Heavy Metals
Heavy Metals
Introduction
The term heavy
metal refers to any metallic chemical element that has a relatively high
density and is toxic or poisonous at low concentrations. Examples of heavy
metals include mercury(Hg), cadmium(Cd), arsenic(As), chromium(Cr),
thallium(Tl), and lead(Pb).
Heavy metals are
natural components of the Earth's crust. They cannot be degraded or destroyed.
To a small extent they enter our bodies via food, drinking water and air. As
trace elements, some heavy metals (e.g. copper, selenium, zinc) are essential
to maintain the metabolism of the human body. However, at higher concentrations
they can lead to poisoning. Heavy metal poisoning could result, for instance,
from drinking-water contamination (e.g. lead pipes), high ambient air
concentrations near emission sources, or intake via the food chain.
Heavy metals are
dangerous because they tend to bioaccumulate. Bioaccumulation means an increase
in the concentration of a chemical in a biological organism over time, compared
to the chemical's concentration in the environment. Compounds accumulate in
living things any time they are taken up and stored faster than they are broken
down (metabolized) or excreted.
Heavy metals can
enter a water supply by industrial and consumer waste, or even from acidic rain
breaking down soils and releasing heavy metals into streams, lakes, rivers, and
groundwater.
Environmental and
health risks.
Now we are going to
describe the effects of the heavy metals in the environment. The three most
pollutans heavy metals are Lead, Cadmium, and Mercury.
Effects of Antimony
on the environment
Antimony is a metal
used in the compound antimony trioxide, a flame retardant. It can also be found
in batteries, pigments, and ceramics and glass. Exposure to high levels of
antimony for short periods of time causes nausea, vomiting, and diarrhea. There
is little information on the effects of long-term antimony exposure, but it is
a suspected human carcinogen. Most antimony compounds do not bioaccumulate in
aquatic life.
Effects of Cadmium
on the environment
Cadmium derives its
toxicological properties from its chemical similarity to zinc an essential
micronutrient for plants, animals and humans. Cadmium is biopersistent and,
once absorbed by an organism, remains resident for many years (over decades for
humans) although it is eventually excreted.
In humans,
long-term exposure is associated with renal disfunction. High exposure can lead
to obstructive lung disease and has been linked to lung cancer, although data
concerning the latter are difficult to interpret due to compounding factors.
Cadmium may also produce bone defects (osteomalacia, osteoporosis) in humans
and animals. In addition, the metal can be linked to increased blood pressure
and effects on the myocardium in animals, although most human data do not
support these findings.
The average daily
intake for humans is estimated as 0.15µg from air and 1µg from water. Smoking a
packet of 20 cigarettes can lead to the inhalation of around 2-4µg of cadmium,
but levels may vary widely.
In what form is
emitted Cadmium?
Cadmium is produced
as an inevitable by-product of zinc (or occasionally lead) refining, since
these metals occur naturally within the raw ore. However, once collected the
cadmium is relatively easy to recycle.
The most
significant use of cadmium is in nickel/cadmium batteries, as rechargeable or
secondary power sources exhibiting high output, long life, low maintenance and
high tolerance to physical and electrical stress. Cadmium coatings provide good
corrosion resistance, particularly in high stress environments such as marine
and aerospace applications where high safety or reliability is required; the
coating is preferentially corroded if damaged. Other uses of cadmium are as
pigments, stabilisers for PVC, in alloys and electronic compounds. Cadmium is
also present as an impurity in several products, including phosphate
fertilisers, detergents and refined petroleum products.
In the general,
non-smoking population the major exposure pathway is through food, via the
addition of cadmium to agricultural soil from various sources (atmospheric
deposition and fertiliser application) and uptake by food and fodder crops.
Additional exposure to humans arises through cadmium in ambient air and
drinking water.
Effects of Chromium
on the environment
Chromium is used in
metal alloys and pigments for paints, cement, paper, rubber, and other
materials. Low-level exposure can irritate the skin and cause ulceration.
Long-term exposure can cause kidney and liver damage, and damage too
circulatory and nerve tissue. Chromium often accumulates in aquatic life,
adding to the danger of eating fish that may have been exposed to high levels
of chromium.
Effects of Copper
on the environment
Copper is an
essential substance to human life, but in high doses it can cause anemia, liver
and kidney damage, and stomach and intestinal irritation. People with Wilson's
disease are at greater risk for health effects from overexposure to copper.
Copper normally occurs in drinking water from copper pipes, as well as from
additives designed to control algal growth.
Effects of Lead on
the environment
In humans exposure
to lead can result in a wide range of biological effects depending on the level
and duration of exposure. Various effects occur over a broad range of doses,
with the developing foetus and infant being more sensitive than the adult. High
levels of exposure may result in toxic biochemical effects in humans which in
turn cause problems in the synthesis of haemoglobin, effects on the kidneys,
gastrointestinal tract, joints and reproductive system, and acute or chronic
damage to the nervous system.
Lead poisoning,
which is so severe as to cause evident illness, is now very rare indeed. At
intermediate concentrations, however, there is persuasive evidence that lead
can have small, subtle, subclinical effects, particularly on neuropsychological
developments in children. Some studies suggest that there may be a loss of up
to 2 IQ points for a rise in blood leadlevels from 10 to 20µg/dl in young
children.
Average daily lead
intake for adults in the UK is estimated at 1.6µg from air, 20µg from drinking
water and 28µg from food. Although most people receive the bulk of their lead
intake from food, in specific populations other sources may be more important,
such as water in areas with lead piping and plumbosolvent water, air near point
of source emissions, soil, dust, paint flakes in old houses or contaminated
land. Lead in the air contributes to lead levels in food through deposition of
dust and rain containing the metal, on crops and the soil. For the majority of
people in the UK, however, dietary lead exposure is well below the provisional
tolerable weekly intake recommended by the UN Food and Agriculture Organisation
and the World Health Organisation.
In what form is
emitted lead?
Lead in the
environment arises from both natural and anthropogenic sources. Exposure can
occur through drinking water, food, air, soil and dust from old paint
containing lead. In the general non-smoking, adult population the major
exposure pathway is from food and water. Food, air, water and dust/soil are the
major potential exposure pathways for infants and young children. For infants
up to 4 or 5 months of age, air, milk formulae and water are the significant
sources.
Lead is among the
most recycled non-ferrous metals and its secondary production has therefore
grown steadily in spite of declining lead prices. Its physical and chemical
properties are applied in the manufacturing, construction and chemical
industries. It is easily shaped and is malleable and ductile. There are eight
broad categories of use: batteries, petrol additives (no longer allowed in the
EU), rolled and extruded products, alloys, pigments and compounds, cable
sheathing, shot and ammunition.
Effects of Mercury
on the environment
Mercury is a toxic
substance which has no known function in human biochemistry or physiology and
does not occur naturally in living organisms. Inorganic mercury poisoning is
associated with tremors, gingivitis and/or minor psychological changes,
together with spontaneous abortion and congenital malformation.
Monomethylmercury
causes damage to the brain and the central nervous system, while foetal and
postnatal exposure have given rise to abortion, congenital malformation and
development changes in young children.
In what form is
emitted Mercury?
Mercury is a global
pollutant with complex and unusual chemical and physical properties. The major
natural source of mercury is the degassing of the Earth’s crust, emissions from
volcanoes and evaporation from natural bodies of water.
World-wide mining
of the metal leads to indirect discharges into the atmosphere. The usage of
mercury is widespread in industrial processes and in various products (e.g.
batteries, lamps and thermometers). It is also widely used in dentistry as an
amalgam for fillings and by the pharmaceutical industry. Concern over mercury
in the environment arises from the extremely toxic forms in which mercury can
occur.
Mercury is mostly
present in the atmosphere in a relatively unreactive form as a gaseous element.
The long atmospheric lifetime (of the order of 1 year) of its gaseous form
means the emission, transport and deposition of mercury is a global issue.
Natural biological
processes can cause methylated forms of mercury to form which bioaccumulate over
a million-fold and concentrate in living organisms, especially fish. These
forms of mercury: monomethylmercury and dimethylmercury are highly toxic,
causing neurotoxicological disorders. The main pathway for mercury to humans is
through the food chain and not by inhalation.
The main sources of
mercury emissions in the UK are from the manufacture of chlorine in mercury
cells, non-ferrous metal production, coal combustion and crematoria. UK
emissions of mercury are uncertain and it is estimated that the range is from
13 to 36 tonnes per year (DERA). Emissions are estimated to have declined by
around ѕ’s between 1970-1998 (NAEI),
mainly due to improved controls on mercury cells and their replacement, and the
fall in coal use.
Whilst there has
been a decline in the level of European emissions of mercury, emissions from
outside of Europe have started to increase – increasing the level of ambient
concentrations in the continent.
Effects of Nickel
on the environment
Small amounts of
Nickel are needed by the human body to produce red blood cells, however, in
excessive amounts, can become mildly toxic. Short-term overexposure to nickel
is not known to cause any health problems, but long-term exposure can cause
decreased body weight, heart and liver damage, and skin irritation. The EPA
does not currently regulate nickel levels in drinking water. Nickel can
accumulate in aquatic life, but its presence is not magnified along food
chains.
Effects of Selenium
on the environment
Selenium is needed
by humans and other animals in small amounts, but in larger amounts can cause
damage to the nervous system, fatigue, and irritability. Selenium accumulates
in living tissue, causing high selenium content in fish and other organisms,
and causing greater health problems in human over a lifetime of overexposure.
These health problems include hair and fingernail loss, damage to kidney and
liver tissue, damage to circulatory tissue, and more severe damage to the
nervous system.
Список литературы
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