A Fluorescent Oxaliplatin Derivative for Investigation of Oxaliplatin Resistance Using Imaging Techniques

Overview

Journal J Biol Inorg Chem

Publisher Springer

Specialty Biochemistry

Date 2017 Oct 19

PMID 29043454

Citations 2

Authors

Ganna V Kalayda

Maximilian Kullmann

Mathea Sophia Galanski

Sabrina Gollos

Affiliations

Soon will be listed here.

Abstract

Oxaliplatin is the backbone of chemotherapy for advanced colorectal cancer and undergoes clinical trials for treatment of other tumour entities. However, acquired resistance is a major hurdle. Confocal microscopy is a useful tool to get an insight into the mechanisms of resistance but it requires fluorescent compounds. This work describes the synthesis of the novel oxaliplatin derivative (CFDA-oxPt) featuring 5(6)-carboxyfluorescein diacetate and evaluation of its applicability for the investigation of oxaliplatin resistance using imaging techniques. CFDA-oxPt was somewhat less cytotoxic than oxaliplatin in sensitive colorectal cancer cells, with EC values of 26 and 5.8 µM, respectively. Nevertheless, the potency of the novel complex was significantly decreased to the EC of 711.2 µM in oxaliplatin-resistant cells, as was the case for oxaliplatin (EC = 81 µM). After incubation, both nuclear and cytosolic localisation was observed. Over time CFDA-oxPt concentrated near the cell membrane and in the vesicular structures, in contrast to the platinum-free label, which was rapidly excreted. These findings suggest that CFDA-oxPt can be used to study oxaliplatin resistance and open the route to new fluorophore-tethered oxaliplatin derivatives.

Citing Articles

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Silencing GnT-V reduces oxaliplatin chemosensitivity in human colorectal cancer cells through N-glycan alteration of organic cation transporter member 2.

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