TOXIC HEAVY METALS:

[Guest guest]

Dear Group,

 

This just covers the toxic heavy metals group. There are thousands of other

toxic chemicals out there where they are being taken in by the body evry day.

 

Our bodies are becoming toxic dumps. Oral chelation, high nutrition and

especially high amounts of vitamin C wil help to get the poisons out.

 

Eat organic food when possible and use nontoxic products in your homes also

 

Frank.

 

 

http://www.extremehealthusa.com/source.html

 

 

TOXIC HEAVY METALS:

SOURCES AND SPECIFIC EFFECT

 

 

Human beings have been exposed to heavy metal toxins for an immeasurable amount

of time. The industrialization of the world has dramatically increased the

overall environmental 'load' of heavy metal toxins, to the point that our

societies are dependent upon them for proper functioning. Industry and

commercial processes have actively mined, refined, manufactured, burned, and

manipulated heavy metal compounds for a number of reasons. Today, heavy metals

are abundant in our drinking water, air and soil due to our increased use of

these compounds. They are present in virtually every area of modern

consumerism-from construction materials to cosmetics, medicines to processed

foods, fuel sources to agents of destruction, appliances to personal care

products. It is very difficult for anyone to avoid exposure to any of the many

harmful heavy metals that are so prevalent in our environment. While it does not

appear that we are going to neutralize the threat of heavy metal toxicity in our

communities, nor decrease our utilization of the many commercial goods that

they help produce, we can take steps to understand this threat and put into

action policies of prevention and treatment that may help to lessen the negative

impact that these agents have on human health.

 

Heavy metal toxins contribute to a variety of adverse health effects. There

exist over 20 different heavy metal toxins that can impact human health and each

toxin will produce different behavioral, physiological, and cognitive changes in

an exposed individual. The degree to which a system, organ, tissue, or cell is

affected by a heavy metal toxin depends on the toxin itself and the individual's

degree of exposure to the toxin. Here are presented just 5 of the many hazardous

metal toxins that are commonly encountered by humans. Each of these metals

affects an individual in such a way that its respective accumulation within the

body leads to a decline in the mental, cognitive, and physical health of the

individual. The specific sources of exposure, where the metals tend to be

deposited and the adverse health effects of each metal are identified below.

 

1. Aluminum (CAS# 7429-90-5)

Sources of exposure: Aluminum is a naturally occurring metal that has been

utilized by humans for a number of years. It is the third most abundant element

in the earth's crust (approximately 8% of the crust is composed of aluminum

compounds) and is apparent is small quantities (from 3-2400 ppb) in seawater

(Venugopal and Luckey, 1978). Incidences of acid rain on the planet have

increased the availability of aluminum to various biological systems. Acid rain

is able to dissolve aluminum compounds that are naturally found in soil and

rock, thus increasing their prevalence in soils and fresh- and salt-water

sources. Because of this, aluminum concentrations can be seen in various fresh

and salt-water marine life, and in plants that have been grown in aluminum laden

soil. Humans have processed aluminum compounds for years, and its use is

apparent in many different forms of industry. Because of its many industrial and

commercial uses, aluminum is consumed and/or handled by many individuals

on a daily basis. Today aluminum can be found in cookware, aluminum foil,

dental cements, dentures, leather tanning preparations, antacids,

antiperspirants, appliances, baking powder, buffered aspirin, building

materials, canned acidic foods, food additives, lipsticks, construction

materials (the automotive, aviation and electrical industries all use aluminum

compounds for various uses), prescription and over-the-counter drugs

(anti-diarrhea agents, hemorrhoid medications, vaginal douches), dialysates,

vaccines, processed cheese, paints, toothpaste, fireworks and " softened " and

normal tap water (ATSDR 1990, Wills and Savory, 1985). Aluminum has been found

in at least 489 of the 1,416 (34%) National Priorities List (NPL) sites

identified by the Environmental Protection Agency (EPA) (ATSDR 1995).

 

 

Target tissues: Aluminum accumulates in the brain, muscles, liver lungs, bones,

kidneys, skin, reproductive organs and stomach (ATSDR 1990, Wills and Savory,

1985). Depending on the source of exposure, aluminum can be absorbed through the

gastrointestinal (GI) tract or the lungs. Absorption through the GI tract is

slow, due primarily to pH factors, but once absorbed it is distributed to the

bones, liver, testes, brain and soft tissues. Following aluminum inhalation,

deposition occurs primarily within the lungs (Venugopal and Luckey, 1978).

 

Signs and Symptoms: Aluminum toxicity can produce a number of clinical signs and

symptoms. Common are excessive headaches, abnormal heart rhythm, depression,

numbness of the hands and feet and blurred vision (Kilburn and Warshaw, 1993).

Aluminum toxicity has been shown to produce impairment in choice reaction time,

long-term memory, psychomotor speed, and recall in affected individuals as

compared to controls (Wills and Savory 1985). Animal studies have shown similar

impairment in locomotor activity/response and spatial learning in rats receiving

dietary aluminum for a period of 12 weeks (Commissaris et al., 1982). In a study

conducted with patients receiving dialysis for renal failure, aluminum was

believed to be a causal agent in the development of dialysis encephalopathy (or

" dialysis dementia " ), a special form of bone disease known as osteomalacic

dialysis osteodystrophy, and anemia (Wills and Savory, 1985). In this study,

individuals had been receiving concentrations of aluminum

directly from their dialysate. Similarly, long-term hemo-dialysis patients have

exhibited a progressive neurological syndrome that includes speech disorders,

dementia, myoclonus and encephalopathy (Perl and Brody, 1980). Evidence suggests

that inhaled aluminum may contribute to the development of pulmonary fibrosis

and, to a lesser degree, pulmonary granulomatosis (ATSDR 1990).

Aluminum may be involved in a myriad of neurodegenerative diseases. Dr.

McLaughlin, MD, F.R.C.P., a professor of physiology and medicine and the

director of the Centre for Research in Neurodegenerative Diseases at the

University of Toronto, states: " Concentrations of aluminum that are toxic to

many biochemical processes are found in at least ten human neurological

conditions " (Crapper-McLachlan 1980). Recent studies suggest that aluminum may be

involved in the progression of Alzheimer's Disease, Parkinson's disease, Guam

ALS-PD complex, " Dialysis dementia " , Amyotrophic Lateral Sclerosis (ALS), senile

and presenile dementia, neurofibrillary tangles, clumsiness of movements,

staggering when walking and an inability to pronounce words properly (Berkum

1986; Goyer 1991; Shore and Wyatt, 1983). To date, however, we do not completely

understand the role that aluminum plays in the progression of such human

degenerative syndromes.

Chronic aluminum exposure has contributed directly to hepatic failure, renal

failure, and dementia (Arieff et al., 1979). Other symptoms that have been

observed in individuals with high internal concentrations of aluminum are colic,

convulsions, esophagitis, gastroenteritis, kidney damage, liver dysfunction,

loss of appetite, loss of balance, muscle pain, psychosis, shortness of breath,

weakness, and fatigue (ATSDR 1990). Behavioral difficulties among schoolchildren

have also been correlated with elevated levels of aluminum and other neuro-toxic

heavy metals (Goyer 1991). And, aluminum toxicity may also cause birth defects

in new-borns (ATSDR 1990).

 

Medical tests for aluminum screening: Blood, urine, feces, hair, and

fingernails.

 

2. Arsenic (CAS# 7440-38-2)

Sources of exposure: The use of this toxic element in numerous industrial

processes has resulted in its presence in many biological and ecological

systems. Ground, surface, and drinking water are susceptible to arsenic

poisoning from the use of arsenic in smelting, refining, galvanizing and power

plants; environmental contaminants like pesticides, herbicides, insecticides,

fungicides, desiccants, wood preservatives, and animal feed additives; and human

made hazardous waste sites, chemical wastes and antibiotics. Arsenic

concentrations are apparent in the air as a result of the burning of arsenic

containing materials such as wood, coal, metal alloys, and arsenic waste (ATSDR

1989; Morton and Caron, 1989). Arsenic concentrations can also be found in

specialty glass, defoliants, marine life (primarily fish and shellfish) and

riot-control gas (Hine et al., 1977). Arsenic is present in at least 781 of the

1,300 (60%) NPL sites as identified by the EPA (RAIS 1992).

 

Target tissues: Many arsenic compounds are readily absorbed through the GI tract

when delivered orally in humans. Absorption within the lungs is dependent upon

the size of the arsenic compound, and it is believed that much of the inhaled

arsenic is later absorbed through the stomach after (respiratory) mucocillary

clearance (ATSDR 1989). After the absorption of arsenic compounds, the primary

areas of distribution are the liver, kidneys, lung, spleen, aorta, and skin.

Arsenic compounds are also readily deposited in the hair and nails (U.S. EPA,

1984).

 

Signs and Symptoms: Arsenic is a highly toxic element that has been used

historically for purposes of suicide and homicide. Its health effects are well

known and multiform. Acute exposure to arsenic compounds can cause nausea,

anorexia, vomiting, abdominal pain, muscle cramps, diarrhea and burning of the

mouth and throat (ATSDR 1989). Garlic-like breath, malaise, and fatigue have

also been seen in individuals exposed to an acute dose of arsenic, while contact

dermatitis, skin lesions and skin irritation are seen in individuals whom come

into direct tactile contact with arsenic compounds (Feldman et al., 1979). A

large, acute oral dose has caused tachycardia, acute encephalopathy, congestive

heart failure, stupor, convulsions, paralysis, coma and even death (Morton and

Caron 1989). Animal studies have shown similar acute effects when arsenic

compounds were delivered orally to Rhesus monkeys (Heywood and Sortwell, 1979).

Repeat exposure to arsenic compounds have been shown to lead to

the development of peripheral neuropathy, encephalopathy, cardiovascular

distress, peripheral vascular disease, EEG abnormalities, Raynaud's phenomenon,

gangrene of the lower legs ( " Black foot disease " ), acrocyanosis, increased

vasopastic reactivity in the fingers, kidney and liver damage, hypertension,

myocardial infarction, anemia and leukopenia (ATSDR 1989; Blom et al., 1985;

Feldman et al., 1979; Heyman et al., 1956; Hine et al., 1977; Langerkvist et

al., 1986; Morton and Caron, 1989). Other chronic effects of arsenic

intoxication are skin abnormalities (darkening of the skin and the appearance of

small " corns " or " warts " on the palms, soles, and torso), neurotoxic effects,

chronic respiratory diseases (pharyngitits, laryngitis, pulmonary

insufficiency), neurological disorders, dementia, cognitive impairment, hearing

loss and cardiovascular disease (Blom et al., 1985; Kyle and Pease, 1965; Morton

and Caron, 1989). A significantly higher percentage of spontaneous abortions has

been shown in a population living near a copper smelting plant; lower birth

weights of babies born to this same population are seen, and an abnormal

percentage of male to female births is also apparent, suggesting that arsenic

affects babies in utero (Nordstrom et al., 1979).

Studies have shown close associations between both inhaled and ingested arsenic

and cancer rates. Cancers of the skin, liver, respiratory tract and

gastrointestinal tract are well documented in regards to arsenic exposure (IARC

1980; Lee-Feldstein 1989). Several arsenic compounds have been classified by the

US Environmental Protection Agency as a Class A- Human Carcinogen (IARC 1987).

 

Medical test for arsenic screening: Urine (best), hair and fingernails.

 

3. Copper (CAS# 7440-50-8)

Sources of exposure: Copper occurs naturally in elemental form and as a

component of many different compounds. The most toxic form of copper is thought

to be that in the divalent state, cupric (Cu2+). Because of its high electrical

conductivity, copper is used extensively in the manufacturing of electrical

equipment and different metallic alloys. Copper is released into the environment

primarily through mining, sewage treatment plants, solid waste disposal, welding

and electroplating processes, electrical wiring materials, plumbing supplies

(pipes, faucets, braces, and various forms of tubing), and agricultural

processes (ATSDR 1990a). It is present in the air and water due to natural

discharges like volcanic eruptions and windblown dust. Drinking water sources

become contaminated with copper primarily because of its use in many different

types of plumbing supplies. It is a common component of fungicides and

algaecides, and agricultural use of copper for these purposes can result in

its presence in soil, ground water, farm animals (grazing animals like cows,

horses, etc.) and many forms of produce (ATSDR 1990a). Copper is also present in

ceramics, jewelry, monies (coins) and pyrotechnics (ACGIH 1986). Though copper

is an essential trace element required by the body for normal physiological

processes, increased exposure to copper containing substances can result in

copper toxicity and a wide variety of complications.

 

Target tissues: Absorption of copper occurs through the lungs, gastrointestinal

tract and skin (U.S. EPA, 1987). The degree to which copper is absorbed in the

gastrointestinal tract largely depends upon its chemical state and the presence

of other compounds, like zinc (U.S.A.F., 1990). Once absorbed, copper is

distributed primarily to the liver, kidneys, spleen, heart, lungs, stomach,

intestines, nails, and hair. Individuals with copper toxicity show an abnormally

high level of copper in the liver, kidneys, brain, eyes and bones (ATSDR 1990a).

 

Signs and symptoms: Acute toxicity of ingested copper is characterized by

abdominal pain, diarrhea, vomiting, tachycardia and a metallic taste in the

mouth. Continued ingestion of copper compounds can cause cirrhosis and other

debilitating liver conditions (Mueller-Hoecker et al., 1989). Inhaled copper

dust or fumes can produce eye and respiratory tract irritation, headaches,

vertigo, drowsiness, chills, fever, aching muscles and discoloration of the skin

and hair in humans (U.S.A.F., 1990). Vineyard workers exposed to copper fumes

for a long period of time developed pulmonary fibrosis and granulomas of the

lungs, liver impairment and liver disease (cirrhosis, fibrosis, and various

morphological changes). Similar results were obtained in animals chronically

exposed to copper containing dust and fumes (Johansson et al., 1984; Stockinger

1981). Further animal studies on copper toxicity have shown varying degrees of

liver and kidney damage (necrosis of the kidney; sclerosis, necrosis,

and cirrhosis of the liver), decreased total weight, brain weight and red blood

cell count, increased platelet counts and the presence of gastric ulcers (Kline

et al., 1977; Rana and Kumar, 1978). Copper also appears to affect reproduction

and development in humans and animals. Offspring of hamsters that received

copper sulfate injections while pregnant exhibited increased incidences of

hernias, encephalopathy, abnormal spinal curvature and spina bifida (Ferm and

Hanlon, 1974). Sperm motility also appears to be compromised by the presence of

copper in human spermatozoa (Battersby and Morton, 1982).

 

 

Chronic exposure to copper can produce numerous physiological and behavioral

disturbances. Copper toxicity has been characterized in patients with Wilson's

Disease, a genetic disorder that causes an abnormal accumulation of copper in

body tissue. Wilson's disease is fatal unless treated in time. Manifestations of

Wilson's Disease include brain damage and progressive demylination, psychiatric

disturbances-- depression, suicidal tendencies and aggressive behavior--

hemolytic anemia, cirrhosis of the liver, motor dysfunction and corneal

opacities (ATSDR 1990a; Goyer, 1991a; U.S. EPA, 1987). Some patients may also

experience poor coordination, tremors, disturbed gait, muscle rigidity, and

myocardial infarction (ATSDR 1990a).

 

Medical tests for copper screening: Blood, urine, and hair.

 

4. Lead (CAS# 7439-92-1)

Sources of exposure: Lead is the 5th most utilized metal in the U.S. It is mined

extensively in Missouri, Colorado, Idaho, and Utah and is used for the

production of ammunition, bearing metals, brass materials, solder, ballasts,

tubes, containers, gasoline products, ceramics, and weights (ATSDR 1993). Human

exposure to lead occurs primarily through drinking water, airborne

lead-containing particulates and lead-based paints. Several industrial processes

create lead dust/fumes, resulting in its presence in the air. Mining, smelting

and manufacturing processes, the burning of fossil fuels (especially lead-based

gasoline) and municipal waste and incorrect removal of lead-based paint results

in airborne lead concentrations. After lead is airborne for a period of ten

days, it falls to the ground and becomes distributed in soils and water sources

(fresh and salt water, surface and well water, and drinking water). However, the

primary source of lead in drinking water is from lead-based

plumbing materials (U.S. EPA, 1989). The corrosion of such materials will lead

to increased concentrations of lead in municipal drinking water. Lead from water

and airborne sources have been shown to accumulate in agricultural areas,

leading to increased concentrations in agricultural produce and farm animals

(ATSDR 1993). Cigarette smoke is also a significant source of lead exposure;

people whom smoke tobacco, or breath in tobacco smoke, may be exposed to higher

levels of lead than people whom are not exposed to cigarette smoke (RAIS 1994).

 

Target tissues: Lead is absorbed into the body following inhalation or

ingestion. Children absorb lead much more efficiently than adults do after

exposure, and ingested lead is more readily absorbed in a fasting individual

(U.S.EPA 1986). Over 90% of inhaled lead is absorbed directly into the blood.

After lead is absorbed into the body, it circulates in the blood stream and

distributes primarily in the soft tissues (kidneys, brain and muscle) and bone.

Adults distribute about 95% of their total body lead to their bones, while

children distribute about 73% of their total body lead to their bones (U.S. EPA,

1986a).

 

Signs and Symptoms: Lead is one of the most toxic elements naturally occurring

on Earth. High concentrations of lead can cause irreversible brain damage

(encephalopathy), seizure, coma and death if not treated immediately (U.S. EPA,

1986). The Central Nervous System (CNS) becomes severely damaged at blood lead

concentrations starting at 40mcg/dL, causing a reduction in nerve conduction

velocities and neuritis (ATSDR 1993). Neuropsychological impairment has been

shown to occur in individuals exposed to moderate levels of lead. Evidence

suggests that lead may cause fatigue, irritability, information processing

difficulties, memory problems, a reduction in sensory and motor reaction times,

decision making impairment, and lapses in concentration (Ehle and McKee, 1990).

At blood concentrations above 70 mcg/dL, lead has been shown to cause anemia,

characterized by a reduction in hemoglobin levels, and erythropoiesis-- a

shortened life span of red blood cells (Goyer, 1988; US EPA 1986a). In

adults, lead is very detrimental to the cardiovascular system. Occupationally

exposed individuals tend to have higher blood pressure than normal controls

(Pocock et al., 1984; Harlan et al., 1985; Landis and Flegal, 1988), and are at

an increased risk for cardiovascular disease, myocardial infarction, and stroke

(US EPA, 1990). The kidneys are targets of lead toxicity and prone to impairment

at moderate to high levels of lead concentrations. Kidney disease, both acute

and chronic nephropathy, is a characteristic of lead toxicity (Goyer, 1988).

Kidney impairment can be seen in morphological changes in the kidney epithelium,

increases in the excretion rates of many different compounds, reductions in

glomerular filtration rate, progressive glomerular, arterial, and arteriolar

sclerosis, and an altered plasma albumin ratio (Goyer, 1985, 1988; Landigran,

1989). Chronic nephropathy has lead to increased death rates among

occupationally exposed individuals as compared to controls in

studies by Selevan et al. (1975) and Cooper et al. (1985). Other signs/symptoms

of lead toxicity include gastrointestinal disturbances-abdominal pain, cramps,

constipation, anorexia and weight loss-immunosuppression, and slight liver

impairment (ATSDR, 1993; US EPA, 1986a).

 

 

Children are susceptible to the most damaging effects of lead toxicity. Ample

literature exists that shows just how damaging lead is to children. Prenatal and

postnatal development are compromised significantly by the presence of lead in

the body. At blood lead concentrations of 80-100 mcg/dL, severe encephalopathy

occurs. Those children who survive lead-induced encephalopathy typically suffer

permanent brain damage marked by mental retardation and numerous behavioral

impairments. These children also suffer slower neural conduction velocities,

peripheral neuropathy, cognitive impairment, and personality disorders (US EPA

1986a). Tuthill (1996) has found that hair lead levels in children were

positively correlated with attention-deficit and hyperactive behavior. Numerous

studies have implicated lead as a causal agent in the deterioration of cognitive

functioning in children. Studies by Schroeder and Hawk (1986), Burchfield et al.

(1980), Otto et al. (1981, 1982), and Munoz et al.

(1993) have shown IQ deficits in children with blood lead concentrations from

6-70 mcg/dL. Longitudinal studies have given further evidence that lead affects

intelligence in exposed children. Studies by Vimpani et al. (1989), McMichael et

al. (1988) and Wigg et al. (1988) have shown decreased performance on

intelligence tests in lead exposed school children. One study has correlated

lower socio-economic status with childhood lead poisoning 50 years after lead

exposure (White et al., 1993). Maternal blood lead concentrations and prenatal

lead exposure appear to be strong predictors of cognitive performance in

offspring. Prenatal exposure may also cause birth defects, miscarriage,

spontaneous abortion and underdeveloped babies (Goyer, 1988; McMichael et al.,

1988; US EPA 1986d). Lead not only appears to affect cognitive development of

young children, but also other areas of neuropsychological function. Young

children exposed to lead may exhibit mental retardation, learning

difficulties, shortened attention spans (ADHD), increased behavioral problems

(aggressive behaviors) and reduced physical growth (Bellinger, D. et al., 1990,

1992). Lead has been determined by many health experts to be the #1 threat to

developing children in our industrial societies.

 

Medical test for lead screening: Blood, urine, and hair.

 

5. Mercury (CAS#7439-97-6)

Sources of exposure: Mercury occurs primarily in two forms: organic mercury and

inorganic mercury. Inorganic mercury occurs when elemental mercury is combined

with chlorine, sulfur, or oxygen. Inorganic mercury and elemental mercury are

both toxins that can produce a wide range of adverse health affects. Inorganic

mercury is used in thermometers, barometers, dental fillings, batteries,

electrical wiring and switches, fluorescent light bulbs, pesticides, fungicides,

vaccines, paint, skin-tightening creams, vapors from spills, antiseptic creams,

pharmaceutical drugs and ointments (ATSDR, 1989a). Inorganic mercury vapor is at

high concentrations near chlorine-alkali plants, smelters, municipal

incinerators and sewage treatment plants. The organic form occurs when mercury

is combined with carbon. The most common form of organic mercury is methyl

mercury, which is produced primarily by small organisms in water and soil when

they are exposed to inorganic mercury. Humans also have the

ability to convert inorganic mercury to an organic form once it has become

absorbed into the bloodstream. Organic mercury is known to bioaccumulate -- or

pass up the food chain due an organism's inability to process and eliminate it.

It is found primarily in marine life (fish), and can often be found in produce

and farm animals, processed grains and dairy products, and surface, salt-, and

fresh water sources (ATSDR, 1989a; Brenner and Snyder, 1980). Occupational

exposure to mercury containing compounds presents a significant health risk to

individuals. Dentists, painters, fisherman, electricians,

pharmaceutical/laboratories workers, farmers, factory workers, miners, chemists

and beauticians are just some of the professions chronically exposed to mercury

compounds.

 

Target tissues: The absorption and distribution of mercury compounds depends

largely upon its chemical state. Organic mercury compounds are absorbed from the

gastrointestinal tract more readily than inorganic mercury compounds, with the

latter being very poorly absorbed. After absorption in the gastrointestinal

tract, organic mercury is readily distributed throughout the body but tends to

concentrate in the brain and kidneys (Goyer, 1991b). Approximately 80% of

mercury vapor is absorbed directly through the lungs and distributed primarily

to the CNS and the kidneys (Friberg and Nordberg, 1973). Inorganic and organic

forms of mercury have also been seen in the red blood cells, liver, muscle

tissue, and gall bladder (Peterson et al., 1991, Dutczak et al., 1991, ATSDR

1989a).

 

Signs and symptoms: Mercury exposure can result in a wide variety of human

health conditions. The degree of impairment and the clinical manifestations that

accompany mercury exposure largely depend upon its chemical state and the route

of exposure. While inorganic mercury compounds are considered less toxic than

organic mercury compounds (primarily due to difficulties in absorption),

inorganic mercury that is absorbed is readily converted to an organic form by

physiological processes in the liver.

 

 

The acute ingestion of inorganic mercury salts may cause gastrointestinal

disorders such as abdominal pain, vomiting, diarrhea, and hemorrhage (ATSD

1989a). Repeated and prolonged exposure has resulted in severe disturbances in

the central nervous system, gastrointestinal tract, kidneys, and liver. Daivs et

al. (1974) reported dementia, colitis, and renal failure in individuals

chronically poisoned due to the ingestion of an inorganic mercury containing

laxative. Inhaled inorganic mercury can cause a wide range of clinical

complications in individuals including corrosive bronchitis, interstitial

pneumonitis, renal disorders, fatigue, insomnia, loss of memory, excitability,

chest pains, impairment of pulmonary function and gingivitis (Goyer 1991b, ATSDR

1989a). Chronic inhalation of inorganic mercury compounds may result in a

reduction of sensory and motor nerve function, depression, visual and/or

auditory hallucinations, muscular tremors, sleep disorders, alterations in

autonomic

function (heart rate, blood pressure, reflexes), impaired visuomotor

coordination, speech disorders, dementia, coma and death (Clarkson 1989; Goyer

1991b; Fawyer et al. 1983; Piikivi and Hanninen 1989; and Ngim et al. 1992).

Ngim et al. (1992) have shown that a group of dentists exposed to mercury vapors

occupationally perform significantly worse in neurobehavioral tests that measure

motor speed, visual scanning, visuomotor coordination and concentration, verbal

memory and visual memory. Kishi et al. (1993) have found that smelter workers

exposed to inorganic mercury compounds continue to experience neurological

symptoms-tremors, headaches, slurred speech-senile symptoms and diminished

mental capacities eighteen years after the cessation of mercury exposure.

 

 

Our understanding of the effects of methyl mercury poisoning comes primarily

from epidemic poisonings in Iraq and Japan. In iraq, more than 6,000 individuals

were hospitalized and 459 died as a result of methyl mercury poisoning. Adults

experienced symptoms including parasthesia, visual disorders, ataxia, fatigue,

tremor, hearing disorders (deafness) and coma (Bakir et al., 1973; Mottet, Shaw,

and Burbacher, 1985). Neuropathologic observations of exposed individuals have

shown irreversible brain damage including neuronal necrosis, cerebral edema,

gliosis, and cerebral atrophy (Mottet, Shaw, and Burbacher, 1985). Iraqi

children poisoned through the consumption of methyl mercury containing food

products (grains treated with mercury containing fungicides) exhibited nervous

system impairment, visual and auditory disorders, weakness, marked motor and

cognitive impairment, and emotional disturbances (Bakir et al., 1973; Bakir et

al., 1978). Individuals in Japan experienced many of these

same symptoms after the ingestion of fish containing large amounts of methyl

mercury. Similarly, autopsies conducted on deceased Japanese in the Minamata Bay

have shown pronounced brain lesions, cerebral atrophy, edema, and gliosis in the

deeper fissures (sulci) of the brain, such as in the visual cortex (Takeuchi

1968). The Japan and Iraq epidemics have clearly established mercury as an agent

that can disrupt developmental processes in the unborn, and infantile,

individual. Methyl mercury can pass through the placental barrier and produce

many deleterious effects on the unborn fetus (Mottet, Shaw and Burbacher 1985).

Children born to mercury poisoned mothers were of smaller total weight, had

decreased brain weights at birth, had fewer nerve cells in the cerebral cortex,

and experienced an abnormal pattern of neuronal migration (Choi et al. 1978;

Takeuchi 1968, Amin-Zake et al. 1974). Of those children that survived the

epidemic, many experienced severe developmental effects like

impaired motor and mental function, hearing loss, and blindness throughout

their childhood (Amin-Zaki et al. 1974). Researchers have also observed a

heightened incidence of cerebral palsy in children born to mothers in the

Minamata Bay (Matsumoto, Koya, and Takeuchi 1965).

Mercury has recently been implicated as being a contributing factor to the

increasing prevalence of autism in American children. The Autism Research

Institute has focused on mercury containing vaccines (TMS) and their

relationship to autism. Over 2 million individuals are affected with autism, a

neurodevelopment syndrome that typically produces impairment in sociality,

communication, and sensory/perceptual processes, and recent evidence has found a

positive correlation between complications seen in autistics and complications

seen in mercury poisoned individuals (Bernard et al., 2000). While it is

difficult to ascribe causation in this case, it should not be altogether

dismissed. Mercury poisoning has been implicated in the development of many

other human dysfunctional states for many years. Among these are cerebral palsy,

amyotrophic lateral sclerosis, Parkinson's disease, psychosis, and chronic

fatigue syndrome (Adams et al., 1983; Bernard et al., 2000; Dales 1972) .

 

We are beginning to understand the threat that heavy metal toxins are to our

health. However, heavy metal toxicity is a condition that often goes overlooked

in traditional medical diagnoses. While it is rare for an individual to

experience a disease or health condition solely from a heavy metal toxin, it is

reasonable to conclude that these toxins exert a dramatic effect on the health

of an individual and contribute to the progression of many different

debilitating conditions. We have seen how just 5 heavy metals and their

respective compounds can adversely affect an individual's health. These effects

range from simple gastrointestinal disturbances to severe emotional and

cognitive disturbances. Metal toxins have the ability to impair not just a

single cell or tissue, but many of the body's systems that are responsible for

our behavior, mental health, and proper physiological functioning that we depend

on for sustained life. If undetected, these agents can cause immeasurable pain

and

suffering for any afflicted individual. Fortunately, there are avenues that an

affected individual can pursue to detoxify heavy metals already in their system.

Popular therapies (known as chelation) today rely on intravenous (IV) solutions

to help eliminate heavy metal toxins. EDTA and DMSA are two compounds that are

being used for the removal of heavy metals today. These therapies have been

shown to be effective, but also potentially harmful to many individuals.

Alternative chelation therapies have been developed that are safer than the

traditional IV therapies, and may prove to be just as effective. These

therapies, popularly known as oral chelation therapies, rely on nutritional

substances that have been shown to help detoxify heavy metals within the body

and help support the body's overall health.

 

Oral Chelation and Age-Less(Nutritional Replacement) for Heavy Metal Toxicity

and Cardiovascular Conditions

 

Heavy metal toxicity is frequently the result of long term, low level exposure

to pollutants common in our environment: air, water, food, and numerous consumer

products. Exposure to toxic metals is associated with many chronic diseases.

Recent research has found that even low levels of lead, mercury, cadmium,

aluminum and arsenic can cause a wide variety of health problems.

 

 

SYMPTOMS

 

Decreased Intelligence in Children

Nervous System Disorders

Immune Dysfunction

Depression

Fatigue

Muscle Weakness and Aches

Anemia

Skin Rashes

High Blood Pressure

Memory Loss

 

SOURCES

 

-Aluminum Cookware

-Amalgam Fillings

-Drinking Water

-Air Pollution

-Tobacco Smoke

-Fish and Seafood

-Pesticides

-Medications

-Cosmetics

-Fertilizers

-Heavy Traffic

-Old Paint

-Anti-Perspirants

 

 

 

 

SOLUTION

 

Extreme Health's Oral Chelation Formula

 

Diarrhea

Nausea

Metallic Taste in Mouth

Irritability

Tremors

Cancer

Hyperactivity

Autism

Behavioral Disorders

Headaches

 

Testing is available to verify the effectiveness of the Oral Chelation and

Age-Less Formula

 

Recommended by DOCTORS

 

Behavioral, Structural, Functional Abnormalities associated with various Heavy

Metal Toxins

 

Published in the August Issue of Alternative & Complementary Therapies

(a magazine for doctors) and Published in the April Issue of Townsend Letter for

Doctor's & Patients.

 

Psychiatric Disturbances:

 

Social Deficits, Social withdrawal

 

Mercury

 

Repetitive, perseverative, stereotyped behaviors; OCD-typical behaviors

 

Mercury

 

Depression, mood swings, flat affect; impaired facial recognition

 

Arsenic, Copper, Lead, Mercury

 

Schizoid tendencies; hallucinations; delirium

 

Mercury

 

Irritability, aggressive behaviors, temper tantrums

 

Lead, Mercury

 

Suicidal Behaviors

 

Copper, Mercury

 

Sleep difficulties/ disturbances

 

Lead, Mercury, Thallium

 

Chronic fatigue (CFS); weakness, malaise

 

Aluminum, Arsenic, Cadmium, Copper, Lead, Mercury, Thallium

 

Anorexia; symptoms reflecting eating disorders, loss of appetite/weight

 

Arsenic, Lead, Mercury

 

Anxiety; nervous tendencies

 

Thallium

 

Attentional problems (ADHD), lacks eye contact, impaired visual fixation

 

Lead, Mercury

 

Speech and Language Deficits:

 

Speech disorders

 

Aluminum, Mercury

 

Loss of speech, developmental problems with language

 

Mercury

 

Speech comprehension deficits

 

Mercury

 

Dysarthria; articulation problems; slurred speech, unintelligible speech

 

Mercury

 

Cognitive Impairments:

 

Mental retardation, borderline intelligence

 

Arsenic, Lead, Mercury

 

 

 

 

 

Uneven performance on IQ scores, low IQ scores

 

Copper, Lead

 

Poor concentration, attention deficits (ADHD), response inhibition

 

Aluminum, Lead

 

Poor memory (short term, verbal, and auditory)

 

Aluminum, Lead

 

Difficulties understanding abstract ideas; difficulty carrying out complex

commands

 

X metals

 

Dementia; pre-senile and senile dementia

 

Aluminum

 

Stupor

 

Aluminum, Arsenic,

 

Impaired reaction time; lower performance on timed tests

 

Lead

 

Sensory Abnormalities:

 

Abnormal Sensations in the mouth and extremities

 

Arsenic

 

Hearing loss, difficulty hearing

 

Arsenic, Lead, Mercury

 

Abnormal touch sensations; diminished touch sensations, aversion to touch

 

Arsenic

 

Blurred vision; sensitivity to light

 

Arsenic, Mercury

 

Motor Disorders:

 

Choreiform movements, myoclonal jerks, unusual postures

 

Copper, Mercury

 

Difficulty walking, swallowing, talking

 

Copper, Mercury

 

Flapping, circling, rocking, toe walking

 

Mercury

 

Problems with intentional movements or imitation

 

Mercury

 

Abnormal gait/posture; uncoordination, loss of balance; problems sitting, lying,

crawling, and walking

 

Mercury

 

Decreased locomotor activity

 

Aluminum, Arsenic

 

Convulsions; seizure

 

Aluminum , Arsenic, Copper, Lead, Mercury, Thallium

 

 

 

Physiological Impairment

 

Brain and Central Nervous System:

 

Neurofibrillary tangles

 

Aluminum

 

Neuritis, retrobulbar neuritis; neuropathy

 

Aluminum, Arsenic, Thallium

 

Encephalopathy

 

Aluminum, Arsenic, Lead, Thallium

 

Cerebrovascular disease

 

X metals

 

Alterations in nerve conduction velocity

 

Lead

 

Alterations in the spinal chord

 

Thallium

 

Accumulates in CNS structures

 

Aluminum, Mercury

 

Abnormal EEGs

 

Arsenic, Lead

 

Autonomic disturbances

 

Copper, Lead, Mercury, Thallium

 

Peripheral Nervous System:

 

Peripheral neuropathy

 

Arsenic, Mercury

 

Alterations in peripheral nerves

 

Arsenic

 

Loss of feeling/ numbness in the extremities; parasthesia

 

Arsenic, Mercury, Thallium

 

Gastrointestinal Tract:

 

Nausea, vomiting, diarrhea; loss of appetite

 

Arsenic, Copper, Mercury, Thallium

 

Abdominal pain, stomach cramps; burning of the throat and mouth

 

Arsenic, Copper, Lead, Mercury, Thallium

 

Esophagitis; gastroenteritis; colitis

 

Arsenic, Mercury, Thallium

 

Cancers (colon, pancreatic, stomach, or rectal)

 

Arsenic

 

Renal and Hepatic Impairment:

 

Hepatotoxicity; Liver dysfunction, damage

 

Arsenic, Copper, Thallium

 

Cirrhosis of the liver; hepatitis

 

Copper

 

Kidney disease ; kidney failure

 

Arsenic, Lead, Mercury

 

Renal toxicity; tubular proteinosis

 

Arsenic, Copper, Lead

 

Kidney Damage, histological alterations

 

Arsenic, Lead

 

Cardiovascular System:

 

Blood vessel damage

 

Arsenic

 

Anemia; decreased red blood cell count

 

Arsenic, Copper, Lead

 

Hypertension; increased heart rate (tachycardia)

 

Arsenic, Copper, Lead, Thallium

 

Electrocardiac disorders

 

Peripheral vascular disease; cardiovascular disease; vascular collapse

 

Arsenic, Lead

 

Respiratory System:

 

Pulmonary Fibrosis

 

Aluminum, Arsenic

 

Pulmonary edema

 

X metals

 

Pneumonia, laryngitis, pharyngitis, bronchitis

 

Aluminum, Arsenic, Mercury

 

Restrictive airway disorders, asthmatic conditions, pneumoconisis

 

Arsenic, Aluminum

 

Respiratory tract cancers

 

Arsenic

 

Nasal ulcers, perforation of the nasal septum

 

X metals

 

Immune System:

 

Increased incidences of asthma, autoimmune-like symptoms, & allergies

 

X metals

 

Inhibition of lymphocytes, T-cells, monocytes

 

X metals

 

Immunosuppression

 

Lead

 

Decreased white blood cell count

 

Arsenic, Thallium

 

Reproductive System:

 

Genital abnormalities

 

Aluminum, Thallium

 

Disturbances in menstrual cycle; menstrual pains

 

Copper, Mercury

 

Birth defects; premature births; Spontaneous abortion

 

Arsenic, Lead, Mercury

 

Reproductive dysfunction

 

Arsenic, Aluminum, Cadmium, Lead

 

Other Physical Disturbances:

 

Hypotonia or hypertonia; decreased muscular strength

 

X metals

 

Rashes, contact dermatitis, eczema, itchy/irritating skin

 

Aluminum, Arsenic, Copper, Mercury

 

Muscle pain; headache; acrodynia; colic

 

Arsenic, Copper, Lead, Thallium

 

Alopecia (hair loss)

 

Thallium

 

References:

 

ACGIH (American Conference of Governmental Industrial Hygienists). 1986. Copper.

In: Documentation of the Threshold Limit Values and Biological Exposure Indices,

5th ed. ACGIH, Cincinnati, OH, p. 146.

Adams, C.R., Ziegler, D.K., and Lin, J.T. 1983. Mercury intoxication simulating

Amyotrophic Lateral Sclerosis. JAMA 250: 642-643.

Amin-Zaki, L., S. Elhassani, M.A. Majeed, T. W. Clarkson, R.A. Doherty and M.

Greenwood. 1974. Intra-uterine methylmercury poisoning. Pediatrics 54:587-595.

Arieff, A.L., Cooper, J.D., Armstrong, D., and Lazarowitz, V.C. 1979. Dementia,

renal failure, and brain aluminum. Ann. Intern. Med. 90: 741-747.

Bernard, S., Enayati, A., Redwood, L., and Bistock, T. 2000. Autism: A novel

form of mercury poisoning. The Aurtism Research Institute.

http://www.autism.com/ari/mercury.html.

ATSDR (Agency for Toxic Substances and Disease Registry). 1989. Toxicological

Profile for Arsenic. Agency for Toxic Substances and Disease Registry, U.S.

Public Health Service, Atlanta, GA. ATSDR/TP-88/02.

ATSDR (Agency for Toxic Substances and Disease Registry). 1989a. Toxicological

Profile for Mercury. ATSDR/U.S. Public Health Service.

ATSDR (Agency for Toxic Substances and Disease Registry). 1990. Toxicological

Profile for Aluminum. Agency for Toxic Substances and Disease Registry, U.S.

Public Health Service, Atlanta, GA ATSDR/TP-88/01.

ATSDR (Agency for Toxic Substances and Disease Registry). 1990a. Toxicological

Profile for Copper. Prepared by Syracuse Research Corporation for ATSDR, U.S.

Public Health Service under Contract 88-0608-2. ATSDR/TP-90-08.

ATSDR (Agency for Toxic Substances and disease Registry). 1993. Toxicological

Profile for Lead. Update. Prepared by Clement International Corporation under

contract No. 205-88-0608 for ATSDR, U.S. Public Health Service, Atlanta, GA.

Bakir, F., S. F. Kamluji, L. Amin-Zaki, et al. 1973. Methylmercury poisoning in

Iraq. Science 181: 230-241.

Battersby, S., J.A. Chandler and M.S. Morton. 1982. Title not given. Fertil.

Steril. 37: 230-235.

Bellinger, D.; Leviton, a.; Sloman, J. (1990) Antecedents and correlates of

improved cognitive performance in children exposed in utero to low levels of

lead. Environ. Health Perspect. 89:5-11.

Bellinger, D.C.; Stiles, K.M.; Needleman, H.L. (1992) Low-level lead exposure,

intelligence and academic achievement: A long-term follow-up study. Pediatrics.

90:855-561.

Berkum, M.F.A. 1986. Aluminum: a role in degenerative brain disease associated

with neurofibrillary degeneration " Progress in Brain Research 70: 399-409.

Blom, S.; Lagerkvist, B.; Linderholm, H. 1985. Arsenic exposure to smelter

workers: clinical and neurophysiological studies. Scand. J. Work Environ. Health

11:265-270.

Brenner, R.P. and Snyder, R.D. 1980. Late Eeg findings and clinical status after

organic mercury poisoning. Arch. Neurol. 37: 282-284.

Burchfiel, J.L., F.H. Duffy, P.H. Bartels and H.L. Neelleman. 1980. The combined

discriminating power of quantitative electroencephalography and neuropsychologic

measures in evaluating central nervous system effects of lead at low levels. In:

Needleman, H.L., Ed. Low Level Lead Exposure: The Clinical Implications of

Current Research. Raven Press, New York. pp. 75-89

Clarkson, T. W. 1989. Mercury. J. Am. Coll. Toxicol. 8: 1291-1295.

Commissaris, R.L., J.J. Gordon, S. Sprague, et al. 1982. Behavioral changes in

rats after chronic aluminum and parathyroid hormone administration.

Neurobehavior. Toxicol. Teratol. 4: 403-410.

Cooper, W.C.; Wong, O.; Kheifets, L. (1985) Mortality among employees of lead

battery plants and lead-producing plants, 1947 - 1980. Scand. J. Work Environ.

Health 11:331-345.

Crapper-McLachlan, D.R., and DeBoni, U. 1980. Aluminum in human brain disease-an

overview. " Neurotoxicology 1:3-16.

Dales, L.G. 1972. The Neurotoxicity of alkyl mercury compounds. Am. J. of Med.

53: 219-232.

Davis, L. E., J. R. Wands, S. A. Weiss, et al. 1974. Central nervous

intoxication from mercurous chloride laxatives - quantitative, histochemical and

ultrastructure studies. Arch. Neurol. 30: 428-431.

Dutczak, W., T. W. Clarkson, and N. Ballatori. 1991. Biliary-hepatic recycling

of a xenobiotic: gallbladder absorption of methyl mercury. Amer. J. Physiol.

260: G873-G880.

Ehle, A.L.; McKee, D.C. (1990) Neuropsychological effect of lead in

occupationally exposed workers: a critical review. Crit. Rev. Toxicol.

20:237-255.

Fawer, R. F., Y. De Ribaupierre, M. P. Guillemin, M. Berode, and M. Lob. 1983.

Measurement of hand tremor induced by industrial exposure to metallic mercury.

Br. J. Indust. Med. 40: 204-208.

Feldman, R.G.; Niles, C.A.; Kelly-Heyes, M.; Sax, D.S.; Dixon, W.J.; Thompson,

D.J.; Landau, E. 1979. Peripheral neuropathy in arsenic smelter workers.

Neurology 29:939-944.

Ferm, V.H. and D.P. Hanlon. 1974. Toxicity of copper salts in hamster embryonic

development. Biol. Reprod. 11: 97-101.

Friberg, L. and F. Nordberg. 1973. Inorganic mercury--a toxicological and

epidemiological appraisal. In: Miller, M.W. and T.W. Clarkson, eds. Mercury,

mercurials and mercaptans. Charles C. Thomas Co., Springfield, Il. pp. 5-22.

Goyer, R.A. (1988) Lead. In: Handbook on Toxicity of Inorganic Compounds. H.G.

Seiler and H. Sigel, eds. Marcel Dekker, Inc.: New York, pp. 359-382.

Goyer, R.A. 1991. Toxic Effects of Metals. In: Casarett and Doull's Toxicology.

The Basic Science of Poisons. Fourth Edition. M.O. Amdur, J. Doull, and C.D.

Klaassen, Ed. Permagon Press. pp. 662-663.

Goyer, R.A. 1991a. Toxic effects of metals. In: M.O. Amdur, J. Doull and C.D.

Klaasen, Eds., Casarett and Doull's Toxicology, 4th ed. Pergamon Press, New

York, NY, p. 653-655.

Goyer. R. 1991b. Toxic effects of metals. In: Amdur, M.O., J.D. Doull and C.D.

Klassen, Eds. Casarett and Doull's Toxicology. 4th ed. Pergamon Press, New York.

pp.623-680.

Harlan, W.R.; Landi, J.R.; Shcmouder, R.L.; Goldstein, N.G.; Harlan, L.C. (1985)

Blood lead and blood pressure: relationship in the adolescent and adult US

population. J. Am. Med. Assoc. 253:530-534.

Heyman, A.; Pfeiffer, J.B.; Willett, R.W.; Taylor, H.M. 1956. Peripheral

neuropathy caused by arsenical intoxication. New England J. Med. 254(9):

401-409.

Heywood. R.; Sortwell, R.J. 1979. Arsenic intoxication in the rhesus monkey.

Toxicol. Lett. 3:137-144.

Hine, C.H.; Pinto, S.S.; Nelson, K.W. 1977. Medical problems associated with

arsenic exposure. J. Occup. Med. 19(6):391-396.

IARC (International Agency for Research on Cancer. 1980. Some metals and

metallic compounds. IARC Monographs on the Evaluation of Carcinogenic Risks to

Humans, vol. 23. Geneva.

IARC (International Agency for Research on Cancer (IARC). 1987. Overall

Evaluations of Carcinogenicity: an Updating of IARC Monographs Volumes 1 to 42.

IARC Monographs on the Evaluation of Carcinogenic Risks to Humans, supplement 7.

Geneva.

Johansson, A., T. Curstedt, B. Robertson, et al. 1984. Lung morphology and

phospholipids after experimental inhalation of soluble cadmium, copper, and

cobalt. Environ. Res. 34: 285-309.

Killburn, K.H. and Warshaw, R.H. 1993. Neurobehavioral testing of subjects

exposed residually to groundwater contaminated from an aluminum die-casting

plant and local referents. J. Toxicol. Environ. Health. 39: 483-496.

Kishi, R., R. Doi, Y. Fukuchi, H. Satoh, T. Satoh, A. Ono, et al. 1993.

Subjective symptoms and neurobehavioral performances of ex-mercury miners at an

average of 18 years after the cessation of chronic exposure to mercury vapor.

Environ. Res. 62: 289-302.

Kline, R.D., V.W. Hays and G.L. Cromwell. 1971. Effects of copper, molybdenum

and sulfate on performance, hematology and copper stores of pigs and lambs. J.

Animal Sci. 33: 771-779.

Kyle, R.A.; Pease, G.L. 1965. Hematologic aspects of arsenic intoxication. New

Eng. J. Med. 273(1):18-23.

Landis, J.R.; Flegal, K.M. (1988) A generalized Mantel-Haenszel analysis of the

regression of blood pressure on blood lead using NHANES II data. Environ. Health

Prospect. 78:35-41.

Langerkvist, B., Linderholm, H., and Nordberg, G.F. 1986. Vasopastic tendency

and Raynaud's Phenomenon in smelter workers exposed to arsenic. Environ. Res.

39: 465-474.

Lee-Feldstein, A. 1989. A comparison of several measures of exposure to arsenic:

matched case control study of copper smelter employees. Am. J. Epidemiol.

129:112-124.

Matsumoto, H., Koya, G., and Takeuchi, T. 1965. Fetal Minamata Disease. J.

Neuropath. Exp. Neurol. 24: 563.

McMichael, A.J.; Baghurst, P.A.; Wigg, N.R.; et al. (1988) Port Pirie cohort

study: environmental exposure to lead and children's ability at the age of four

years. N. Engl. J. Med. 319:468-475.

Morton, W.E.; Caron, G.A. 1989. Encephalopathy: an uncommon manifestation of

workplace arsenic poisoning? Am. J. Ind. Med. 15:1-5.

Mottet, N. K., C.-M. Shaw, and T. M. Bubacher. 1985. Health risks from increases

in methylmercury exposure. Environ. Health Perspect. 63: 133-140.

Mueller-Hoecker, J., U. Meyer, B. Wiebecke, et al. 1988. Copper storage disease

of the liver and chronic dietary copper intoxication in two further German

infants mimicking Indian childhood cirrhosis. Pathol. Red. Pract. 183: 39-45.

Muñoz, H.; Romieu, I.; Palazuelos, E.; et al. (1993) Blood lead level and

neurobehavioral development among children living in Mexico City. Arch. Environ.

Health. 48:132-139.

Ngim, C. H., S. C. Foo, K. W. Boey, and J. Jeyaratnam. 1992. Chronic

neurobehavioral effects of elemental mercury in dentists. Br. J. Ind. Med. 49:

782-790.

Nordström, S.; Beckman, L.; Nordenson, I. 1978a. Occupational and environmental

risks in and around a smelter in northern Sweden. I. Variations in birth weight.

Hereditas 88:43-46.

Otto, D.A., V.A. Benignus, K.E. Muller and C.N. Barton. 1981. Effects of age and

body lead burden on CNS function in young children. I. Slow cortical potentials.

Electroencephalogr. Clin. Neurophysiol. 52: 229-239.

Perl, D.P. and Brody, A.R. 1980. Alzheimer's disease: X-ray spectrometric

evidence of aluminum accumulation in neurofibrillary tangle-bearing neurons.

Science 208: 297-299.

Petersson, K., L. Dock, K. Söderling and M. Vahter. 1991. Distribution of

mercury in rabbits subchronically exposed to low levels of radiolabeled methyl

mercury. Pharmacol. Toxicol. 68: 464-468.

Piikivi, L., and H. Hanninen. 1989. Subjective symptoms and psychological

performance of chlorine-alkali workers. Scand. J. Work Environ. Health 15:

69-74.

Pocock, S.J.; Shaper, A.G.; Ashby, D. Delves, T.; Whitehead, T.P. (1984) Blood

lead concentration, blood pressure, and renal function. Br. Med. J. 289:872-874.

RAIS Toxicity Profile for Arsenic. April 1992.

http://risk.lsd.ornl.gov/tox/profiles/arsenic.shtml.

RAIS Toxicity Profile for Lead. December 1994.

http://risk.lsd.ornl.gov/tox/profiles/lead.shtml.

Rana, S.V.S. and A. Kumar. 1978. Simultaneous effects of dietary molybdenum and

copper on the accumulation of copper in the liver and kidney of copper poisoned

rats. A histochemical study. Ind. Health 18: 9-17.

Selevan, S.G.; Landrigan, P.J. Stern, F.B.; Jones, J.H. (1985) Mortality of lead

smelter workers. Am. J. Epidemiol. 122:673-683.

Shore, D. and R.J. Wyatt. 1983. Aluminum and Alzheimer's disease. J. Nerv. Ment.

Dis. 171: 553-558.

Stokinger, H.E. 1981. Copper. In: G.D. Clayton and E. Clayton, Eds, Patty's

Industrial Hygiene and Toxicology, Vol. 2A. John Wiley & Sons, New York, NY, pp.

1620-1630.

Takeuchi, T. 1968. In: Minamata Disease (M. Kutsama Ed.), Kumamoto Univ. Press,

Kumamoto, Japan. Pp141-228.

Tuthill, R.W. 1996. Hair lead levels related to children's classroom

attention-deficit behavior. Arch. Environ. Health 51 (3): 214-220.

U.S. AF (U.S. Air Force). 1990. Copper. In: The Installation Program Toxicology

Guide, Vol. 5. Wright-Patterson Air Force Base, Ohio, pp. 77(1-43).

U.S. EPA. 1984. Health Assessment Document for Arsenic. Office of Health and

Environmental Assessment, Environmental Criteria and Assessment Office, Research

Triangle Park, NC. EPA 600/8-32-021F.

U.S. Environmental Protection Agency (EPA). 1986. Lead effects on cardiovascular

function, early development, and stature: an addendum to EPA Air Quality

Criteria for Lead (1986). In: Air Quality Criteria for Lead, Vol. I.

Environmental Criteria and Assessment Office, Research Triangle Park, NC.

EPA-600/8-83/028aF. Available from NTIS, Springfield, VA; PB87-142378. pp.

A1-67.

U.S. EPA. 1987. Drinking Water Criteria Document for Copper. Prepared by the

Office of Health and Environmental Assessment, Environmental Criteria and

Assessment Office, Cincinnati, OH, for the Office of Drinking Water, Washington,

DC. ECAO-CIN-417.

U.S. Environmental Protection Agency (EPA). 1989. Evaluation of the Potential

Carcinogenicity of Lead and Lead Compounds. Office of Health and Environmental

Assessment. EPA/600/8-89/045A.

U.S. Environmental Protection Agency (EPA). 1990. Air Quality Criteria for Lead:

Supplement to the 1986 Addendum. Environmental Criteria and Assessment Office,

Research Triangle Park, NC. EPA-600/8-89/049F.

Venugopal, B. and T.D. Luckey. 1978. Metal Toxicity in Mammals-2. Chemical

Toxicity of Metals and Metalloids. Plenum Press. pp. 104-112.

Vimpani, G.; Baghurst, P.; McMichael, A.J.; et al. (1989) " The effects of

cumulative lead exposure on pregnancy outcome and childhood development during

the first four years. " Presented at: Conference on Advances in Lead Research:

Implications for Environmental Research. Research Triangle Park, NC, National

Institute of Environmental Health Sciences, January.

White, R.F.; Diamond, R.; Proctor, S.; Morey, C.; Hu, H. (1993) Residual

cognitive deficits 50 years after lead poisoning during childhood. Br. J. Ind.

Med. 50:613-622.

Wigg, N.R.; Vimpani, G.V.; McMichael, A.J.; et al. (1988) Port Pirie cohort

study: childhood blood lead and neuropsychological development at age two years.

J. Epidemiol. Commun. Health. 42:213-219.

Willis, M.R. and Savory, J. 1985. Water content of aluminum, dialysis dementia,

and osteomalacia. Env. Health. Persp. 63: 141-147.

 

 

 

 

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