Preparation of 177Lu-labeled oxine in lipiodol as a possible agent for therapy of hepatocellular carcinoma: a preliminary animal study.

Hepatocellular carcinoma (HCC) is one of the most prevalent forms of cancer with high morbidity. (131)I-lipiodol is used clinically and has been found to be effective for the treatment of HCC. However, this preparation has its limitations, including compromised yield and stability of exchange labeling and unnecessary dose burden from gamma emissions. In the present study, (177)Lu-oxine in lipiodol was considered as a possible alternative for radioiodinated lipiodol. Oxine or 8-hydroxyquinoline was labeled with (177)Lu obtained by neutron irradiation of natural lutetium. Under optimized conditions, the radiolabeled complex was obtained with yields >98% and adequate in vitro stability. (177)Lu-oxine dispersed in lipiodol showed appreciable uptake into rat liver cells (normal and HCC-induced) in vitro. (177)Lu-oxine-lipiodol showed initial localization in the liver, but subsequent leakage of radioactivity with deposition in the skeletal tissue was seen. The studies suggest that (177)Lu-oxine dispersed in lipiodol might not be suitable for treatment of HCC.

Block-copolymer-stabilized iodinated emulsions for use as CT contrast agents.

The objective of this study was to develop radiopaque iodinated emulsions for use as CT blood pool contrast agents. Three hydrophobic iodinated oils were synthesized based on the 2,3,5-triiodobenzoate moiety and formulated into emulsions using either phospholipids or amphiphilic polymers, i.e. Pluronic F68 and poly(butadiene)-b-poly(ethylene glycol) (PBD-PEO), as emulsifiers. The size, stability and cell viability was investigated for all stabilized emulsions. Three emulsions stabilized with either lipids or PBD-PEO were subsequently tested in vivo as a CT blood pool contrast agent in mice. While the lipid-stabilized emulsions turned out unstable in vivo, polymer-stabilized emulsions performed well in vivo. In blood, a contrast enhancement of 220 Hounsfield Units (HU) was measured directly after intravenous administration of 520 mg I/kg. The blood circulation half-life of a PBD-PEO stabilized emulsion was approximately 3 h and no noticeable in vivo toxicity was observed. These results show the potential of above emulsions for use as blood pool agents in contrast enhanced CT imaging.

Biodistribution of phenylboric acid derivative entrapped lipiodol and 4-borono-2-18F-fluoro-L-phenylalanine-fructose in GP7TB liver tumor bearing rats for BNCT.

A new phenylboric acid derivative entrapped lipiodol (PBAD-lipiodol) was developed as a boron carrier for the boron neutron capture therapy (BNCT) of hepatoma in Taiwan. The biodistribution of both PBAD-lipiodol and BPA-fructose was assayed in GP7TB hepatoma-bearing rat model. The highest uptake of PBAD-lipiodol was found at 2h post injection. The application of BNCT for the hepatoma treatment in tumor-bearing rats is suggested to be 2-4h post PBAD-lipiodol injection.

Preparation of 166Ho-oxine-lipiodol and its preliminary bioevaluation for the potential application in therapy of liver cancer.

OBJECTIVE: Intra-arterial administration of beta-emitting radionuclides in the form of suitable radiopharmaceuticals is one of the promising modalities for the treatment of liver cancer. Ho [T1/2=26.9 h, Ebeta(max)=1.85 MeV, Egamma=81 keV (6.4%)] could be envisaged as an attractive radionuclide for the use in liver cancer therapy owing to its high-energy beta-emission, short half-life and feasibility of its production with adequately high specific activity and radionuclidic purity using moderate flux reactors. Lipiodol is chosen as the vehicle to deliver localized doses of ionizing radiation to liver cancer cells after intra-arterial hepatic infusion as it is selectively retained in the vascular periphery of the proliferating cells. METHODS: Ho was produced by thermal neutron bombardment on a natural Ho2O3 target at a flux of approximately 6 x 10 n/cm.s for 7 days. Radiolabelled lipiodol was prepared by dispersing the Ho-oxine complex in lipiodol. The biological behaviour of Ho-oxine-lipiodol was studied by biodistribution and imaging studies in normal Wistar rats. RESULTS: Ho was produced with a specific activity of 9.25-11.10 TBq/g and radionuclidic purity of approximately 100%. The Ho-labelled oxine complex was prepared in high yield (approximately 97%). Approximately, 95% of the Ho activity was dispersed in lipiodol within 30 min. The resulting radiolabelled preparation was found to exhibit good stability in physiological saline and human serum up to 3 days. The biodistribution and imaging studies revealed satisfactory hepatic retention (88.43+/-2.85% of injected activity after 2 days) with insignificant uptake in any other major organ/tissue except skeleton (6.44+/-1.07% at 2 days postinjection). CONCLUSION: The Ho-oxine-lipiodol preparation exhibited promising features in preliminary studies and warrants further investigation.

Development of acetylated HDD kit for preparation of 188Re-HDD/lipiodol.

A lipiodol solution of (188)Re-4-hexadecyl-2,2,9,9-tetramethyl-4,7-diaza-1,10-decanedithiol ((188)Re-HDD/lipiodol) is in clinical study for liver cancer therapy. However, formulation of it is difficult due to highly active and unstable sulfhydryl groups. We produced new kits using diacetylated HDD (AHDD), in which sulfhydryl groups are protected. We found that AHDD kit can replace HDD kit due to an increased stability for formulation, the better radiolabeling efficiency (78%) and the equivalent biodistribution pattern in mice.

Preparation and biodistribution of rhenium-188 ECD/Lipiodol in rats following hepatic arterial injection.

Radiolabeled Lipiodol has routinely been used in hepatoma therapy. In this article an attempt to develop a new (188)Re-ECD/Lipiodol radiopharmaceutical, in which the chelating agent ECD (ethyl cyteinate dimer), is the constituent of the known brain perfusion agent (99m)Tc-ECD, and an evaluation of its stability and biodistribution in rats with hepatic tumors is presented. First, (188)Re-ECD was prepared in a vial, followed by extraction with Lipiodol to get the final product, (188)Re-ECD/Lipiodol. The optimal labeling conditions for (188)Re-ECD were: (1) tartaric acid which is better than EDTA as a weak chelating agent; and (2) 15 mg of SnCl(2), as the reducing agent, and 5-10 mg of tartaric acid in each vial had a better labeling yield. The radiochemical purity of (188)Re-ECD/Lipiodol was more than 94%. Twenty-four male Sprague-Dawley rats with liver tumors were sacrificed at 1, 24, and 48 h (eight rats each time) after an injection of approximately 7.4 MBq of (188)Re-ECD/Lipiodol via the hepatic artery. The radioactivity in the liver tumor is significantly high following therapeutic arterial injection, and relatively low in other organs including the bone, spleen, brain, thyroid, stomach, muscle, blood, and testis throughout this study. In conclusion, the new preparation of (188)Re-ECD/Lipiodol is a candidate agent for the treatment of liver cancer.

Synthesis and in vitro evaluation of the phenylboric acid derivative entrapped lipiodol in boron neutron capture therapy for hepatoma.

BACKGROUND: Hepatoma, a common cancer in Taiwan, responds poorly to conventional therapies. Boron neutron capture therapy (BNCT) may provide a promising approach for hepatoma therapy. In this study, a pharmaceutical composition, phenylboric acid derivative entrapped lipiodol (PBAD-lipiodol), was synthesized and characterized. In vitro study was used for evaluation of PBAD-lipiodol for the BNCT of hepatoma. MATERIALS AND METHODS: alpha Track observation was used to identify the boron compound in the TLC plate and to evidence the uniform distribution of boron in the PBAD-lipiodol. Inductively coupled plasma-atomic emission spectroscopy and neutron activation analysis were used to determine the concentrations of boron and lipiodol, respectively. Human hepatoma HepG2 cells were used for in vitro experiments. A Nomarski optical microscope was used to investigate the uptake of PBAD-lipiodol globules in individual hepatoma cells. RESULTS: PBAD-lipiodol was stable in human serum. The boron source, PBAD, was uniformly distributed in PBAD-lipiodol. Many of the PBAD-lipiodol globules were internalized and retained in HepG2 cells, and the boron concentration of HepG2 cells reached 269 ppm after 72 hours of PBAD-lipiodol treatment. CONCLUSION: In vitro studies revealed that PBAD-lipiodol could deliver a therapeutically effective amount of PBAD as a boron source for the BNCT of hepatoma. PBAD-lipiodol is a potential new boron drug for the BNCT of hepatoma.