Multiscale kinetic modeling of liposomal Doxorubicin delivery quantifies the role of tumor and drug-specific parameters in local delivery to tumors.

Nanoparticle encapsulation has been used as a means to manipulate the pharmacokinetic (PK) and safety profile of drugs in oncology. Using pegylated liposomal doxorubicin (PLD) vs. conventional doxorubicin as a model system, we developed and experimentally validated a multiscale computational model of liposomal drug delivery. We demonstrated that, for varying tumor transport properties, there is a regimen where liposomal and conventional doxorubicin deliver identical amounts of doxorubicin to tumor cell nuclei. In mice, typical tumor properties consistently favor improved delivery via liposomes relative to free drug. However, in humans, we predict that some tumors will have properties wherein liposomal delivery delivers the identical amount of drug to its target relative to dosing with free drug. The ability to identify tumor types and/or individual patient tumors with high degree of liposome deposition may be critical for optimizing the success of nanoparticle and liposomal anticancer therapeutics.CPT: Pharmacometrics & Systems Pharmacology (2012) 1, e15; doi:10.1038/psp.2012.16; advance online publication 21 November 2012.

Developing chemokine mutants with improved proteoglycan affinity and knocked-out GPCR activity as anti-inflammatory recombinant drugs.

The interaction of chemokines and GAGs (glycosaminoglycans) on endothelial surfaces is a crucial step for establishing a chemotactic gradient which leads to the functional presentation of chemokines to their GPCRs (G-protein-coupled receptors) and thus to activation of approaching leucocytes. Based on molecular modelling, biophysical investigations, cell-based and in vivo experiments, we have developed a novel concept for therapeutically interfering with chemokine-GAG interactions, namely dominant-negative chemokine mutants with improved GAG binding affinity and knocked-out GPCR activity. These recombinant proteins displace their wild-type chemokine counterparts from the natural proteoglycan co-receptors without being able to activate leucocytes via GPCRs. Our mutant chemokines therefore represent the first protein-based GAG antagonists with high therapeutic potential in inflammatory diseases.