Lectuire 4 Heavy Metals &Lead.pdf

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ENVIRONMENTAL &
INDUSTRIAL TOXINS PART II
Dr. Abdullah Alnuqaydan
Associate Professor & Consultant of Toxicology
ami.alnuqaydan @ qu.edu.sa

2 . Industrial Toxins
I. 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).
• Lead (Pb) (from the Latin plumbum)

Introduction
• 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.

Mode of action
• 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.

 The most pollutants of heavy metals are:
Lead, Arsenic, Cadmium, and Mercury.
Arsenic Lead Mercury

Lead Poisoning

• Lead poisoning is one of the
oldest occupational and
environmental diseases in the
world.
• Environmental lead exposure,
ubiquitous by virtue of the
anthropogenic distribution of
lead to air, water and food, has
declined considerably due to
diminished use of lead in
gasoline and other applications.

Sources of Exposure

Sources of Exposure
 Soil and dust
 Paint chips
 Contaminated water
 Parents lead -related
occupation
 Folk remedies
 Household plumbing.

Health Effects
• Lead serves no useful purpose in the human body.
• Lead is slowly but consistently absorbed via the respiratory and
gastrointestinal tracts.
• Inorganic lead is poorly absorbed through the skin absorption via the GIT
varies with the nature of the lead compound, but in general, adults absorb
about 10% of the ingested amount while young children absorb closer to
50%.
• The daily lead consumption is about 300μg. It is unsafe if consumed at a
concentration greater than 0.5 mg/day for 3 months or more.
• Once absorbed from the respiratory or GIT, lead is bound to erythrocytes
and widely distributed initially to soft tissues, then to the subperiosteal
surface of bone and bone matrix.

Health Effects

Health Effects
• It has a half life of 2 -3 weeks in blood and 15 years in bone.
• More than 90 % of the lead that is eliminated appears in the urine
 Lead exerts multi systemic toxic effects through at least three
mechanisms by;
• Inhibiting enzyme activity.
• Interfering with the action of essential cations, particularly calcium, iron,
and zinc.
• Altering the structure of cell membranes and receptors.
• increased fragility and decreased survival time due to interference of
sodium -potassium pump.

Lead Paint
 The use of lead in residential paint was banned in 1977
 Lead -containing pigments still are used for outdoor paint
products because of their bright colors and weather resistant
properties
 Tetraethyl and tetramethyl lead are still used as additives in
gasoline in several countries

Toxicokinetics and Toxicodynamics of lead toxicity
 Absorption:
 Lungs: depends on size particle
 GI:
 Adults: 20 -30%
 Children: as much as 50% of dietary lead
 Inadequate intake of iron, calcium, and total calories are
associated with higher lead levels
 Skin:
 Inorganic lead is not absorbed
 Organic lead is well absorbed
 Lead is carried bound to the RBC

Pharmacokinetics and Pharmacoynamics
 Distributed extensively throughout tissues: bone,
teeth, liver, lung, kidney, brain, and spleen

Toxicokinetics and Toxicodynamics of lead toxicity
 Body lead storage: bones - can constitute a source of
remobilization and continued toxicity after the exposure
has ceased
 Lead crosses the blood brain barrier (BBB) and
concentrates in the gray matter
 Lead crosses the placenta
 Excretion:
 Kidneys. The excretion increases with increasing body
stores ( 30  g -200  g/day)
 Feces

Clinical Manifestation
 Acute toxicity
 Acute encephalopathy, renal failure and severe GI
symptoms

Chronic and Long Term Toxicity -
Pathophysiology
 Lead has affinity for SH groups and is toxic to zinc -dependent
enzyme systems
 Heme synthesis: hemoglobin, cytochromes
 Steroid metabolism and membrane integrity
 Interference in vitamin D synthesis in renal tubular cells (conversion of
1 -hydroxyvitamin D to 1,25 -hydroxyvitamin D)

General Signs and Symptoms of Lead Toxicity
 Fatigue
 Irritability
 Lethargy
 Paresthesis
 Myalgias
 Abdominal pain
 Tremor
 Headache
 Vomiting
 Weight loss
 Constipation
 Loss of libido
 Motor neuropathy
 Encephalopathy
 Cerebral edema
 Seizures
 Coma
 Severe abdominal
cramping
 Epiphyseal lead lines in
children (growth arrest)
 Renal failure

General Signs and Symptoms of Lead Toxicity
Lead poisoning symptoms in newborns
Babies exposed to lead before birth might:
•Be born prematurely
•Have lower birth weight
•Have slowed growth

Blood lead
levels
Adults Children
10 g/dL Hypertension may occur •Crosses placenta
•Impairment IQ, growth
•Partial inhibition of heme
synthesis
20 g/dL Inhibition of heme synthesis
Increased erythrocyte
protoporphyrin
Beginning impairment of nerve
conduction velocity
30 g/dL •Systolic hypertension
•Impaired hearing( )
Impaired vitamin D metabolism
40 g/dL •Infertility in males
•Renal effects
•Neuropathy
•Fatigue, headache, abd pain
Hemoglobin synthesis inhibition
50 g/dL Anemia, GI sx, headache,
tremor
Colicky abd pain, neuropathy
100 g/dL Lethargy, seizures,
encephalopathy
Encephalopathy, anemia,
nephropathy, seizures
Range of Lead - induced Health
Effects in Adults and Children

Childhood Lead Poisoning
 Childhood lead poisoning is now defined as a
blood lead level of 10  g/dl

 The average lead level of American children is 2
 g/dl
 8.9% of American children have lead poisoning
 Lead intoxication is more prevalent in minority
groups and among those living in the northeast

Neurotoxicity of Lead in Childhood
 Mental retardation in severe lead intoxication
  5 points in IQ for every 10  g/dl  in blood lead level -
population based studies
 Other adverse developmental outcomes:
 Aggression
 Hyperactivity
 Antisocial behaviors
 Learning disability - impairment in memory, auditory processing, and
visual -motor integration. The IQ is normal. These effects has been
demonstrated with blood lead levels as low as 6  g/dl

Diagnosis
 Evaluation of clinical symptoms and signs
 CBC
 Serum iron levels, TIBC, ferritin
 Abdominal radiographs (for recent ingestion of lead -
containing material)
 Whole blood lead level
 X -ray fluorescence (XRF) - to asses body burden