ABSTRACT
Positron emission tomography (PET) imaging with the glucose analog 2-deoxy-2-[(18)F]fluoro-D-glucose ([(18)F] FDG) has demonstrated clinical utility for the monitoring of brain glucose metabolism alteration in progressive neurodegenerative diseases. We examined dynamic [(18)F]FDG PET imaging and kinetic modeling of atlas-based regions to evaluate regional changes in the cerebral metabolic rate of glucose in the widely-used 6-hydroxydopamine (6-OHDA) rat model of Parkinson's disease. Following a bolus injection of 18.5 ± 1 MBq [(18)F]FDG and a 60-minute PET scan, image-derived input functions from the vena cava and left ventricle were used with three models, including Patlak graphical analysis, to estimate the influx constant and the metabolic rate in ten brain regions. We observed statistically significant changes in [(18)F]FDG uptake ipsilateral to the 6-OHDA injection in the basal ganglia, olfactory bulb, and amygdala regions; and these changes are of biological relevance to the disease. These experiments provide further validation for the use of [(18)F]FDG PET imaging in this model for drug discovery and development.
ABSTRACT
The primary limitation of IgG antibodies for radioimmunotherapy of solid tumors is their prolonged serum half-life, leading to dose-limiting bone marrow toxicity at doses providing inadequate radiation to the tumor. A humanized C(H)2 domain-deleted variant of the anti-TAG-72 antibody CC49 (HuCC49DeltaC(H)2) has faster blood clearance, compared to the IgG, while retaining tumor targeting. We compared the pharmacokinetics and tumor uptake of (111)In-HuCC49DeltaC(H)2 in BALB/c mice and a colon carcinoma (LS-174T) mouse xenograft with that of (111)In-labeled chimeric CC49 (cCC49), an antibody with pharmacokinetics similar to the humanized CC49 parent. Immuno-conjugates of HuCC49DeltaC(H)2 and cCC49 prepared with the (111)In chelator Mx-DTPA (1-isothiocyantobenzyl-3-methyldiethylenetriaminepentaacetic acid) retained low nM affinity and radiolabeling protocols provided greater than 95% radio-incorporation with (111)In while retaining greater than 80% immunoreactivity. Blood clearance of (111)In-HuCC49DeltaC(H)2 in BALB/c mice was monoexponential (t(1/2) 5.4 hours) and faster than (111)In-cCC49 (biexponential clearance; t1/2Delta 1.5 hours; t1/2beta 162 hours). The (111)In-HuCC49DeltaC(H)2 also cleared more rapidly from the blood in the murine xenograft. At 1 hour postinjection, blood concentrations for (111)In-HuCC49DeltaC(H)2 and (111)In-cCC49 were comparable (25.5 injected dose per g [%ID/g] and 21.3 %ID/g, respectively); tumor uptake for (111)In- HuCC49DeltaC(H)2 was 7.9 %ID/g, compared to 7.5 %ID/g for (111)In-cCC49. However, at 24 hours, blood concentration for (111)In-HuCC49DeltaC(H)2 was less than (111)In-cCC49 (0.9 %ID/g versus 5.2 %ID/g, respectively) with comparable tumor retention (14.4 %ID/g versus 19.0 %ID/g, respectively). Faster blood clearance of (111)In-HuCC49DeltaC(H)2 and tumor localization comparable to that of (111)In-cCC49 provided a fourfold improved tumor-to-blood ratio for (111)In-HuCC49DeltaC(H)2 at 24 hours postinjection.
