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Materials

For Nanoparticles, Size Does Matter

Nanotoxicology: Precise control of nanoparticle dimensions shows that size and shape of cerium dioxide nanomaterials influences their ability to damage cells

by Katharine Sanderson
May 14, 2012

SIZE MATTERS
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Credit: ACS Nano
Scientists made cerium dioxide nanorods of various lengths and diameters to test their toxicity.
Micrographs of cerium dioxide nanorods
Credit: ACS Nano
Scientists made cerium dioxide nanorods of various lengths and diameters to test their toxicity.

A library of nanoparticles made to exact dimensions has revealed that particle size and shape affects their toxicity in cells (ACS Nano, DOI: 10.1021/nn3012114).

As part of a larger effort to devise safety tests for nanomaterials, Jeffrey Zink of the University of California, Los Angeles and his colleagues have made libraries of nanorods and wires of cerium dioxide. For applications in electronics and catalysis, manufacturers usually make nanoscale cerium dioxide into spheres, which aren’t thought to be toxic. But these products sometimes contain other shapes. Zink and his team wanted to determine whether shape made a difference.

Using a standard synthesis method in water, Zink’s team carefully controlled the temperature, pH, and ions present to make a range of nanorods and wires with precisely controlled ratios of length to diameter, called the aspect ratio. Using this library of eight materials, they tested the toxicity of the nanoparticles in human leukemia cells, a line commonly used in inflammation studies.

Cells treated with the short rods died at the same rate as untreated cells, indicating to the researchers that the small particles weren’t toxic. But bigger particles–those greater than 495 nm long and 9.5 nm wide–triggered some cells to activate an inflammatory protein, and killed the 35% of the cells.

The test is the first to examine the role of aspect ratio in cell toxicity, the team says. Using these results coupled with other data the group is gathering, including data on particles’ electronic properties (ACS Nano, DOI: 10.1021/nn3010087), could help researchers predict toxicology and risk for nanomaterials, says study coauthor Andre Nel.

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