In current research related to improving cancer treatments, one promising area of research is the effort to find ways to selectively pinpoint and target cancer cells while minimizing effects on healthy cells.
In that effort, it's already been found in lab experiments that iron-oxide nanoparticles, when heated and then applied specifically to cancer cells, can kill those cells because cancer cells are particularly susceptible to changes in temperature. Increasing the temperature of cancer cells to over 43 degrees Celsius (about 109 degrees Fahrenheit) for a sufficient period of time can kill those cells.
So, a University of Cincinnati-led team -- along with researchers at Iowa State University, the University of Michigan and Shanghai Jiao Tong University -- recently conducted experiments to see which iron-oxide nanoparticle configurations or arrangements might work best as a tool to deliver this killing heat directly to cancer cells, specifically to breast cancer cells. The results will be presented at the March 3-7 American Physical Society Conference in Denver by UC physics doctoral student Md Ehsan Sadat.
In systematically studying four distinct magnetized nanoparticle systems with different structural and magnetic properties, the research team found that an unconfined nanoparticle system, which used an electromagnetic field to generate heat, was best able to transfer heat absorbed by cancer cells.
So, from the set of nano systems studied, the researchers found that uncoated iron-oxide nanoparticles and iron-oxide nanoparticles coated with polyacrylic acid (PAA) -- both of which were unconfined or not embedded in a matrix -- heated quickly and to temperatures more than sufficient to kill cancer cells.
The goal was to determine the heating behaviors of different iron-oxide nanoparticles that varied in terms of the materials used in the nanoparticle apparatus as well as particle size, particle geometry, inter-particle spacing, physical confinement and surrounding environment since these are the key factors that strongly influence what's called the Specific Absorption Rate (SAR), or the measured rate at which the human body can absorb energy (in this case heat) when exposed to an electromagnetic field.
According to Sadat, "What we found was that the size of the particles and their anisotropic (directional) properties strongly affected the magnetic heating achieved. In other words, the smaller the particles and the greater their directional uniformity along an axis, the greater the heating that was achieved."
He added the systems' heating behaviors were also influenced by the concentrations of nanoparticles present. The higher the concentration of nanoparticles (the greater the number of nanoparticles and the more densely collected), the lower the SAR or the rate at which the tissue was able to absorb the heat generated.
THE FOUR SYSTEMS STUDIED The researchers studied
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