Characterizing Drug-Polymer Bead Interactions Using Isothermal Titration Calorimetry.

Isothermal titration calorimetry was used to investigate thermodynamic and kinetic binding interactions between 4 clinically relevant drugs: doxorubicin (Dox), irinotecan (Iri), mitoxantrone (Mitox), and topotecan (Topo) and a range of commercially available embolization microspheres. Five drug-eluting beads were chosen to consider the effect of bead size (ranging from 70-150 µm to 500-700 µm) and bead type (sulfonate-modified polyvinylalcohol hydrogel, known commercially as DC BeadM1™, and a sulfonate-modified polyethylene glycol hydrogel bead, known commercially as LifePearl™). The molar ratio of drug to SO3- was found to be 0.9:1, 0.8:1, 0.4:1, and 0.9:1 for Dox, Iri, Mitox, and Topo, respectively. These findings indicate the steric effects of drug shape, charge, and size on binding ability. Four distinct bead sizes all produced drug:bead binding ratios of >0.9:1 doxorubicin:SO3-, thus indicating that bead size does not affect binding stoichiometry. Interestingly, bead size did affect the rate of binding as bead size was found to be indirectly proportional to binding rate. Finally, it was found for the sulfonate-modified polyethylene glycol hydrogel beads that doxorubicin binding was faster (at certain ratios of drug to bead) than that for the sulfonate-modified polyvinylalcohol hydrogel yet was maximal at a drug to bead ratio of only 0.7:1.

A calorimetric investigation of doxorubicin-polymer bead interactions.

Isothermal titration calorimetry (ITC) was utilised to investigate suitability of the technique to determine the stoichiometry and thermodynamics of the interactions that occur between a commonly used chemotherapeutic drug, namely doxorubicin, and a polymer bead-based drug delivery embolisation system (DC Bead™). Six temperatures were selected for drug-polymer titrations (293-313 K) and in all cases an initially exothermic signal reverted to an endothermic response upon the saturation of the beads with drug. From these experiments, and subsequent calculations, the molar ratio of drug to SO3(-) (polymer) was found to be 0.4:1 at all temperatures studied. Enthalpic data was calculated from the raw ITC data with an average enthalpy of drug-polymer binding of - 14.8 kJ mol(-1) at 293 K through to - 19.4 kJ mol(-1) at 313 K implying the process is enthalpically-driven yet only affected by an increase in experimental temperature to a limited extent whereby an increase in experimental temperature results in a small increase in the negativity in change in enthalpy recorded. The application of ITC in this study (with its unique ability to monitor real-time interactions and facilitate stoichiometric calculations) resolves the lack of knowledge regarding the thermodynamics of this specific drug-polymer interaction. This study confirms that ITC is not only useful for this specific system, but also highlights the potential use of ITC for more general studies in this area.