In depth study on thermosensitive liposomes: Optimizing formulations for tumor specific therapy and in vitro to in vivo relations.

In numerous studies, thermosensitive liposomes (TSLs) for local heat-triggered delivery of Doxorubicin (Dox) to tumors have been investigated, with TSLs having different lipid formulations, drug loading methodology and testing procedures. To gain more insight in these parameters, we investigated TSLs with four variable DSPC-DPPC lipid ratios (50, 60, 70 or 80% DPPC and 5 mol% of DSPE-PEG2000) using either ammonium sulfate or a citrate buffer for Dox loading. Ammonium sulfate loading of Dox yielded more stable TSLs than citrate loading. At 37 °C, leakage was unnoticeable for all ammonium sulfate TSLs. At 42 °C, complete release occurred within seconds, except for 50% DPPC TSLs, where slow and incomplete release was observed in vitro but also in vivo using a dorsal skinfold window chamber. In contrast to in vitro assays, blood kinetics studies indicated a burst release of Dox upon injection and higher leakage for all TSLs. In therapeutic studies, hyperthermia in combination with TSLs repressed BFS-1 sarcoma growth. Our study shows that prediction of therapeutic efficacy purely based on differences found in vitro is difficult, instead, parameters obtained from pharmacokinetic studies in vivo, and the exact timing of the delivery protocol need to be taken into account.

89 Zr- and Fe-Labeled Polymeric Micelles for Dual Modality PET and T1 -Weighted MR Imaging.

In this study, a new 89 Zr- and Fe3+ -labeled micelle nanoplatform (89 Zr/Fe-DFO-micelles) for dual modality position emission tomography/magnetic resonance (PET/MR) imaging is investigated. The nanoplatform consists of self-assembling amphiphilic diblock copolymers that are functionalized with 89 Zr-deferoxamine (89 Zr-DFO) and Fe3+ -deferoxamine (Fe-DFO) for PET and MR purposes, respectively. 89 Zr displays favorable PET imaging characteristics with a 3.3 d half-life suitable for imaging long circulating nanoparticles. The nanoparticles are modified with Fe-DFO as MR T1 -contrast label instead of commonly used Gd3+ -based chelates. As these micelles are cleared by liver and spleen, any long term Gd- related toxicity such as nephrogenic systemic fibrosis is avoided. As a proof of concept, an in vivo PET/MR study in mice is presented showing tumor targeting of 89 Zr/Fe-DFO-micelles through the enhanced permeability and retention (EPR) effect of tumors, yielding high tumor-to-blood (10.3 ± 3.6) and tumor-to-muscle (15.3 ± 8.1) ratios at 48 h post injection. In vivo PET images clearly delineate the tumor tissue and show good correspondence with ex vivo biodistribution results. In vivo magnetic resonance imaging (MRI) allows visualization of the intratumoral distribution of the 89 Zr/Fe-DFO-micelles at high resolution. In summary, the 89 Zr/Fe-DFO-micelle nanoparticulate platform allows EPR-based tumor PET/MRI, and, furthermore, holds great potential for PET/MR image guided drug delivery.