by a novel method, via a nicotinyl hydrazine derivative, was evaluated in rats. Technetium-99m- and indium-111-IgG were co-administered to normal rats and biodistribution was determined at 2, 6, and 16 hr. The inflammation imaging properties of the two reagents were compared in rats with deep-thigh infection due to Escherichia coli. Blood clearance of both antibody preparations was well described by a bi-exponential function: (99mTc-IgG: t1/2 = 3.82 +/- 0.89 and 57.52 +/- 1.70 hr. 111In-IgG: 3.93 +/- 0.117 and 40.71 +/- 1.26 hr). Biodistributions in the solid organs were similar, however, small but statistically significant differences were detected: 99mTc-IgG greater than 111In-IgG in lung, liver, and spleen; 99mTc-IgG less than 111In-IgG in kidney and skeletal muscle (p less than 0.01). At all three imaging times, target-to-background ratio and percent residual activity for the two compounds were remarkably similar. These studies establish that human polyclonal IgG labeled with 99mTc via a nicotinyl hydrazine modified intermediate is equivalent to 111In-IgG for imaging focal sites of infection in experimental animals.