Polymeric vesicles loaded with gadoteridol as reversible and concentration-independent magnetic resonance imaging thermometers.

The use of temperature sensitive liposomes (TSLs) loaded with paramagnetic Gd(III) complexes have been explored to develop MRI agents able to provide a imaging guide to heating-based therapies. Though the performance of such probes has been already demonstrated in vivo at preclinical level, further improvements (e.g., concentration independent image response, reversibility of the sensor) are necessary to increase the accuracy of the temperature readout. This work reports for the first time, the potential of Gd-loaded polymersomes (bilayered vesicles made of amphiphilic di-block copolymers) as improved thermosensitive MRI probes. Differently from conventional TSLs, such probes do not display a defined gel-to-liquid temperature transition and, therefore, they did not release their content in a wide temperature range, thereby allowing reversible temperature readouts. Moreover, a ratiometric approach based on the measurement of the ratio between transverse and longitudinal water protons relaxation rates (R2/R1) allows a temperature readout independent of the probe concentration. The imaging performance of temperature sensitive polymersomes prepared in this work was tested both in vitro and in vivo after subcutaneous injection in healthy mice.

Paramagnetic liposomes as innovative contrast agents for magnetic resonance (MR) molecular imaging applications.

This article illustrates some innovative applications of liposomes loaded with paramagnetic lanthanide-based complexes in MR molecular imaging field. When a relatively high amount of a Gd(III) chelate is encapsulated in the vesicle, the nanosystem can simultaneously affect both the longitudinal (R(1)) and the transverse (R(2)) relaxation rate of the bulk H2O H-atoms, and this finding can be exploited to design improved thermosensitive liposomes whose MRI response is not longer dependent on the concentration of the probe. The observation that the liposome compartmentalization of a paramagnetic Ln(III) complex induce a significant R(2) enhancement, primarily caused by magnetic susceptibility effects, prompted us to test the potential of such agents in cell-targeting MR experiments. The results obtained indicated that these nanoprobes may have a great potential for the MR visualization of cellular targets (like the glutamine membrane transporters) overexpressing in tumor cells. Liposomes loaded with paramagnetic complexes acting as NMR shift reagents have been recently proposed as highly sensitive CEST MRI agents. The main peculiarity of CEST probes is to allow the MR visualization of different agents present in the same region of interest, and this article provides an illustrative example of the in vivo potential of liposome-based CEST agents.

Determination of water permeability of paramagnetic liposomes of interest in MRI field.

The water permeability of various liposome membranes has been determined at 298K by measuring the NMR longitudinal water proton relaxation rate of vesicles encapsulating the clinically approved Gd-HPDO3A complex (HPDO3A=10-(2-hydroxypropyl)-1,4,7,10-tetraazacyclododecane-1,4,7-triacetic acid). Two basic formulations based on DPPC (dipalmitoylphosphatidylcholine) and POPC (palmitoyl-oleylphosphatidylcholine) phospholipids were selected and investigated. Furthermore, the permeability changes caused by the membrane incorporation of amphiphiles like cholesterol and/or metal complexes of interest for designing improved liposome-based MRI contrast agents, were also investigated. The incorporation of cholesterol and metal complexes bearing C18 saturated chains in POPC-based liposomes reduces the water diffusivity across the membrane bilayer. On the contrary, the incorporation of a macrocyclic metal complex bearing four C12 alkylic chains, one for each coordination arm of the ligand, considerably enhances the water permeability in DPPC-based liposomes. Finally, it is reported that the permeability of POPC-based bilayer is increased when the liposomes are subjected to an osmotic stress.

A R2/R1 ratiometric procedure for a concentration-independent, pH-responsive, Gd(III)-based MRI agent.

A novel procedure for making the pH responsiveness of a Gd-based probe independent of its concentration has been developed. The method is based on a ratiometric approach and requires the measurement, at magnetic fields higher than 1 T, of the paramagnetic contribution to the longitudinal and the transverse NMR relaxation rates of water protons in the presence of a Gd-based probe with a rotational mobility in the nanosecond time scale. The method has been tested and validated in vitro by using a macromolecular adduct based on the polyornithine backbone, whose rotational mobility is pH dependent. The results reported in this communication improve substantially the diagnostic potential of MRI responsive agents.