Eneko Garaio

TL;DR: A broad overview of magnetic hyperthermia addressing new perspectives and the progress on relevant features such as the ad hoc preparation of magnetic nanoparticles, physical modeling of magnetic heating, methods to determine the heat dissipation power of magnetic colloids including the development of experimental apparatus and the influence of biological matrices on the heating efficiency is presented in this article.

TL;DR: Considering the proven advantages of high aspect ratio one-dimensional (1D) Fe3O4 nanostructures over their spherical and cubic counterparts, such as larger surface area, multisegmented capabilities, enhanced blood circulation time, and prolonged retention in tumors, this paper proposed a novel approach that utilizes this 1D nanostructure for enhanced hyperthermia.

TL;DR: In this article, the size and shape of the superparamagnetic iron oxide nanoparticles can be tuned to enhance the heating efficiency of the nanoparticles, which is a promising therapy for cancer treatment.

TL;DR: A broad overview of magnetic hyperthermia addressing new perspectives and the progress on relevant features such as the ad hoc preparation of magnetic nanoparticles, physical modeling of magnetic heating, methods to determine the heat dissipation power of magnetic colloids including the development of experimental apparatus and the influence of biological matrices on the heating efficiency is presented in this paper.

TL;DR: In this article, the shape of nano-octopod cubes (Octopods) was modified to increase the heating efficiency of the octopod to up to 70% (from 140 to 240 W/g) by using nonhydrolytic thermal decomposition.