All the objectives provided in the implementation plan related to Stage 1 ("(“Processing and morpho-structural characterization of Fe based magnetic nanoparticles and their optimization in relation to different applications”) consisting of: i) Synthesis, morpho-structural and magnetic characterization of at least 5 systems of magnetic nanoparticles (objectives O1 and O2), ii) scientific research report, iii) 1 scientific article sent for publication in ISI listed journals, iv) creation of a website for project and v) participation in a national/international conference) were fulfilled integral.

Following the studies from specific literature, the preparation methods and precursors for obtaining magnetic monodomain particles, with specific morphologies, controlled size and a relatively narrow particle size distribution, were established.

Preliminary preparations of oxo-hydroxides and iron oxides (magnetite) were carried out by: i) co-precipitation, ii) treatment of acicular oxy-hydroxide precursors, iii) hydrothermal decomposition and iv) thermal decomposition of organo-metallic compounds in solvents with high boiling point.

The influence of the preparation conditions (molar ratio of surfactant mixture, time and temperature of thermal treatment) on the morphology and size of magnetite nanoparticles obtained by the thermal decomposition of organo-metallic compounds was studied. The correlation between the magnetite morphology and the mixture of surfactants was established.

Various systems of hydrophobic magnetite, magnetic monodomain, with spherical, hexagonal, cubic or polyhedral morphologies were prepared.

Starting from the hydrophobic particles synthesized by the thermal decomposition of organo-metallic compounds in solvents with a high boiling point, hydrophilic particles functionalized with azelaic acid were obtained .

Through morpho-structural measurements the crystalline phases, shape and size of the constituent nanoparticles were identified (iron oxide nanoparticles with diameters between 20-50 nm were processed).

Mössbauer spectroscopy measurements and magnetic measurements confirmed the formation of magnetic monodomain nanoparticles, that do not reach the superparamagnetic regime, but which have saturation magnetizations and coercive appropriate for magnetic hyperthermia applications.

The results obtained were disseminated through a participation in a national conference, 2 articles published in ISI rated journals and an article sent for publication to Materials magazine.

Stage II: Comparative studies on specific mechanisms revealed by SAR measurements. Final characteristics of new mechanisms for optimizing compounds for hyperthermia applications.

Summary

• Through the thermal decomposition of organo-metallic compounds in solvents with a high boiling point, hydrophobic magnetic nanoparticle systems with controlled shape and size were obtained. In order to be able to use them in bio-medical applications, the following procedures were approached to functionalize the surface of hydrophobic magnetic nanoparticles: i) the transformation of hydrophobic magnetite into hydrophilic magnetite through oxidative reactions; ii) using a Shaker with Eppendorf blocks, with mixing and heating functions, in the attempt to replace the organic surfactant on the NPs surface with citric acid or ascorbic acid; iii) functionalization of hydrophobic Fe3O4 with Silica; iv) removal of the surfactant/organic ligand from the hydrophobic MNPs surface by dissolving it in DMSO or DMF;

• To improve the stability of magnetic nanoparticle systems in aqueous solutions, new processing methods were approached consisting of: i) Synthesis of magnetite MNPs by direct functionalization with citric acid right during the preparation procedure; ii) Synthesis by coprecipitation of magnetite MNPs and surface functionalization by coating with compounds that induce electrostatic repulsive forces;

•  In order to reduce/eliminate as much as possible the heat losses in the magnetic hyperthermia experiments, a device with quasi-adiabatic isolation (patent pending) was designed and made to increase the precision of the specific absorption rate (SAR) measurements of a suspension of magnetic nanoparticles. Only non-magnetic materials (Duramid, Plexiglas, plastic) were used in order not to interact with the electromagnetic field of the induction coil;

• For a more accurate assessment of the specific absorption rate (SAR) in magnetic hyperthermia experiments, an original methodology was proposed for the compensation of heat losses over a wide range of temperature, along with a series of experimental precautions to minimize the heat losses, maintaining the inductor's cooling liquid at a constant temperature (as close as possible to room temperature), as well as gravitational sedimentation of the MNPs under investigation;

• The morpho-structural and magnetic measurements confirm the formation of superparamagnetic particles or the formation of magnetic monodomain nanoparticles (which do not reach the superparamagnetic regime), but which show saturation magnetizations and coercive fields that recommend them for magnetic hyperthermia applications;

• Recommendations for average concentrations of nanoparticles intended for biomedical applications and the optimization of heat transfer in relation to the frequencies and biological RF field intensities accepted.