Apr 1 2008
The University of Oregon's Jim Hutchison already holds three patents in the emerging field of nanotechnology as well as leadership roles in organizations that promote the technology's potential in materials science and medicine.
UO chemist Jim Hutchison pushes for green nanotechnology to reduce hazards(Photo by John Bauguess)
Hutchison, a chemist and materials scientist, however, also embraces a strong call for exploring potential environmental and health implications, which he says could be many, and for designing new materials with reduced hazard. The available data, he notes, are often uncertain or in conflict. He urges the industry to adopt a proactive approach now, before unforeseen roadblocks threaten the technology's progress.
"The absence of data or seemingly conflicting data -- for example, research articles and subsequent media reports that contribute to uncertainty about the hazards of carbon nanotubes -- reduces public confidence in product safety and invigorates activist groups that aim to prevent the use of nanomaterials in products of commerce," Hutchison writes in the March issue of ACS Nano, an international journal of the American Chemical Society.
Carbon nanotubes are molecules shaped like cylinders and have unique properties potentially useful in electronics, optics and various other materials. They are manufactured and synthesized in many different ways, and produce different results when trying to assess their safety.
"Without relevant data, innovators are forced to rely on 'reasonable worst-case scenarios' in applying risk-management frameworks or may not discover product hazards until late in product development," writes Hutchison, who is the leader of the Safer Nanomaterials and Nanomanufacturing Initiative of the Oregon Nanoscience and Microtechnologies Institute (ONAMI). "The lack of information on material safety hinders innovation and places companies at considerable risk of failure."
Nanomaterials are complex, as are their interactions with biological organisms and the environment. While microscopically sized, they come in all sizes, shapes and compositions. "To confound the situation further," he writes, "the methods of production are still immature for most materials, often resulting in batch-to-batch variability in composition and purity." Impurities, he says, are hard to detect, difficult to extract and may obscure the real effects of nanomaterials.
In his article, Hutchison, who also is the UO’s associate vice president for research and strategic initiatives, argues that "interdisciplinary teams that partner life, environmental and nanomaterial scientists need to work together to define standard approaches and share expertise to accelerate the collection of definitive data on nanomaterial hazards."
He has carried that message to numerous meetings of scientists involved in nanotechnology, a March 10 talk at the Greener Nano 2008 meeting in Corvallis, Ore., and in a presentation Dec. 17 to the Congressional Nanotech Caucus. Safety must be at the forefront, Hutchison says, as Congress considers reauthorization of the 21st Century Nanotechnology Research and Development Act.
Researchers need to come out of isolated labs, Hutchison says, and work collaboratively to address design, synthesis, characterization, and biological and environmental impacts. He praises an early effort to just that: the Nanotechnology Characterization Laboratory, a collaborative effort of the National Cancer Institute, National Institute of Standards and Technology and the Food and Drug Administration. He also notes the new federally funded NanoHealth Enterprise Initiative.
In ACS Nano, Hutchison addresses how green chemistry can reduce byproducts and simplify purification. He cites, as an example, how a particular material, using conventional chemistry, takes three days to purify and results in 15 liters of solvent per gram of nanoparticle. Using a green chemistry approach, he notes, the same thing is done in 15 minutes, and "the purification method can effectively reduce solvent consumption and provide cleaner, well-defined building blocks."
The time to implement green chemistry into nanotechnology is now, he says, before the industry exits its discovery phase, in which only small quantities of nanomaterials have been produced, and enters the production phase that will require the production of large quantities of nanomaterials that may pose potentially industry-stopping health and environmental problems.
Hutchison explains how the 12 principles of green chemistry can guide the design, production and use of nanomaterials. A green-chemistry approach, he says, should initially focus on determining the hazards of a narrow subset of nanomaterials that are closest to commercialization.
"Although these materials warrant immediate attention," he writes, "the information received from these studies will not provide enough correlations between nanomaterial structure and material hazard to design alternatives to those materials found to have an unacceptable level of hazard. A broader focus is needed to determine the design rules so that (re)design for product safety does not stall innovation and commercialization."