Researchers at North Carolina State University have developed a method for predicting the ways nanoparticles will interact with biological systems — including the human body. Their work could have implications for improved human and environmental safety in the handling of nanomaterials, as well as applications for drug delivery.
NC State researchers Dr. Jim Riviere, Burroughs Wellcome Distinguished Professor of Pharmacology and director of the university’s Center for Chemical Toxicology Research and Pharmacokinetics, Dr. Nancy Monteiro-Riviere, professor of investigative dermatology and toxicology, and Dr. Xin-Rui Xia, research assistant professor of pharmacology, wanted to create a method for the biological characterization of nanoparticles — a screening tool that would allow other scientists to see how various nanoparticles might react when inside the body.
“We wanted to find a good, biologically relevant way to determine how nanomaterials react with cells,” Riviere says. “When a nanomaterial enters the human body, it immediately binds to various proteins and amino acids. The molecules a particle binds with will determine where it will go.”
This binding process also affects the particle’s behavior inside the body. According to Monteiro-Riviere, the amino acids and proteins that coat a nanoparticle change its shape and surface properties, potentially enhancing or reducing characteristics like toxicity or, in medical applications, the particle’s ability to deliver drugs to targeted cells.
To create their screening tool, the team utilized a series of chemicals to probe the surfaces of various nanoparticles, using techniques previously developed by Xia. A nanoparticle’s size and surface characteristics determine the kinds of materials with which it will bond. Once the size and surface characteristics are known, the researchers can then create “fingerprints” that identify the ways that a particular particle will interact with biological molecules. These fingerprints allow them to predict how that nanoparticle might behave once inside the body.
The study results appear in the Aug. 23 online edition of Nature Nanotechnology.
“This information will allow us to predict where a particular nanomaterial will end up in the human body, and whether or not it will be taken up by certain cells,” Riviere adds. “That in turn will give us a better idea of which nanoparticles may be useful for drug delivery, and which ones may be hazardous to humans or the environment.”
The Center for Chemical Toxicology Research and Pharmacokinetics is part of NC State’s College of Veterinary Medicine. The research was funded by the Environmental Protection Agency and the U.S. Air Force Office of Scientific Research.
Note to editors: An abstract of the paper follows
“An index for characterization of nanomaterials in biological systems”
Authors: Xin-Rui Xia, Nancy A. Monteiro-Riviere and Jim E. Riviere, NC State University
Published: Online in Aug. 15, 2010, Nature Nanotechnology
Abstract: In a physiological environment, nanoparticles selectively absorb proteins to form ‘nanoparticle — protein coronas’, a process governed by molecular interactions between chemical groups on the nanoparticle surfaces and the amino-acid residues of the proteins. Here, we propose a biological surface adsorption index to characterize these interactions by quantifying the competitive adsorption of a set of small molecule probes onto the nanoparticles. The adsorption properties of nanomaterials are assumed to be governed by Coulomb forces, London dispersion, hydrogen-bond acidity and basicity, polarizability and lone-pair electrons. Adsorption coefficients of the probe compounds were measured and used to create a set of nanodescriptors representing the contributions and relative strengths of each molecular interaction. The method successfully predicted the adsorption of various small molecules onto carbon nanotubes, and the nanodescriptors were also measured for 12 other nanomaterials. The biological surface adsorption index nanodescriptors can be used to develop pharmacokinetic and safety assessment models for nanomaterials.
Could nanoparticles be used to reconstruct myelin destroyed by such diseases as multiple sclerosis? Even though the exact disease process is itself unknown.