99m Tc-glycopeptide: synthesis, biodistribution and imaging in breast tumor-bearing rodents.

This study was aimed to develop a glycopeptide (GP) to be used as a carrier for anti-cancer drug delivery. GP was synthesized by conjugating glutamate peptide and chitosan using carbodiimide as a coupling agent. Elemental analysis and capillary electrophoresis confirmed the purity was >95%. GP was labeled with sodium pertechnetate (Na99m TcO4) for in vitro and in vivo studies. Rhenium-GP was synthesized to support the binding site of 99m Tc at the glutamate positions 3-5. In vitro cellular uptake of 99m Tc-GP was performed in breast cancer cells. Cytosol had 60% whereas nucleus had 40% uptake of 99m Tc-GP. When cancer cells were incubated with glutamate or aspartate, followed by 99m Tc-GP, there was decreased uptake in cells treated with glutamate but not aspartate. The findings indicated that cellular uptake of 99m Tc-GP was via glutamate transporters. In addition, 99m Tc-GP was able to measure uptake differences after cells treated with paclitaxel. Biodistribution and planar imaging were conducted in breast tumor-bearing rats. Biodistribution of 99m Tc-GP showed increased tumor-to-tissue ratios as a function of time. Planar images confirmed that 99m Tc-GP could assess tumor uptake changes after paclitaxel treatment. In vitro and in vivo studies indicated that GP could target tumor cells, thus, GP may be a useful carrier for anti-cancer drug delivery.

Diammine dicarboxylic acid platinum enhances cytotoxicity in platinum-resistant ovarian cancer cells through induction of apoptosis and S-phase cell arrest.

PURPOSE: Polysaccharides such as chondroitin play a potent role in tumor growth, tissue repair and angiogenesis. These properties make chondroitin a good candidate for novel drug delivery systems. Diammine dicarboxylic acid platinum (DDAP), a novel polymeric platinum compound, was developed by conjugating the platinum analogue to aspartate-chondroitin for drug delivery to tumor cells. DDAP improves platinum solubility which may reduce systemic toxicity and be more efficacious than cisplatin in killing tumor cells. METHODS: We tested and compared the cytotoxic effects of DDAP and CDDP on the platinum-sensitive 2008 and A2780 ovarian cancer cell lines and their platinum-resistant sublines 2008.C13 and A2780cis; we also investigated DDAP's mechanism of action. RESULTS: In the platinum-sensitive cell lines, the cytotoxic effects of DDAP and CDDP were comparable. However, in the platinum-resistant sublines, significantly greater cell-growth inhibition was induced by DDAP than by CDDP, especially at lower doses. DDAP also induced more apoptosis than CDDP did in the 2008.C13 subline, which was partially mediated by the caspase 3-dependent pathway. In addition, lower (but not higher) doses of DDAP arrested 90% of S-phase 2008.C13 cells, which might be associated with up-regulation of p21 and maintenance of low cyclin A expression. Furthermore, greater cellular uptake of DDAP was seen in platinum-resistant than in platinum-sensitive ovarian cancer cells. CONCLUSIONS: Low-dose DDAP enhances drug delivery to platinum-resistant ovarian cancer cells and substantially inhibits their growth by inducting apoptosis and arresting cells in the S-phase, suggesting that DDAP may overcome platinum resistance in ovarian cancer.