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France’s nanomaterial declaration

Thursday, May 16th, 2013

I stumbled across a rather brief May 13, 2013 announcement on the ICON (International Council on Nanotechnology) website about a French nanomaterial initiative,

France Extends Deadline for Reporting Nanomaterials (NOECT Blog)

Further investigation landed me on the R-Nano.fr; Declaration of Nanomaterials website,

Welcome to the website for declaring substances with nanoparticle status: “r-nano”. On these pages you can declare the substances with nanoparticle status that you produce, import, distribute, or formulate, as required by Articles L. 523-1 to L. 523-5 of the French Environmental Code.

At the deadline of 30 April 2013, 457 companies have made 1991 declarations. These initial results shows a satisfactory mobilization of stakeholders.

The Ministry of Ecology, Sustainable Development and Energy, considering the diversity of actors covered by the declaration requirement, and at the request of several industries, decided, for the first reporting year, to grant two more months to complete the declarations. Thereby, exceptionally, new declarations can be initiated and submitted until 30 June 2013.

There’s a little more explanation of the site’s raison d’être on the Help/FAQs page,

Q : 1/ Why is there a system for declaring substances with nanoparticle status ?

Because of the advantages offered by their specific properties, substances with nanoparticle status are used in a number of sectors: foodstuffs, aeronautics, cosmetics, alternative energies, pneumatics, health, sport and others. The properties in question are such as to create potential hazards for humans and the environment. As emphasised in the European Commission Communication of 3 October 2012, a substance can present different hazards depending on whether it has bulk status or nanoparticle status.

For a better understanding of the issues, it seems necessary to acquire an improved knowledge of the market, including the substances marketed in France, their uses, the sectors in which they are used, the quantities involved, etc.

With the help of this information, it will be possible to estimate exposures more accurately and produce risk assessments for these substances. It is for this purpose that France has decided to introduce mandatory declaration of substances with nanoparticle status, whether in that form, in mixtures or within certain materials.

Q : 2/ How must declarations be made? Is there a special form ?

A web site has been set up on which the various companies concerned can each create an account and submit their declarations. The address of the declaration web site is www.r-nano.fr

Regarding declarations for which applicants wish to make use of the waiver concerning the availability of information to the public provided for activities related to national defence, the declaration will first be made online and then finalised on paper.

Q : 3/ At what date does the system come into force ?

The system comes into force on 1 January 2013: the first declarations will concern substances in nanoparticle status produced, imported and/or distributed during 2012.

Q : 5/ If a substance with nanoparticle status is indicated on the packaging (case of biocides and cosmetics in 2013), is it still necessary to submit a declaration ?

Yes: the labelling and the declaration system do not have the same purpose.

Q : 6/ Is France the only country in Europe with this kind of declaration system ?

Yes, though Italy, Belgium and Denmark are considering the introduction of similar measures.

Q : 7/ Which players are concerned by the declaration ? (UPDATED)

All national participants in the distribution chain in France covered by the requirement to declare substances with nanoparticle status must complete a declaration if they produce, import into France from another Member State of the European Union or from any other country or distribute any substance, mixture or “article” (article, see Question 18) covered by the definitions laid down in Article R. 523-12 and in quantities exceeding 100 grams/year and per substance.

Q : 38/ How will the information supplied be used ?

The information supplied for declarations enables the authorities to estimate the flows of substances with nanoparticle status in France, which will be a “first” for Europe. The knowledge acquired concerning substances and their uses, the production and usage sectors, or the quantities sold, will provide insight into the dissemination of these substances and their actual use.

To help them undertake health risk assessments, authorities will be allowed to request supplementary information from declarers, when available, especially concerning toxicological and ecotoxicological data, as well as data concerning exposure.

I have two comments. First, there are over 40 questions in the FAQs but none concern the issue of how this requirement will be enforced. Second, I gather that after abysmal results elsewhere the French concluded that voluntary reporting does not work.

It’s good to see at least [one*] government making an attempt to gather the information openly. The Canadian scheme was managed in a more clandestine fashion. I finally tracked down some information about it in an OECD (Organization for Economic Cooperation and Development) document and featured some of the data from the Canadian nanomaterial reporting scheme (as reported to the OECD)  in my April 12, 2010 posting.

* ETA May 17, 2013: I added the word ‘one’.

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Nanosilver resistance

Wednesday, May 8th, 2013

Researchers at Australia’s University of New South Wales (UNSW) have published a study where they claim that bacteria have develop resistance to nanosilver, a product used widely for its antibacterial properties. From the May 8, 2013 news item on ScienceDaily,

Researchers from UNSW have cautioned that more work is needed to understand how micro-organisms respond to the disinfecting properties of silver nano-particles, increasingly used in consumer goods, and for medical and environmental applications.

Although nanosilver has effective antimicrobial properties against certain pathogens, overexposure to silver nano-particles can cause other potentially harmful organisms to rapidly adapt and flourish, a UNSW study reveals.

The May 8, 2013 UNSW news release, which originated the news item, notes,

“We found an important natural ability of a widely occurring bacteria to adapt quite rapidly to the antimicrobial action of nanosilver. This is the first unambiguous evidence of this induced adaptation,” says co-author Dr Cindy Gunawan, from the UNSW School of Chemical Engineering.

Using an experimental culture, UNSW researchers observed that nanosilver was effective in suppressing a targeted bacteria (Escherichia coli), but that its presence initiated the unexpected emergence, adaptation and abnormally fast growth of another bacteria species (Bacillus).

The news release mentions some of the implications,

The efficacy of nanosilver to suppress certain disease-causing pathogens has been well-documented, and as a result, it has become widely used in medicine to coat bandages and wound dressings. It also has environmental uses in water and air purification systems, and is used in cosmetics and detergents, and as a surface coating for things like toys and tupperware.

But the researchers say this exploitation of nanosilver’s antimicrobial properties have “gained momentum due in part to a lack of evidence for the potential development of resistant microorganisms”.

“Antimicrobial action of nanosilver is not universal and the widespread use of these products should take into consideration the potential for longer-term adverse outcomes,” says Gunawan.

The researchers say these adverse impacts could be more pronounced given the near-ubiquitous nature of the Bacillus bacteria, which originate from airborne spores, and because the resistance trait can potentially be transferred to the genes of other micro-organisms.

“For the medical use of nanosilver, this implies the potential for reduced efficacy and the development of resistant populations in clinical settings,” says co-author Dr Christopher Marquis, a senior lecturer from the UNSW School of Biotechnology and Biomolecular Sciences. [emphasis mine]

I have touched on the issue of resistance and bacteria previously in the context of finding new ways to deal with them in my Don’t kill bacteria, uninvite them posting of Aug. 13, 2012 about developing new materials that resist bacteria and and there’s my mention of Sharklet, a material based on the nanoscale properties of sharkskin and which has potential for use in hospital settings, in my Feb. 10, 2011 posting.

For those who’d like to read about this work from the University of New South Wales, the ScienceDaily news item provides a link to and a citation for the paper which has been published in Small. This paper is behind a paywall and the publisher (Wiley Online Library), puzzingly and in comparison to other publishers, has made the paper hard to find.

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US multicenter (Nano GO Consortium) study of engineered nanomaterial toxicology

Wednesday, May 8th, 2013

Nano Go Consortium is the name they gave a multicenter toxicology study of engineered nanomaterials which has pioneered a new approach  in the US to toxicology research. From the May 6, 2013 news item on Azonano,

For the first time, researchers from institutions around the country have conducted an identical series of toxicology tests evaluating lung-related health impacts associated with widely used engineered nanomaterials (ENMs).

The study [on rodents] provides comparable health risk data from multiple labs, which should help regulators develop policies to protect workers and consumers who come into contact with ENMs.

The May 6, 2013 North Carolina State University news release, which originated the news item, describes the results from one of two studies that were recently published by the Nano GO Consortium in Environmental Health Perspectives,

The researchers found that carbon nanotubes, which are used in everything from bicycle frames to high performance electronics, produced inflammation and inflammatory lesions in the lower portions of the lung. However, the researchers found that the nanotubes could be made less hazardous if treated to remove excess metal catalysts used in the manufacturing process or modified by adding carboxyl groups to the outer shell of the tubes to make them more easily dispersed in biological fluids.

The researchers also found that titanium dioxide nanoparticles also caused inflammation in the lower regions of the lung. Belt-shaped titanium nanoparticles caused more cellular damage in the lungs, and more pronounced lesions, than spherical nanoparticles.

Here’s a link to and a citation for this study on rodents,

Interlaboratory Evaluation of Rodent Pulmonary Responses to Engineered Nanomaterials: The NIEHS NanoGo Consortium by James C. Bonner, Rona M. Silva, Alexia J. Taylor, Jared M. Brown, Susana C. Hilderbrand, Vincent Castranova, Dale Porter, Alison Elder, Günter Oberdörster, Jack R. Harkema, Lori A. Bramble, Terrance J. Kavanagh, Dianne Botta, Andre Nel, and Kent E. Pinkerton. Environ Health Perspect (): .doi:10.1289/ehp.1205693  Published: May 06, 2013

And the information for the other study which this consortium has published,

Interlaboratory Evaluation of in Vitro Cytotoxicity and Inflammatory Responses to Engineered Nanomaterials: The NIEHS NanoGo Consortium by Tian Xia, Raymond F. Hamilton Jr, James C. Bonner, Edward D. Crandall, Alison Elder, Farnoosh Fazlollahi, Teri A. Girtsman, Kwang Kim, Somenath Mitra, Susana A. Ntim, Galya Orr, Mani Tagmount8, Alexia J. Taylor, Donatello Telesca, Ana Tolic, Christopher D. Vulpe, Andrea J. Walker, Xiang Wang, Frank A. Witzmann, Nianqiang Wu, Yumei Xie, Jeffery I. Zink, Andre Nel, and Andrij Holian. Environ Health Perspect (): .doi:10.1289/ehp.1306561 Published: May 06, 2013

Environmental Health Perspectives is an open access journal and the two studies are being offered as ‘early’ publication efforts and will be updated with the full studies at a later date.

Most interesting for me is the editorial offered by four of the researchers involved in the Nano GO Consortium, from the editorial,

Determining the health effects of ENMs presents some unique challenges. The thousands of ENMs in use today are made from an enormous range of substances, vary considerably in size, and take a diversity of shapes, including spheres, cubes, cones, tubes, and other forms. They are also produced in different laboratories across the world using a variety of methods. In the scientific literature, findings on the properties and toxicity of these materials are mixed and often difficult to compare across studies. To improve the reliability and reproducibility of data in this area, there is a need for uniform research protocols and methods, handling guidelines, procurement systems, and models.

Although there is still much to learn about the toxicity of ENMs, we are fortunate to start with a clean slate: There are as yet no documented incidences of human disease due to ENM exposure (Xia et al. 2009). Because ENMs are manmade rather than natural substances, we have an opportunity to design, manufacture, and use these materials in ways that allow us to reap the maximum benefits—and minimal risk—to humans.

With $13 million from the American Recovery and Reinvestment Act (2009), the National Institute of Environmental Health Sciences (NIEHS) awarded 13 2-year grants to advance research on the health impacts of ENMs (NIEHS 2013). [emphasis mine] Ten grants were awarded through the National Institutes of Health (NIH) Grand Opportunities program and three were funded through the NIH Challenge Grants program. One goal of this investment was to develop reliable, reproducible methods to assess exposure and biological response to nanomaterials.

Within the framework of the consortium, grantees designed and conducted a series of “round-robin” experiments in which similar or identical methods were used to perform in vitro and in vivo tests on the toxicity of selected nanomaterials concurrently at 13 different laboratories.

Conducting experiments in a round-robin format within a consortium structure is an unfamiliar approach for most researchers. Although some researchers acknowledged that working collaboratively with such a large and diverse group at times stretched the limits of their comfort zones, the consortium ultimately proved to be “greater than the sum of its parts,” resulting in reliable, standardized protocols that would have been difficult for researchers to achieve by working independently. Indeed, many participants reflected that participating in the consortium not only benefitted their shared goals but also enhanced their individual research efforts. The round-robin approach and the overall consortium structure may be valuable models for other emerging areas of science.

Here’s a link to and a citation for the Consortium’s editorial, which is available in full,

Nano GO Consortium—A Team Science Approach to Assess Engineered Nanomaterials: Reliable Assays and Methods by Thaddeus T. Schug, Srikanth S. Nadadur, and Anne F. Johnson. Environ Health Perspect 121(2013). http://dx.doi.org/10.1289/ehp.1306866 [online 06 May 2013]

I like the idea of researchers working together across institutional and geographical boundaries as that can be a very powerful approach. I hope that won’t devolve into a form of institutionalized oppression where individual researchers are forced out or ignored. In general, it’s the outlier research that often proves to be truly groundbreaking, which often generates extraordinary and informal (and sometimes formal) resistance. For an example of groundbreaking work that was rejected by other researchers who banded together informally, there’s Dan Shechtman, 2011 Nobel Laureate in Chemistry, famously faced hostility from his colleagues for years over his discovery of quasicrystals.

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US Environmental Protection Agency (EPA) releases Application of Life-Cycle Assessment to Nanoscale Technology: Lithium-ion Batteries for Electric Vehicles

Tuesday, April 30th, 2013

There’s more about the Application of Life-Cycle Assessment to Nanoscale Technology: Lithium-ion Batteries for Electric Vehicles (final report) in the Apr. 30, 2013 news item on Nanowerk (Note: Links were removed),

The final report for the life-cycle assessment (LCA) of current and emerging energy systems used in plug-in hybrid and electric vehicles conducted by the DfE [Design for the Environment]/ORD [Office of Research and Development] Li-ion Batteries and Nanotechnology Partnership is now available. The LCA results will help to promote the responsible development of these emerging energy systems, including nanotechnology innovations in advanced batteries, leading to reduced overall environmental impacts and the reduced use and release of more toxic materials.

This partnership was led by EPA’s Design for the Environment (DfE) Program, in the Office of Pollution Prevention and Toxics, and the National Risk Management Research Laboratory, in EPA’s Office of Research and Development.

US EPA’s Partnership for “Application of Life-Cycle Assessment to Nanoscale Technology: Lithium-ion Batteries for Electric Vehicles” webspace describes the project and the report,

The partnership conducted a screening-level life-cycle assessment (LCA) of currently manufactured lithium-ion (Li-ion) battery technologies for electric vehicles, and a next generation battery component (anode) that uses single-walled carbon nanotube (SWCNT) technology.

A quantitative environmental LCA of Li-ion batteries was conducted using primary data from both battery manufacturers and recyclers–and the nanotechnology anode currently being researched for next-generation batteries.

This type of study had not been previously conducted, and was needed to help grow the advanced-vehicle battery industry in a more environmentally responsible and efficient way. The LCA results are expected to mitigate current and future impacts and risks by helping battery manufacturers and suppliers identify which materials and processes are likely to pose the greatest impacts or potential risks to public health or the environment throughout the life cycle of their products. The study identifies opportunities for environmental improvement, and can inform design changes that will result in the use of less toxic materials and reduced overall environmental impacts, and increased energy efficiency.

The opportunities for improving the environmental profile of Li-ion batteries for plug-in and electric vehicles identified in the draft LCA study have the potential to drive a significant reduction of potential environmental impacts and risks, given that advanced batteries are an emerging and growing technology.

The study also demonstrates how the life-cycle impacts of an emerging technology and novel application of nanomaterials (i.e., the SWCNT anode) can be assessed before the technology is mature, and provides a benchmark for future life-cycle assessments of this technology.

For anyone who’s interested the final report (all 126 pp) of the LCA is available here.

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Gold nanoparticles: more toxic than we thought?

Friday, April 19th, 2013

The research from Stony Brook University (New York State) is a bit disturbing but it should be noted that the tests were done ‘in vitro’ which means they took place in a test tube or a culture dish or somewhere else outside the body. Plus, the conditions for this type of testing are usually quite different than those in real life, e.g. the concentration of gold particles may be significantly higher than the concentration an individual would be exposed to at any one time.

Oddly, earlier this week I responded to a query about information on gold nanoparticles from an artist in New Zealand by noting that I had never come across any toxicity or toxicology testing studies but mentioned that mine is a passive approach. I scan aggregators and other news sources but I don’t usually seek out specific  information about toxicity/toxicology.

So here it is, the first gold nanoparticle toxicity study I’ve featured on this blog in almost five years,from an Apr. 18, 2013 news item on ScienceDaily,

New research reveals that pure gold nanoparticles found in everyday items such as personal care products, as well as drug delivery, MRI contrast agents and solar cells can inhibit adipose (fat) storage and lead to accelerated aging and wrinkling, slowed wound healing and the onset of diabetes. [emphasis mine] The researchers, led by Tatsiana Mironava, a visiting assistant professor in the Department of Chemical and Molecular Engineering at Stony Brook University, detail their research in the journal Nanotoxicology.

The Stony Brook University Apr. 18, 2013 news release, which originated the news item, provides details,

Together with co-author Dr. Marcia Simon, Professor of Oral Biology and Pathology at Stony Brook University, and Director of the University’s Living Skin Bank, a world-class facility that has developed skin tissue for burn victims and various wound therapies, the researchers tested the impact of nanoparticles in vitro on multiple types of cells, including adipose (fat) tissue, to determine whether their basic functions were disrupted when exposed to very low doses of nanoparticles. Subcutaneous adipose tissue acts as insulation from heat and cold, functions as a reserve of nutrients, and is found around internal organs for padding, in yellow bone marrow and in breast tissue.

They discovered that the human adipose-derived stromal cells – a type of adult stem cells – were penetrated by the gold nanoparticles almost instantly and that the particles accumulated in the cells with no obvious pathway for elimination. The presence of the particles disrupted multiple cell functions, such as movement; replication (cell division); and collagen contraction; processes that are essential in wound healing.

According to the researchers, the most disturbing finding was that the particles interfered with genetic regulation, RNA expression and inhibited the ability to differentiate into mature adipocytes or fat cells. “Reductions caused by gold nanoparticles can result in systemic changes to the body,” said Professor Mironava. “Since they have been considered inert and essentially harmless, it was assumed that pure gold nanoparticles would also be safe. Evidence to the contrary is beginning to emerge.”

The study was also the first to,

… demonstrate the impact of nanoparticles on adult stem cells, which are the cells our body uses for continual organ regeneration. It revealed that adipose derived stromal cells involved in regeneration of multiple organs, including skin, nerve, bone, and hair, ignored appropriate cues and failed to differentiate when exposed to nanoparticles. The presence of gold nanoparticles also reduced adiponectin, a protein involved in regulating glucose levels and fatty acid breakdown, which helps to regulate metabolism.

“We have learned that careful consideration and the choice of size, concentration and the duration of the clinical application of gold nanoparticles is warranted,” said Professor Mironava. “The good news is that when the nanoparticles were removed, normal functions were eventually restored.”

Here’s a link to and citation for the study,

Gold nanoparticles cellular toxicity and recovery: Adipose Derived Stromal cells by Tatsiana Mironava, Michael Hadjiargyrou, Marcia Simon, & Miriam H. Rafailovich. Nanotoxicology. Posted online on February 8, 2013. (doi:10.3109/17435390.2013.769128)

As for the aging and wrinkling, you can see the basis for the claims in the paper’s abstract,

Gold nanoparticles (AuNPs) are currently used in numerous medical applications. Herein, we describe their in vitro impact on human adipose-derived stromal cells (ADSCs) using 13 nm and 45 nm citrate-coated AuNPs. In their non-differentiated state, ADSCs were penetrated by the AuNPs and stored in vacuoles. The presence of the AuNPs in ADSCs resulted in increased population doubling times, decreased cell motility and cell-mediated collagen contraction. [emphasis mine] The degree to which the cells were impacted was a function of particle concentration, where the smaller particles required a sevenfold higher concentration to have the same effect as the larger ones. Furthermore, AuNPs reduced adipogenesis as measured by lipid droplet accumulation and adiponectin secretion. These effects correlated with transient increases in DLK1 and with relative reductions in fibronectin. Upon removal of exogenous AuNPs, cellular NP levels decreased and normal ADSC functions were restored. As adiponectin helps regulate energy metabolism, local fluctuations triggered by AuNPs can lead to systemic changes. Hence, careful choice of size, concentration and clinical application duration of AuNPs is warranted.
The researchers’ paper is behind a paywall.

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Silver nanoparticles: we love you/we hate you

Tuesday, April 16th, 2013

We seem to have a love/hate affair with silver nanoparticles. Long recognized as biocides capable of killing bacteria, silver nanoparticles are used both in hospital settings and in sports wear. As the use of silver nanoparticles increases, there are concerns about unintended consequences to the environment and to human health. An Apr. 12, 2013 news item on Nanowerk highlights some research done in Europe in 2011 (Note: Links have been removed),

As part of an EU funded project called Prosuite, Walser [Tobias Walser, researcher at the Institute for environmental engineering at the Swiss Federal Institute of Technology Zürich {ETH}] and colleagues analysed the environmental impact of nanosilver T-shirts during their entire life cycle, from raw material extraction to end-of-life disposal (“Prospective Environmental Life Cycle Assessment of Nanosilver T-Shirts”). This, according to Walser, is the first of its kind for a nanomaterial. The scientists found that the T-shirt’s environmental impact during use would be reduced if they are washed less often than conventional ones, due to their antimicrobial properties. This would even compensate for a slightly higher climate footprint during production. Walser explains: “In comparison to all toxic releases during the life cycle of a T-shirt, the toxic releases from nanosilver from washing appear to be of minor relevance.” [emphasis mine]

The Apr. 11, 2013 article by Constanze Böttcher for Youris.com, which originated the news item, expands on the theme of toxicity, nanosilver, and wastewater (Note: A link has been removed),

Previous studies looked at single impacts of antibacterial textiles. For example, scientists found that nanosilver leaches into the wastewater during washing. According to other studies, this silver may not be that harmful to the environment because it is transformed into a nearly insoluble substance called silver sulphide in wastewater treatments. A study published by the Danish Environmental Protection Agency in 2012 did not find “specific risks” to health or environmental effects of nanosilver textiles available in Denmark.

This finding contrasts with more recent research at Duke University’s CEINT (Center for Environmental Implications of Nanotechnology) mesocosm project where a study did point to adverse responses (noted in my Feb. 28, 2013 posting where I highlighted two nanosilver environmental studies, a Finnish/Estonian research project and the CEINT project),

In experiments mimicking a natural environment, Duke University researchers have demonstrated that the silver nanoparticles used in many consumer products can have an adverse effect on plants and microorganisms.

The main route by which these particles enter the environment is as a by-product of water and sewage treatment plants. [emphasis] The nanoparticles are too small to be filtered out, so they and other materials end up in the resulting “sludge,” which is then spread on the land surface as a fertilizer.

The researchers found that one of the plants studied, a common annual grass known as Microstegium vimeneum, had 32 percent less biomass in the mesocosms treated with the nanoparticles. Microbes were also affected by the nanoparticles, Colman [Benjamin Colman, a post-doctoral fellow in Duke's biology department and a member of the Center for the Environmental Implications of Nanotechnology (CEINT)] said. One enzyme associated with helping microbes deal with external stresses was 52 percent less active, while another enzyme that helps regulate processes within the cell was 27 percent less active. The overall biomass of the microbes was also 35 percent lower, he said.

As I’ve suggested before, analysing the impact that new products and materials may have on the environment and on our health is a complex process.  From Böttcher’s 2013 article (Note: Links have been removed),

Some experts are concerned about their environmental risks, however. The study “is very relevant” because it “gives a fingerprint” about the impact of such T-shirts, Anders Baun says. But the professor in risk assessment of nanomaterials at the department of environmental engineering at the Technical University of Denmark, based in Lyngby, considers it “a bad idea to distribute silver in the environment”. He points to a study that found evidence for nanosilver accumulating in the food web based on a study of plants and animals of an experimental wetland environment. Moreover, he says, it is unknown how the coating of nanosilver influences its environmental behaviour. Baun has previously criticised the European policies regarding nanosilver and is currently enrolled in a scientific committee on the topic as invited expert. The expert group will publish its opinion later this year, he says.

There’s also the possibility that bacteria will develop resistance with increased use of silver nanoparticles in medical environments and in sportswear and in other applications.

For those who want to conduct their own investigations, here’s a link to and a citation for Walser’s 2011 paper,

Prospective Environmental Life Cycle Assessment of Nanosilver T-Shirts by Tobias Walser, Evangelia Demou, Daniel J. Lang, and Stefanie Hellweg.  Environ. Sci. Technol [Environmental Science and Technology], 2011, 45 (10), pp 4570–4578 DOI: 10.1021/es2001248 Publication Date (Web): April 20, 2011
Copyright © 2011 American Chemical Society

This paper is open access.

A description of PROSUITE (PROspective SUstaInability assessment of TEchnologies project) can be found here and the PROSUITE project website can found here.

ETA Apr. 18, 2013: An Apr. 18, 2013 news item (Barely any nanosilver from consumer products in the water) on Nanowerk provides some insight into why at least one European country views the presence of silver nanoparticles in sewage sludge without any particular alarm,

The study did not examine what happens to nanosilver in the sewage sludge thereafter. In Switzerland, it is not permissible to use sewage sludge on farmland, and most of the sludge is therefore burned. [emphasis mine] The heavy metals separated in this process should not be released into the environment in large quantities.

Here’s a link to and citation for the Swiss study,

Fate and transformation of silver nanoparticles in urban wastewater systems by Ralf Kaegia, Andreas Voegelina, Christoph Orta, Brian Sinneta, Basilius Thalmanna, Jasmin Krismerb, Harald Hagendorferc, Maline Elumelua, and Elisabeth Muellerd. Water Research, http://dx.doi.org/10.1016/j.watres.2012.11.060 Available online 26 March 2013

The article is behind a paywall.

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Beginner’s guide to carbon nanotubes and nanowires

Thursday, April 11th, 2013

There’s a very nice Apr. 11, 2013  introductory article by David L. Chandler for the Massachusetts Institute of Technology (MIT) news office) about carbon and other nanotubes and nanowires,

The initial discovery of carbon nanotubes — tiny tubes of pure carbon, essentially sheets of graphene rolled up unto a cylinder — is generally credited to a paper published in 1991 by the Japanese physicist Sumio Ijima (although some forms of carbon nanotubes had been observed earlier). Almost immediately, there was an explosion of interest in this exotic form of a commonplace material. Nanowires — solid crystalline fibers, rather than hollow tubes — gained similar prominence a few years later.

Due to their extreme slenderness, both nanotubes and nanowires are essentially one-dimensional. “They are quasi-one-dimensional materials,” says MIT associate professor of materials science and engineering Silvija Gradečak: “Two of their dimensions are on the nanometer scale.” This one-dimensionality confers distinctive electrical and optical properties.

For one thing, it means that the electrons and photons within these nanowires experience “quantum confinement effects,” Gradečak says. And yet, unlike other materials that produce such quantum effects, such as quantum dots, nanowires’ length makes it possible for them to connect with other macroscopic devices and the outside world.

The structure of a nanowire is so simple that there’s no room for defects, and electrons pass through unimpeded, Gradečak explains. This sidesteps a major problem with typical crystalline semiconductors, such as those made from a wafer of silicon: There are always defects in those structures, and those defects interfere with the passage of electrons.

H/T Nanowerk Apr. 11, 2013 news item. There’s more to read at the MIT website and I recommend this as a good beginner’s piece since the focus is entirely on what carbon nanotubes and nanowires are , how they are formed, and which distinctive properties are theirs. You can find some of this information in the odd paragraph of a news release touting the latest research but I’m very excited to find this much explanatory material in one place.

Another very good explanatory piece, this one focused on carbon nanotubes and risk, is a video produced by Dr. Andrew Maynard for his Risk Bites series. I featured and embedded it in my Mar. 15, 2013 posting. titled, The long, the short, the straight, and the curved of them: all about carbon nanotubes.  You can also find the video in Andrew’s Mar. 14, 2013 posting on his 2020 Science blog where he also writes about the then recently released information from the US National Institute of Occupational Health and Safety on carbon nanotubes and toxicity.

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‘Nano fest’ at the 245th meeting of the American Chemical Society

Tuesday, April 9th, 2013

The American Chemical Society’s (ACS) 245th meeting (April 7 – 11, 2013) features a few items about nanotechnology: the funding of it and the toxicological testing of it, in two separate news items which bear a ‘political’ link.

An April 9, 2013 news item on Azonano tells of concerns regarding recent funding cuts resulting from the US budget sequestration,

Speaking at the 245th National Meeting & Exposition of the American Chemical Society, the world’s largest scientific society, A. Paul Alivisatos, Ph.D., expressed concern that the cuts come when nanotechnology is poised to deliver on those promises. He told the meeting, which continues through Thursday, that ill-conceived cuts could set back America’s progress in nanotechnology by decades.

“The National Science Foundation announced that they will issue a thousand fewer new grants this year because of sequestration,” said Alivisatos, referring to the across-the-board mandatory federal budget cuts that took effect on March 1. “What it means in practice is that an entire generation of early career scientists, some of our brightest and most promising scientists, will not have the funding to launch their careers and begin research properly, in the pathway that has established the United States as leader in nanotechnology research. It will be a setback, perhaps quite serious, for our international competitiveness in this key field.”

Alivisatos described applications of nanotechnology that can help reduce fossil fuel consumption and the accompanying emissions of carbon dioxide, the main greenhouse gas. He is professor of chemistry and materials science and the Larry and Diane Bock Professor of Nanotechnology at the University of California at Berkeley, director of the Lawrence Berkeley National Laboratory and co-editor of the ACS journal Nano Letters. …

Alivisatos expressed concern, however, that cuts in federal funding will take a heavy toll on the still-emerging field. He explained that the reductions stand to affect scientists at almost every stage of making contributions to society. Young scientists, for instance, will find it more difficult to launch research programs in new and promising fields.[emphases mine]  Established scientists will have to trim research programs, and may not have the money to explore promising new leads.

“We haven’t been able to communicate adequately with the public and policymakers, and explain the impact of what may sound like small and unimportant cuts in funding.” Alivisatos said. “A 5 percent reduction in funding — well, to the public, it seems like nothing. In reality, these cuts will be applied in ways that do maximal damage to our ability to be globally competitive in the future.”

Coincidentally or not,  the ACS had placed an Apr. 8, 2013 news release on EurekAlert highlighting some work in the field of nanotoxicology led by a ‘young’ scientist (I imagine she received her funding prior to sequestration) doing some exciting work,

Earlier efforts to determine the health and environmental effects of the nanoparticles that are finding use in hundreds of consumer products may have produced misleading results by embracing traditional toxicology tests that do not take into account the unique properties of bits of material so small that 100,000 could fit in the period at the end of this sentence.

That was among the observations presented here today at the 245th National Meeting & Exposition of the American Chemical Society (ACS), the world’s largest scientific society, by one of the emerging leaders in nanoscience research. The talk by Christy Haynes, Ph.D., was among almost 12,000 presentations at the gathering, which organizers expect to attract more than 14,000 scientists and others.

Haynes delivered the inaugural Kavli Foundation Emerging Leader in Chemistry Lecture at the meeting, … Sponsored by the Kavli Foundation, the Emerging Leaders Lectures recognize the work of outstanding young chemical scientists. [emphasis mine] …

“Christy Haynes is the perfect scientist to launch this prestigious lecture series,” said Marinda Li Wu, Ph.D., president of the ACS. “Haynes’ research is making an impact in the scientific community in efforts to use nanoparticles and nanotechnology in medicine and other fields. And that research has sparked the popular imagination, as well. Haynes was included in Popular Science‘s ‘Brilliant 10′ list, a group of ‘geniuses shaking up science today.’ [emphasis mine] We are delighted to collaborate with the Kavli Foundation in highlighting the contributions of such individuals.”

Moving on from politics to science, the EurekAlert Apr. 8, 2013 news release offers a standard discussion regarding gold and nanoparticle gold before highlighting the aspect that marks Haynes’ fresh approach to toxicity at the nanoscale,

A 1-ounce nugget of pure gold, for instance, has the same chemical and physical properties as a 2-ounce nugget or a 27-pound gold bar. For nanoparticles, however, size often dictates the physical and chemical properties, and those properties change as the size decreases.

Haynes said that some of the earlier nanotoxicology tests did not fully take those and other factors into account when evaluating the effects of nanoparticles. In some cases, for instance, the bottom line in those tests was whether cells growing in laboratory cultures lived or died after exposure to a nanoparticle.

“While these results can be useful, there are two important limitations,” Haynes explained. “A cell can be alive but unable to function properly, and it would not be apparent in those tests. In addition, the nature of nanoparticles — they’re more highly reactive — can cause ‘false positives’ in these assays.”

Haynes described a new approach used in her team’s work in evaluating the toxicity of nanoparticles. It focuses on monitoring how exposure to nanoparticles affects a cell’s ability to function normally, rather than just its ability to survive the exposure. In addition, they have implemented measures to reduce “false-positive” test results, which overestimate nanoparticle toxicity. One of the team’s safety tests, for instance, determines whether key cells in the immune system can still work normally after exposure to nanoparticles. In another, the scientists determine whether bacteria exposed to nanoparticles can still communicate with each other, engaging in the critical biochemical chatter that enables bacteria to form biofilms, communities essential for them to multiply in ways that lead to infections.

“So far, we have found that nanoparticles made of silver or titanium may be the most problematic, though I would say that neither is as bad as some of the alarmist media speculations, especially when they are stabilized appropriately,” said Haynes. “I think that it will be possible to create safe, stable coatings on nanoparticles that will make them stable and allow them to leave the body appropriately. We need more research, of course, in order to make informed decisions.”

Hopefully, you find this mixture of science and politics as interesting as I do.

ETA Apr. 10, 2013: Dexter Johnson has commented on and provided some contextual information about nanotechnology research funding in the US in response to the Alivisatos talk about sequestration and its possible impact on nanotechnology research in Apr. 9, 2013 posting (Note: A link has been removed),

There is always room for the argument that reassessing and reallocating resources can help make nanotechnology more efficient and productive, something observers have pointed out in NASA taking on less of its own nanotechnology research and outsourcing it to other government organizations. But it’s not always easy to tell which fundamental research projects will turn out to have been the most productive, and worse, the timing of these cuts could be extremely painful as they occur at a critical moment for U.S. nanotechnology.

Dexter’s piece is well worth reading.

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Safe Work Australia’s two new reports, Europe’s Nanodevice project, and the UK’s HSE nanomaterials handling

Monday, April 1st, 2013

Over the last few weeks in March (2013), there was a sudden burst of health and safety reports and initiatives released by Safe Work Australia, the European Commission’s Nanodevice project, and the UK’s Health and Safety Executive, respectively.

According to a Mar. 19, 2013 news item on Nanowerk, Safe Work Australia released two reports (Note: Links have been removed),

Safe Work Australia Chair Ann Sherry AO today released two research reports examining nanotechnology work health and safety issues.

The reports: Investigating the emissions of nanomaterials from composites and other solid articles during machining process and Evaluation of potential safety (physicochemical) hazards associated with the use of engineered nanomaterials are part of a comprehensive program of work on nanotechnology safety managed by Safe Work Australia which started in 2007.

The March 18, 2013 Safe Work Australia media release, which originated the news item,  provides some information about the approaches and models being used to analyse and develop policies,

In releasing the reports Ms Sherry noted the perceived safety risks of nanomaterials and that a precautionary approach is being taken by the Commonwealth towards nanomaterials under the National Enabling Technologies Strategy.“

While the risk to human health and safety from a number of these materials and applications is low some nanomaterials are potentially more hazardous, for example carbon nanotubes,” Ms Sherry said.

“The National Industrial Chemicals Notification and Assessment Scheme (NICNAS) has recommended carbon nanotubes be classified as suspected carcinogens unless product-specific evidence suggests otherwise.”

Under the model Work Health and Safety (WHS) laws all duties which apply to the handling of materials and to technologies in general also apply to nanomaterials and nanotechnologies. Minimisation of exposure to nanomaterials at work is essential until there is sufficient data to rule out hazardous properties. Research has shown if conventional engineering controls are designed and maintained effectively, exposure to nanomaterials can be significantly reduced.

As a result of the findings of these reports Safe Work Australia will prepare guidance material on combustible dust hazards including nanomaterials.

Here’s more about the reports (from their respective webpages),

Investigating the emissions of nanomaterials from composites and other solid articles during machining processes

This report by CSIRO considers the potential health risk of emissions from machining processes.

The report finds that significant quantities of material, which can present health risk, are emitted from composites by high energy machining processes like cutting with an electric disc saw or band saw. If the composite contains a hazardous nanomaterial, the health risk from the dust may be higher. Lower energy processes like manual cutting will result in lower exposures and lower potential health risk.

Evaluation of potential safety hazards associated with the use of engineered nanomaterials

This report by Toxikos Pty Ltd examines safety hazards associated with engineered nanomaterials and the implications in regard to workers safety.

The report finds that dust clouds of some engineered nanomaterials could give rise to strong explosions if the dust cloud contains a high enough concentration of nanomaterials and if an ignition source is also present. The report gives examples of these. However in a well-managed workplace, emissions from nanotechnology processes will be very significantly below the minimum dust concentration needed for an explosion.

A Mar. 20, 2013 news item on Nanowerk focused on the European Commission’s Nanodevice project,

European researchers in the Nanodevice project are investigating the safety aspects of nanomaterial production. Their plan laid down in 2009 was to develop new concepts, reliable methods and portable devices for detecting, analysing and monitoring airborne ENMs in the workplace. The latest feedback from the team suggests the project has delivered on its promise.

The project has concluded work on seven new ‘nanodevices’, which have been calibrated and tested for use in work environments exposed to nanoparticles. This work, alongside findings from materials studies and research into the association between ENM properties and their biological impacts, will appear in a new nanosafety handbook, called “Safe handling of manufactured nanomaterials: particle measurement exposure assessment and risk management”.

Complex research like this calls for an integrated, multidisciplinary approach,” confirms Nanodevice’s project leader, Dr Kai Savolainen of the Finnish Institute of Occupational Health.

What makes this particular health and safety project special is the focus on affordable monitoring for small and medium-size companies,

With affordable, portable equipment, even small companies can regularly measure their workers’ exposure to potentially harmful particles. When compared with a growing body of data from other workplaces, a more accurate assessment of risk and occupational health and safety emerges.

Prior to Nanodevice’s portable solutions, regular nanosafety checks could cost up to €200 000. The instrumentation hauled in from outside weighed hundreds of kilos and needed several experts to gather and analyse data from multiple sites. Big companies could afford this, but Europe’s important SME sector struggled with the cost.

“We’ve developed devices like a personal nanoparticle monitor for less than €200 that almost any company can afford and quickly learn to use,” says Dr Savolainen. Worn by a worker, the system collects exposure information, but needs to be plugged into a computer to download the data. This is not ideal, so Nanodevice is keen to develop this into a real-time sensing and monitoring device linked to the internet and databases.

“Today, lack of ‘big’ accurate data makes it hard to know if exposure values are too low,” explains Dr Savolainen, “so our work helps the scientific community build a large database on exposure levels in the working environment.” This means companies, regulators and stakeholders will have access to reliable information from which to base risk-assessment decisions and develop standards for occupational exposure levels for different types of ENMs.

“Thanks to our work, the ‘big picture’ is that people won’t have to be concerned about lack of information on exposure levels. This reduces uncertainty about ENM safety and fosters more innovation in nanosciences in general,” he concludes.

You can find out more about the Nanodevice project here.

Finally, the UK’s Health and Safety Executive released a guidance (I think we’d call them guidelines here in Canada) according to a Mar. 28, 2013 news item on Nanowerk (Note: A link has been removed),

The UK’s Health and Safety Executive (HSE) has released a new guidance (“Using nanomaterials at work”; pdf)that describes how to control occupational exposure to manufactured nanomaterials in the workplace. It will help you understand what you need to do to comply with the Control of Substances Hazardous to Health Regulations 2002 (COSHH) (as amended) when you work with these substances.

There’s more information about the guidance on the Using nanomaterials at work webpage where you can also find the document,

If you work with nanomaterials this guidance will help you protect your employees. If you run a medium-sized or large business, where decisions about controlling hazardous substances are more complex, you may also need professional advice. This guidance will also be useful for trade union and employee health and safety representatives.

This guidance is specifically about the manufacture and manipulation of all manufactured nanomaterials, carbon nanotubes (CNTs) and other bio-persistent high aspect ratio nanomaterials (HARNs). It has been prepared in response to emerging evidence about the toxicity of these materials.

The control principles described can be applied to all nanomaterials used in the workplace. Any differences in the approach between control of CNTs and other bio-persistent HARNs to any other type of nanomaterials are highlighted in the text.

For anyone who wants a direct link to the guidance, go here.

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Nanoparticle emissions from electronic cigarettes

Thursday, March 28th, 2013

Electronic cigarettes may be safer but that doesn’t mean they’re 100% safe according to a Mar. 28, 2013 news item on Nanowerk (Note: Links removed),

Electronic cigarettes (EC) deliver aerosol by heating fluid containing nicotine. Cartomizer EC combine the fluid chamber and heating element in a single unit. Because EC do not burn tobacco, they may be safer than conventional cigarettes. Their use is rapidly increasing worldwide with little prior testing of their aerosol.

A new study led by Prue Talbot, Professor of Cell Biology at the University of California, Riverside, and Director, UCR Stem Cell Center and Stem Cell Core Facility, tested the hypothesis that EC aerosol contains metals derived from various components in EC (“Metal and Silicate Particles Including Nanoparticles Are Present in Electronic Cigarette Cartomizer Fluid and Aerosol”).

The article (open access) can be found here,

Citation: Williams M, Villarreal A, Bozhilov K, Lin S, Talbot P (2013) Metal and Silicate Particles Including Nanoparticles Are Present in Electronic Cigarette Cartomizer Fluid and Aerosol. PLoS ONE 8(3): e57987. doi:10.1371/journal.pone.0057987

Here’s a preview of the technical detail and the conclusion from the article’s abstract,

The filament, a nickel-chromium wire, was coupled to a thicker copper wire coated with silver. The silver coating was sometimes missing. Four tin solder joints attached the wires to each other and coupled the copper/silver wire to the air tube and mouthpiece. All cartomizers had evidence of use before packaging (burn spots on the fibers and electrophoretic movement of fluid in the fibers). Fibers in two cartomizers had green deposits that contained copper. Centrifugation of the fibers produced large pellets containing tin. Tin particles and tin whiskers were identified in cartridge fluid and outer fibers. Cartomizer fluid with tin particles was cytotoxic in assays using human pulmonary fibroblasts. The aerosol contained particles >1 µm comprised of tin, silver, iron, nickel, aluminum, and silicate and nanoparticles (<100 nm) of tin, chromium and nickel. The concentrations of nine of eleven elements in EC aerosol were higher than or equal to the corresponding concentrations in conventional cigarette smoke. Many of the elements identified in EC aerosol are known to cause respiratory distress and disease.

The presence of metal and silicate particles in cartomizer aerosol demonstrates the need for improved quality control in EC design and manufacture and studies on how EC aerosol impacts the health of users and bystanders.

I don’t know about anyone else but I’m going to be more careful about where I stand when my friends are smoking electronic cigarettes.

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