Nanotechnology, like genetically modified food or nuclear power,
often produces a knee-jerk reaction. It’s somehow ‘not natural’ and so
is considered scary and dangerous. This is primarily a reaction to
words, the same way that it easy for advertisers to push emotional
buttons with ‘natural’ as good and ‘artificial’ as bad.
This is a silly distinction. There is a lot in nature that is very
dangerous indeed – and much that is artificial protects us from that. If
you doubt this, try removing everything artificial when you are flying
in a plane over shark infested waters. For that matter, many of the most
virulent poisons like ricin and botulinus toxin are natural. Water
crammed with bacteria and faecal matter is natural. Clean, safe drinking
water from a tap is artificial. Yet we can’t help reacting like puppets
when the advertisers use those magic words.
Some concerns about nanotechnology are down to what is at best
futurology and at worst science fiction. Prince Charles infamously
caused headlines back in 2003, when newspapers reported ‘The prince has
raised the spectre of the “grey goo” catastrophe in which
sub-microscopic machines designed to share intelligence and replicate
themselves take over and devour the planet.’
Charles later denied ever meaning this, commenting that he never used
the expression ‘grey goo’ and saying ‘I do not believe that
self-replicating robots, smaller than viruses, will one day multiply
uncontrollably and devour our planet. Such beliefs should be left where
they belong, in the realms of science fiction.’ But he certainly did
express concerns that not enough was being done to assess and manage any
risk associated with the use of nanotechnology.
Unlike the grey goo headlines, this is a perfectly reasonable
attitude. The very nature of nanotechnology implies using substances in
physical formats that our bodies might not have encountered, and hence
we can’t make assumptions without appropriate testing and risk
assessment.
If we are to be sensible about this, we need to first avoid a blanket
response to nanotechnology. You would be hard pressed to find a reason
for being worried about the impact of nanometer thin coatings, such as
that used by P2i (sponsors of the Nature’s Nanotech
series) There is a big difference between manipulating coatings at the
nanoscale and manufacturing products with nanoparticles and small
nanotubes.
We know that breathing in nanoparticles, like those found in soot in
the air, can increase risk of lung disease, and there is no reason to
think that manufactured nanoparticles would be any less dangerous than
the natural versions. When some while ago the Soil Association banned
artificial nanoparticles from products they endorsed, I asked them why
only artificial particles. Their spokesperson said that natural ones are
fine because ‘life evolved with these.’
This, unfortunately, is rubbish. You might as well argue it is okay
to put natural salmonella into food because ‘life evolved with it.’ Life
also evolved with cliffs, but it doesn’t make falling off them any less
dangerous. There is no magic distinction between a natural and an
artificial substance when it comes to chemical makeup, and in practice
if there is risk from nanoparticles it is likely to be from the physics
of their very small size, rather than anything about their chemistry.
There are three primary concerns about nanoparticles – what will
happen if we breathe them, eat them and put them on our skin. The
breathing aspect is probably the best understand and is already strongly
legislated on in the UK – we know that particulates in the air can
cause a range of diseases and have to be avoided. There is really no
difference here between the need to control nanoparticles and any other
particles and fibres we might breathe. Whenever a process throws
particulates into the air it ought to be controlled. (And this applies
to the ‘natural’ smoke from wood fires, say, which is high in dangerous
particulates, as well as any industrial process.)
When it comes to food, we have good coverage from The House of Lords
Science and Technology committee in a 2010 report. They point out that
nanotechnologies have a range of possible applications in food that
could benefit both consumers and industry. ‘These include creating foods
with unaltered taste but lower fat, salt or sugar levels, or improved
packaging that keeps food fresher for longer or tells consumers if the
food inside is spoiled.’
The committee’s report sensibly argued ‘Our current understanding of
how [nanoparticles] behave in the human body is not yet advanced enough
to predict with any certainty what kind of impact specific nanomaterials
may have on human health. Persistent nanomaterials are of particular
concern, since they do not break down in the stomach and may have the
potential to leave the gut, travel throughout the body, and accumulate
in cells with long-term effects that cannot yet be determined.’
Their recommendation was not to abandon these technologies, but
rather that it was essential to perform appropriate research, preferably
across the EU, to check the impact of such nanomaterials when consumed,
and to ensure that all such materials that interact differently with
the body from ordinary foodstuffs are assessed for risk before they are
allowed onto the market. This seems eminently sensible.
The
final area, applying nanoparticles to the skin, is perhaps most urgent,
because most of apply them on a regular basis. Most sun defence
products, and a number of cosmetics contain them. It is hard to find a
good reason to allow for any risk in a pure cosmetic, and arguably they
should be prevented from containing nanoparticles. But the story is more
nuanced with sun creams.
Most sunscreens contain particles of titanium dioxide or zinc oxide.
These invisible particles, ranging from nanoscale to significantly
larger, provide most of the sunscreen’s protection against dangerous
ultraviolet. What has to be weighed up is the benefits of using products
to prevent a cancer that kills over 65,000 people a year worldwide –
and would kill many more if sunscreens weren’t used – against a risk
that has not been associated with any known deaths.
The
potential for these nanoparticles to cause harm depends on them
penetrating through the outer layers of the skin to reach cells where
they could cause damage. In theory a nanoparticle is capable of doing
this. But the current evidence is that the particles remain on the
surface of the skin and do not reach viable skin cells. Skin cancer is a
particular risk in Australia, so this is a topic that has been studied
in depth there. As Cancer Council Australia concludes: ‘there is no
credible evidence that sunscreens containing nanoparticles pose a health
risk. There is plenty of evidence however, proving that sunscreen can
help reduce the risk of skin cancer, in particular non-melanoma skin
cancer.’
Overall, then, we should not be lax about nanoparticles and their
effect on our bodies. We need careful testing and where necessary
regulation. But equally we should not be swayed into knee-jerk reactions
by emotional words carrying little meaning.
Written by Brian Clegg - Popular Science
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