Synthesis and evaluation of novel radioiodinated benzamides for malignant melanoma.

The imaging potential of a series of [123I]benzamides was studied in mice bearing B16F0 melanoma tumors. Compound [123I]25 exhibited tumor uptake >8 %ID/g at 1 h, while that of [123I]14d and [123I]25 reached a maximum of 9-12 %ID/g at 6 h. Standardized uptake values of [123I]14d were higher than 100 between 24 and 72 h after injection. In haloperidol treated animals, the tumor uptake of [123I]14d was not significantly different to controls, while significant reduction of [123I]25 uptake was observed, supporting that [123I]14d uptake relates to melanin interaction, whereas part of the mechanism of [123I]25 uptake is related to its sigma 1-receptor affinity. Benzamides 14d and 25, which display rapid and high tumor uptake, appear to be promising imaging agents for melanoma detection, while 14d, which displays a long lasting and high melanoma/nontarget ratio, is more suitable for evaluation as a potential radiotherapeutic.

Preparation and biologic evaluation of a novel radioiodinated benzylpiperazine, 123I-MEL037, for malignant melanoma.

UNLABELLED: Radiopharmaceuticals that can target the random metastatic dissemination of melanoma tumors may present opportunities for imaging and staging the disease as well as potential radiotherapeutic applications. A novel molecule, 2-(2-(4-(4-(123)I-iodobenzyl)piperazin-1-yl)-2-oxoethyl)isoindoline-1,3-dione (MEL037), was synthesized, labeled with 123I, and evaluated for application in melanoma tumor scintigraphy and radiotherapy. METHODS: The tumor imaging potential of 123I-MEL037 was studied in vivo in C57BL/6J female mice bearing the B16F0 murine melanoma tumor and in BALB/c nude mice bearing the A375 human amelanotic melanoma tumor by biodistribution, competition studies, and SPECT. RESULTS: 123I-MEL037 exhibited high and rapid uptake in the B16F0 melanoma tumor at 1 h (13 %ID/g [percentage injected dose per gram]), increasing with time to reach 25 %ID/g at 6 h. A significant uptake was also observed in the eyes (2 %ID, at 3-6 h after injection) of black mice. No uptake was observed in the tumor or in the eyes of nude mice bearing the A375 tumor. Because of high uptake and long retention in the tumor and rapid body clearance, the mean contrast ratios (MCR) of 123I-MEL037 were 30 and 60, at 24 and 48 h after injection, respectively. At 24 h after injection of mice bearing the B16 melanoma, SPECT indicated that the radioactivity was located predominately in the tumor followed by the eyes, whereas no specific localization of the radioactivity was noted in mice bearing the A375 human amelanotic tumor. In competition experiments, uptake of 123I-MEL037 in brain, lung, heart, and kidney--organs known to contain sigma-receptors--was not significantly different in haloperidol-treated animals compared with control animals. Therefore, reduction of uptake in tumor and eyes of the pigmented mice bearing the B16F0 tumor suggested that the mechanism of tumor uptake was likely due to an interaction with melanin. CONCLUSION: These findings suggested that 123I-MEL037, which displays a rapid and very high tumor uptake, appeared to be a promising imaging agent for detection of most melanoma tumors with the potential for development as a therapeutic agent in melanoma tumor proliferation.

Synthesis and biological evaluation of a series of flavone derivatives as potential radioligands for imaging the multidrug resistance-associated protein 1 (ABCC1/MRP1).

Multidrug resistance (MDR) is one of the major problems affecting the treatment of cancer. In vivo visualization and quantification of MDR proteins would be of great value to better select the therapeutic strategy. Six flavone-based compounds were synthesized and evaluated for their cytotoxic activity and MDR-reversing capacity using hMRP1 or hMDR1 overexpressing cell lines for in vitro assays. All the flavone derivatives were highly selective for hMRP1-expressing cell lines. These derivatives each used at 4muM (a non-cytotoxic concentration) enhance significantly the sensitivity of hMRP1-mediated MDR cell line toward doxorubicin toxicity. Their MDR-reversing capacity suggests that, in particular, the 4'-fluoroalkyloxy and 4'-iodo apigenin derivatives are potential new radiopharmaceuticals to visualize in vivo MRP1-mediated MDR phenomenon by PET or SPECT.

Pharmacological evaluation of (S)-8-[123I]iodobretazenil: a radioligand for in vivo studies of central benzodiazepine receptors.

In vitro studies on cortical membranes indicated (S)-8-[(123)I]iodobretazenil bound saturably to a single population of binding sites (B(max) = 2.33 pmol/mg protein) with a dissociation constant K(d) = 1.9 nM. (R)-8-[(123)I]Iodobretazenil displayed only non-specific binding. In vivo biodistribution of (S)-8-[(123)I]iodobretazenil in rats indicated high accumulation in regions of high BZR density. Radioactivity was blocked by preadministration with iodobretazenil and flumazenil, while non-BZR drugs had no effect on the uptake of activity in any brain region. (S)-8-[(123)I]Iodobretazenil uptake was saturable in a dose dependent manner (ID(50) = 0.13 mg/kg) in all brain regions. With the (R)-enantiomer no specific uptake was observed. Metabolite studies at 1-3 h p.i. indicated that greater than 95% of activity extracted from brain tissue corresponded to unchanged radiotracer while that in plasma was over 70%. (S)-8-[(123)I]Iodobretazenil potently and selectively labels BZR in vivo and deserves further investigation as a possible SPECT radiotracer.