Melita Menelaou received her Diploma in Chemical Engineering (2004) and Ph.D. degree (2009) from the Aristotle University of Thessaloniki (Greece). Dr. Menelaou was a member of respected research groups in Asia (Japan – Advanced Institute of Materials Research) and Europe (Czechia – Central European Institute of the Technology-Brno University of Technology; Spain – University of Barcelona; Greece – School of Chemical Engineering/School of Chemistry, Aristotle University of Thessaloniki). Currently, she is working in the Department of Chemical Engineering at the Cyprus University of Technology. Her work focuses on the synthesis, characterization, and application of a wide range of materials including nanomaterials, superconductors, and aerogels with technological and biomedical applications.
Abstract
Magnetic nanoparticle (MNP)-based theranostics are emerging as important tools for diagnosis and treatment (theranostics) of various cancer types, and bone disorders. Synthesis of MNPs that can act as Magnetic Resonance Imaging contrast agents with high relaxivity and low toxicity is one of the major pre-requisite in the field of theranostics.
Also, such applications require magnetic nanoparticles with well-defined composition, narrow size distribution, and high saturation magnetization values for enhanced interaction with an externally applied magnetic field. Spinel ferrites with the general formula MFe2O4 (M = Mn, Fe, Co, Ni) have been proposed among others to act as MRI contrast enhancement agents among other types of MNPs based on both transition metal ions and rare earth elements in the presence of various organic moieties, polymers, ligands, etc.
A facile solvothermal approach was used to synthesize stable ferrite nanoparticles as a simple and eco-friendly route, providing products that exhibit high crystallinity in the presence of well-defined polymers and/or organic ligands. The hydrophobic MNPs converted to hydrophilic and the hyperthermic effects, as well as relaxometry properties, were studied and evaluated. Hydrophobic MFe2O4 nanoparticles coated with oleylamine (MFe2O4@OAm MNPs, where M = Co, Mn, Ni) with a similar shape and size (∼9 nm) and magnetization values of 87.4, 63.1, and 55.0 emu g−1 for CoFe2O4@OAm, MnFe2O4@OAm, and NiFe2O4@OAm, respectively, were successfully encapsulated into the hydrophobic cores of spherical micellar structures formed by the copolymers in an aqueous solution through a solvent mixing procedure.
Materials Engineering and Technology
Advanced Materials and Devices
Advanced Biomaterials and bio devices
Materials for Drug & Gene Delivery
Materials for Energy and Environmental technology
Polymer Nanotechnology
Carbon Nanostructures & Graphene
Nano Electronics
Bio Nanotechnology
Applications of Material Engineering and Nanotechnology