March 14, 2014
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Classifying human neurotoxins can be tricky. While
laboratory research has identified more than 1,000 chemicals to be
animal neurotoxins, the known list for humans is small by comparison.
Only 214 chemicals have been classified as human neurotoxins, and only
12 have been identified as impacting fetal and child development.
So
why is it that only a fifth of the known animal neurotoxins are
identified as posing risks to humans? Even more worrisome, why are only
1% identified as hazardous to infants and fetuses? The reason lies in
the ethical and practical considerations of scientific research: You
can't study toxicity on humans by feeding people arsenic and comparing
their levels of brain damage with a control group. So no authoritative
top 10 list of the deadliest neurotoxins is possible. We're in the
dark.
Still, a new
study
out of Denmark argues that while human neurotoxins can be clearly
identified when people who are exposed to them later become ill, it's
not so easy to show whether or not small amounts of chemical exposure
may have impacts on developing fetuses and infants, and what those
affects may be. Or as David P. Rall, the former director of the National
Institute of Environmental Health Sciences, who is quoted in the study,
says: “If thalidomide had caused a ten-point loss of intelligence
quotient (IQ) instead of obvious birth defects of the limbs, it would
probably still be on the market."
So, the study points
out, we often do not know which chemicals can cause lost IQ points or
other developmental problems in children. However, research has
identified more developmental neurotoxicants in recent years — doubling
the list since 2006 — as scientists do what are called “epidemiological
birth cohort studies.”
These studies examine exposure
levels of chemicals to fetuses and infants, while comparing growth and
development of the children over time. This helps show the chemicals
that may cause problems, but the method is not perfect. As individuals,
we're all exposed to our own unique cocktail of potentially toxic
chemicals over time, and how they may impact us may vary based on many
factors.
Still, it can also be assumed the more
comprehensive lists of known animal and human neurotoxins will likely
have impacts to fetuses. And prenatal exposure to many of these
chemicals is common, at least at low levels; more than 200 foreign
chemicals have been identified in umbilical cord blood.
Moreover,
the study notes that known human neurotoxins are not at all rare: About
half are widely used and disseminated around the world, and they
include pesticides, organic solvents, metals, and other compounds.
Even
if developmental toxicity can be measured in lost IQ points during
childhood, the researchers also question impacts of chemicals later in
life. Could in-utero exposure increase the chance of developing
neurodegenerative diseases like dementia? And if the effects do not show
up until a person’s sixth or seventh decade, will we continue to expose
future generations to chemicals until we can confirm their toxicity
decades from now?
Questions like these motivate Jeff Gearhart, research director at the Ecology Center. His organization's research website,
HealthyStuff.org
tests common consumer products and then reports the results to
consumers—but also works with manufacturers to make products safer in
the future.
Gearhart says the chemicals
listed in the Danish study are the ones commonly identified as
neurotoxins, but says there is a larger universe of chemicals used in
consumer products that might pose health risks. So while we all have the
common understanding that lead should not be used in consumer products,
there is a considerable amount of concern about many of the chemicals
used in common products,
particularly in plastics.
Yet
Gearhart still finds well-known neurotoxins like lead in the consumer
products he tests. He notes that while we still had a significant
problem with lead in toys only a decade ago, it took public outrage and
federal regulations like the Consumer Product Safety Improvement Act to
greatly reduce the number of toys with lead in them. Today, says
Gearhart, only 2-3% of products they test have lead in them, a
significant reduction.
But the products Gearhart still
finds lead in may surprise you. His organization recently found lead in a
pair of infant shoes, and found dangerous levels of lead, other toxic
metals and toxic flame retardants in
Mardis Gras beads.
In
these enlightened times, how is it that we're still finding lead in
common consumer products? Gearhart says chunks of waste electronics,
which contain hazardous compounds, are being recycled, shredded and
finding their way back into consumer products. In Mardis Gras beads,
this toxic recycled material is used as filler.
When
lead and other chemicals pop up in seemingly random ways like this,
danger could lurk around any corner—or in any product. So what's the fix
for this problem? Gearhart calls for a systemic approach to fix our
problems.
“Our public policy on how we regulate
chemicals in our material economy is not proactive,” says Gearhart, so
we should come to expect lead to show up in seemingly random places. “We
don't have a comprehensive way to have public policy around chemistries
going into commerce. As a result, why should you be surprised about
things popping up where they shouldn't be?”
“We have the
right tools in place, we can actually change things. But the key thing
is that we have to bring that systems approach to that," says Gearhart.
The
current status quo is to react to chemicals in products when they're
identified to be hazardous. For example, BPA (bisphenol A), a compound
found in plastic bottles was found toxic, many manufacturers switched to
a different "safer" plastic, Tritan, now suspected of posing health
risks. Gearhart says were "jumping from one hazard into another."
Gearhart
is proposing a systemic approach to thoroughly test chemicals before
using them in consumer products. He believes that this would give the
most protection to consumers.
Even pesticides, compounds
created solely for their toxic properties, are not thoroughly tested
before commercial use as they should. There are legal loopholes in place
that allow for them to be tested after they're put on the market.
Most
other chemicals are regulated under the Toxic Substances Control Act.
But the TSCA, which is four decades old, grandfathers in the chemicals
on the market before its implementation, and gives the government very
little leeway to stop new chemicals from entering the market or removing
them after they're already there.
Gearhart works
directly with retailers and manufacturers to put safer products on the
market and has found success using this approach.
“It's
leap-frogging where we are in terms of policy,” Gearhart says. Companies
are evolving from a chemical-by-chemical approach to product safety and
are now using a systems-oriented approach. For example, a company is
using flammable polyurethane foam in a product that requires them to use
a chemical flame retardant, they might consider using a less flammable
alternative to polyurethane to avoid the need for flame retardants.
But
Gearhart admits that appealing to retailers and manufacturers has its
limits. “We've got to have the policy piece in place to make the whole
market change, particularly the international component,” he says.
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