To prepare long-circulating liposomes, poly(ethylene glycol) (PEG)-lipid is usually mixed with other lipid components before vesicle formation. PEG-lipids can also be postinserted in the outer layer of liposomes after the preparation. In this study, PEG-distearoylphosphatidylethanolamine was incorporated by postinsertion technique into liposome-encapsulated hemoglobin (LEH) carrying neutral or negative charge. Postinsertion technique improved the encapsulation efficiency of hemoglobin from about 0.0017 to 0.017 (hemoglobin/phospholipid, molar ratio) for a similar lipid composition. Thus, neutral, anionic, PEG-neutral, and PEG-anionic LEHs were made and labeled with technetium-99m to follow their biodistribution. A small dose of LEH (ϳ15 mg of phospholipid) was injected intravenously in rabbits, and its distribution was monitored by blood sampling, gamma camera imaging, and tissue radioactivity counting on necropsy. The 24-h blood levels of neutral, PEGneutral, anionic, and PEG-anionic LEHs were 14, 40.3, 13.1, and 35.7% of injected dose, respectively; calculated T 1/2 values of circulation were 8.9, 19.3, 9.6, and 16.5 h, respectively. PEGylation also influenced accumulation of LEH in the reticuloendothelial system. Liver uptake of neutral LEH dropped from 52.1 to 19.1%, whereas that of anionic LEH came down from 35.3 to 11.5% on PEGylation. In contrast, PEGylation increased the spleen uptake by 8.5-and 2.5-fold for neutral and anionic LEH, respectively. The results demonstrate that PEGylation by postinsertion not only improves the circulation t 1/2 of LEH but also enhances hemoglobin content inside the vesicles for better oxygen-carrying capacity.
The purpose of this study was to determine the feasibility of radiolabeling liposomal doxorubicin (Doxil) for cancer chemoradionuclide therapy by directly loading the therapeutic radionuclide rhenium-186 ((186)Re) into the liposome interior. The pharmacokinetics, imaging and biodistribution of [(186)Re]Doxil (555 MBq/kg) and control [(186)Re]polyethylene glycol (PEG) liposomes (555 MBq/kg) were determined after intravenous administration in a head and neck cancer xenograft model in nude rats. [(186)Re]Doxil and [(186)Re]PEG liposomes were radiolabeled using [(186)Re]N,N-bis(2-mercaptoethyl)-N',N'-diethylethylenediamine. (186)Re labeling efficiency was 76.1+/-8.3% with Doxil. The in vitro serum stability of [(186)Re]Doxil at 37 degrees C was 38.06+/-12.13% at 24 h. Pharmacokinetic studies revealed that [(186)Re]Doxil had a two-phase blood clearance with half clearance times of 0.8 and 28.2 h. Images acquired over 120 h showed that [(186)Re]Doxil had slow blood clearance, low liver accumulation and increasing spleen accumulation. The biodistribution study at 120 h indicated that the percentage of injected dose (%ID) in the blood and tumor for [(186)Re]Doxil was 20-fold higher than that of [(186)Re]PEG liposomes. The %ID values in the kidney and liver were not significantly different between [(186)Re]Doxil and [(186)Re]PEG liposomes. These results suggest that the long circulation and prolonged bioavailability of [(186)Re]Doxil could potentially deliver high concentrations of both doxorubicin and (186)Re to tumor when encapsulated in the same liposome vehicle.
Many methods of labeling liposomes with both diagnostic and therapeutic radionuclides have been developed since the initial discovery of liposomes 40 years ago. Diagnostic radiolabels can be used to track nanometer-sized liposomes in the body in a quantitative fashion. This article reviews the basic methods of single photon emission computed tomography (SPECT) and positron emission tomography (PET) imaging and labeling of liposomes with single photon and dual photon positron emission radionuclides. Examples of the use of these diagnostic imaging agents will be shown. The ability to track the uptake of liposomes in humans and research animals on a whole body basis is providing researchers with an excellent tool for developing liposome-based drug delivery agents. The attachment of therapeutic radionuclides to liposomes also has great promise in cancer therapy. Recent developments in the use of liposomes carrying therapeutic radionuclides for cancer therapy will also be reviewed. Many of the radiolabeling and tracking technologies developed for nanosized liposomes will also be useful for the imaging and tracking of other nanoparticles.
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