(November 9, 2010) — A nest for nanotubes may help magnetic resonance imaging (MRI) become better than ever at finding evidence of disease. Scientists at Rice University and other Texas Medical Center institutions and colleagues in Colorado, Italy and Switzerland have discovered a way to trap contrast agents inside a silicon particle that, when injected into a patient’s bloodstream, would make them up to 50x more effective.
Contrast agents "light up" damaged tissue in the body in images produced by MRI instruments. In 2007, 28 million MRI scans were performed in the United States, and contrast agents were used in nearly 45% of them. Read more about nanotechnology in medical sciences here.
Figure. A discoidal silicon microparticle, or SiMP, one micrometer across may dramatically improve the effectiveness of MRI scans. SiMPs hold nanotube-based contrast agents in their pores, delivering them to targets of interest, where they aggregate for up to 24 hours before the particles harmlessly dissolve. (Lesa Tran/Rice University)
"Making MRIs better is no small matter," said Lon Wilson, professor of chemistry at Rice and one of three senior co-authors of the research paper published online in Nature Nanotechnology. "MRI is one of the most powerful medical tools for imaging, if not the most powerful," he said. "It’s not invasive, it’s not ionizing harmful radiation and the resolution is the best you can get in medical imaging. The sensitivity, however, is poor. So anything you can do to improve performance and increase sensitivity is a big deal — and that’s what this does."
A nano-sized slice of silicon shaped like a hockey puck served as a delivery device for contrast agents in the study. Pores that were nanometers long and wide were created in the discs, called silicon microparticles (SiMPs).
Three types of contrast agents were drawn into the pores. Magnevist, a common contrast agent used worldwide, was one; the others were gadofullerenes and gadonanotubes, both pioneered by Wilson’s Rice lab. All three chemically sequester the toxic element gadolinium to make it safe for injection.
MRIs work by manipulating hydrogen atoms in water, which interact and align with the applied magnetic field from the instrument. The hydrogen atoms are then allowed to return to their original magnetic state, a process called relaxation. In the presence of the paramagnetic gadolinium ion, the atoms’ relaxation time is shortened, making these regions brighter against the background under MRI.
SiMPs are small — about a micrometer across — but when they trap both water molecules and bundles of nanotubes containing gadolinium, the protons appear much brighter in an MR image. Because SiMPs keep their form for up to 24 hours before dissolving into harmless silicic acid, the molecules can be imaged for a long time.
The trick is getting them to places in the body that doctors and technicians want to see. Wilson said SiMPs are designed to escape the bloodstream, where they leak and aggregate at the sites of tumors and lesions. "Spherical particles, at least in mathematical models, flow down the center of the vasculature," he said. "These particles are designed to hug the wall. When they encounter a leaky area like a cancer tumor, they can easily get out."
The encapsulation within SiMPs enhanced the performance of all three contrast agents, but SiMPs with gadonanotubes (carbon nanotubes that contain bundles of gadolinium ions) showed the best results. "The performance was enhanced beyond what we had imagined," he said.
SiMPs may also be functionalized with peptides that target cancer and other cells. SiMPs that contain contrast agents and medications could potentially be tracked as they home in on disease sites, where medications will be released as the silicon dissolves. Also read: A slow road to big impact: Small tech in medicine
The work is a collaboration with the labs of Mauro Ferrari and Paolo Decuzzi, who reported their success in creating mesoporous silicon particles in 2008. Ferrari, now president and CEO of The Methodist Hospital Research Institute in Houston, worked on the project while serving as a professor and chairman of the Department of Nanomedicine and Biomedical Engineering at the University of Texas Health Science Center, with appointments at The University of Texas MD Anderson Cancer Center and as an adjunct professor at Rice.
Decuzzi is a researcher with appointments at The Methodist Hospital Research Institute, The University of Texas Health Sciences Center at Houston and the University of Magna Graecia in Italy.
Ferrari and Decuzzi are the other two senior co-authors of the paper with Wilson. Co-authors of the paper include former Rice graduate student Jeyarama Ananta and current graduate students Richa Sethi and Ramkumar Krishnamurthy; Biana Godin, Xuewu Liu and Rita Serda of The University of Texas Health Science Center at Houston; Loick Moriggi and Lothar Helm of the Ecole Polytechnique Federale de Lausanne, Switzerland; Raja Muthupillai of St. Luke’s Episcopal Hospital; and Robert Bolskar of TDA Research Inc., Wheat Ridge, CO.
The work was supported by the Telemedicine and Advanced Technology Research Center-United States Army Medical Research Acquisition Activity through the Alliance for Nano Health and grants from the Department of Defense and National Institutes of Health, the Robert A. Welch Foundation, the Nanoscale Science and Engineering Initiative at Rice University, the Swiss National Science Foundation, European Cooperation in Science and Technology and TDA Research Inc.
Read the abstract at http://www.nature.com/nnano/journal/v5/n11/full/nnano.2010.203.html