(Extreme
Health doesn't claim to be able to cure or treat autism but targets
and addresses all 20 of the toxic heavy metals. By testing to verify
if your child has toxic heavy metals may offer a solutions to symptoms
that mirror autistic symptoms. Extreme Health doesn't feel that
any one enity can be blamed for a toxic heavy metal overload.)
Autism:
a Novel Form of Mercury Poisoning
S.Bernard,
B.A., A Enayati, M.S.M.E., L.Redwood, M.S.N., H. Roger, B.A, T Binstock
Summary:
Autism is a syndrome characterized by impairments in social relatedness
and communication, repetitive behaviors, abnormal movements, and
sensory dysfunction. Recent epidemiological studies suggest that
autism may affect 1 in 150 U. S. children. Exposure to mercury can
cause immune, sensory, neurological, motor, and behavioral dysfunctions
similar to traits defining or associated with autism, and the similarities
extend to neuroanatomy, neurotransmitters, and biochemistry. Thimerosal,
a preservative added to many vaccines, has become a major source
of mercury in children who, within their first two years, may have
received a quantity of mercury that exceeds safety guidelines. A
review of medical literature and U.S. government data suggests that
(i) many cases of idiopathic autism are induced by early mercury
exposure from thimerosal; (ii) this type of autism represents an
unrecognized mercurial syndrome; and (iii) genetic and non-genetic
factors establish a predisposition whereby thimerosal's adverse
effects occur only in some children.
INTRODUCTION
Autistic
Spectrum Disorder (ASD) is a neurodevelopmental syndrome with onset
prior to age 36 months. Diagnostic criteria consist of impairments
in sociality and communication plus repetitive and stereotypic behaviors
(1). Traits strongly associated with autism include movement disorders
and sensory dysfunctions (2). Although autism may be apparent soon
after birth, most autistic children experience at least several
months, even a year or more of normal development -- followed by
regression, defined as loss of function or failure to progress (2,3,4).
The
neurotoxicity of mercury (Hg) has long been recognized (5). Primary
data derive from victims of contaminated fish (Japan - Minamata
Disease) or grain (Iraq, Guatemala, Russia); from acrodynia (Pink
Disease) induced by Hg in teething powders; and from individual
instances of mercury poisoning (HgP), many occurring in occupational
settings (e.g., Mad Hatter's Disease). Animal and in vitro studies
also provide insights into the mechanisms of Hg toxicity. More recently,
the Food and Drug Administration (FDA) and the American Academy
of Pediatrics (AAP) have determined that the typical amount of Hg
injected into infants and toddlers via childhood immunizations has
exceeded government safety guidelines on an individual (6) and cumulative
vaccine basis (7). The mercury in vaccines derives from thimerosal
(TMS), a preservative which is 49.6% ethylmercury (eHg) (7).
Past
cases of HgP have presented with much inter-individual variation,
depending on the dose, type of mercury, method of administration,
duration of exposure, and individual sensitivity. Thus, while commonalities
exist across the various instances of HgP, each set of variables
has given rise to a different disease manifestation (8,9,10,11).
It is hypothesized that the regressive form of autism represents
another form of mercury poisoning, based on a thorough correspondence
between autistic and HgP traits and physiological abnormalities,
as well as on the known exposure to mercury through vaccines. Furthermore,
other phenomena are consistent with a causal Hg-ASD relationship.
These include (a) symptom onset shortly after immunization; (b)
ASD prevalence increases corresponding to vaccination increases;
(c) similar sex ratios of affected individuals; (d) a high heritability
rate for autism paralleling a genetic predisposition to Hg sensitivity
at low doses; and (e) parental reports of autistic children with
elevated Hg.
TRAIT
COMPARISON
ASD
manifests a constellation of symptoms with much inter-individual
variation (3,4). A comparison of traits defining, nearly universal
to, or commonly found in autism with those known to arise from mercury
poisoning is given in Table I. The characteristics defining or strongly
associated with autism are also more fully described.
Autism
has been conceived primarily as a psychiatric condition; and two
of its three diagnostic criteria are based upon the observable traits
of (a) impairments in sociality, most commonly social withdrawal
or aloofness, and (b) a variety of perseverative or stereotypic
behaviors and the need for sameness, which strongly resemble obsessive-compulsive
tendencies. Differential diagnosis may include childhood schizophrenia,
depression, obsessive-compulsive disorder (OCD), anxiety disorder,
and other neuroses. Related behaviors commonly found in ASD individuals
are irrational fears, poor eye contact, aggressive behaviors, temper
tantrums, irritability, and inexplicable changes in mood (1,2,12-17).
Mercury poisoning, when undetected, is often initially diagnosed
as a psychiatric disorder (18). Commonly occurring symptoms include
(a) "extreme shyness," indifference to others, active avoidance
of others, or "a desire to be alone"; (b) depression, "lack of interest"
and "mental confusion;" (c) irritability, aggression, and tantrums
in children and adults; (d) anxiety and fearfulness; and (e) emotional
lability. Neuroses, including schizoid and obsessive-compulsive
traits, problems in inhibition of perseveration, and stereotyped
behaviors, have been reported in a number of cases; and lack of
eye contact was observed in one 12 year old girl with mercury vapor
poisoning (18-35).
The
third diagnostic criterion for ASD is impairment in communication
(1). Historically, about half of those with classic autism failed
to develop meaningful speech (2), and articulation difficulties
are common (3). Higher functioning individuals may have language
fluency but still show semantic and pragmatic errors (3,36). In
many cases of ASD, verbal IQ is lower than performance IQ (3). Similarly,
mercury-exposed children and adults show a marked difficulty with
speech (9,19,37). In milder cases scores on language tests may be
lower than those of unexposed controls (31,38). Iraqi children who
were postnatally poisoned developed articulation problems, from
slow, slurred word production to an inability to generate meaningful
speech; while Iraqi babies exposed prenatally either failed to develop
language or presented with severe language deficits in childhood
(23,24,39). Workers with Mad Hatter's disease had word retrieval
and articulation difficulties (21).
Nearly
all cases of ASD and HgP involve disorders of physical movement
(2,30,40). Clumsiness or lack of coordination has been described
in many higher functioning ASD individuals (41). Infants and toddlers
later diagnosed with autism may fail to crawl properly or may fall
over while sitting or standing; and the movement disturbances typically
occur on the right side of the body (42). Problems with intentional
movement and imitation are common in ASD, as are a variety of unusual
stereotypic behaviors such as toe walking, rocking, abnormal postures,
choreiform movements, spinning; and hand flapping (2,3,43,44). Noteworthy
because of similarities to autism are reports in Hg literature of
(a) children in Iraq and Japan who were unable to stand, sit, or
crawl (34,39); (b) Minamata disease patients whose movement disturbances
were localized to one side of the body, and a girl exposed to Hg
vapor who tended to fall to the right (18,34); (c) flapping motions
in an infant poisoned from contaminated pork (37) and in a man injected
with thimerosal (27); (d) choreiform movements in mercury vapor
intoxication (19); (e) toe walking in a moderately poisoned Minamata
child (34); (f) poor coordination and clumsiness among victims of
acrodynia (45); (g) rocking among infants with acrodynia (11); and
(h) unusual postures observed in both acrodynia and mercury vapor
poisoning (11,31). The presence of flapping motions in both diseases
is of interest because it is such an unusual behavior that it has
been recommended as a diagnostic marker for autism (46).
Virtually
all ASD subjects show a variety of sensory abnormalities (2). Auditory
deficits are present in a minority of individuals and can range
from mild to profound hearing loss (2,47). Over- or under-reaction
to sound is nearly universal (2,48), and deficits in language comprehension
are often present (3). Pain sensitivity or insensitivity is common,
as is a general aversion to touch; abnormal sensation in the extremities
and mouth may also be present and has been detected even in toddlers
under 12 months old (2,49). There may be a variety of visual disturbances,
including sensitivity to light (2,50,51,52). As in autism, sensory
issues are reported in virtually all instances of Hg toxicity (40).
HgP can lead to mild to profound hearing loss (40); speech discrimination
is especially impaired (9,34,). Iraqi babies exposed prenatally
showed exaggerated reaction to noise (23), while in acrodynia, patients
reported noise sensitivity (45). Abnormal sensation in the extremities
and mouth is the most common sensory disturbance (25,28). Acrodynia
sufferers and prenatally exposed Iraqi babies exhibited excessive
pain when bumping limbs and an aversion to touch (23,24,45,53).
A range of visual problems has been reported, including photophobia
(18,23,34).
COMPARISON
OF BIOLOGICAL ABNORMALITIES
The
biological abnormalities commonly found in autism are listed in
Table II, along with the corresponding pathologies arising from
mercury exposure. Especially noteworthy similarities are described.
Autism
is a neurodevelopmental disorder which has been characterized as
"a disorder of neuronal organization, that is, the development of
the dentritic tree, synaptogenesis, and the development of the complex
connectivity within and between brain regions" (54). Depressed expression
of neural cell adhesion molecules (NCAMs), which are critical during
brain development for proper synaptic structuring, has been found
in one study of autism (55). Organic mercury, which readily crosses
the blood-brain barrier, preferentially targets nerve cells and
nerve fibers (56); primates accumulate the highest Hg-levels in
the brain relative to other organs (40). Furthermore, although most
cells respond to mercurial injury by modulating levels of glutathione
(GSH), metallothionein, hemoxygenase, and other stress proteins,
neurons tend to be "markedly deficient in these responses" and thus
are less able to remove Hg and more prone to Hg-induced injury (56).
In the developing brain, mercury interferes with neuronal migration,
depresses cell division, disrupts microtubule function, and reduces
NCAMs (28, 57-59).
While
damage has been observed in a number of brain areas in autism, many
nuclei and functions are spared (36). HgP's damage is similarly
selective (40). Numerous studies link autism with neuronal atypicalities
within the amygdala, hippocampi, basal ganglia, the Purkinje and
granule cells of the cerebellum, brainstem, basal ganglia, and cerebral
cortex (36,60-69). Each of these areas can be affected by HgP (10,34,40,70-73).
Migration of Hg, including eHg, into the amygdala is particularly
noteworthy, because in primates this brain region has neurons specific
for eye contact (74) and it is implicated in autism and in social
behaviors (65,66,75).
Autistic
brains show neurotransmitter irregularities which are virtually
identical to those arising from Hg exposure: both high or low serotonin
and dopamine, depending on the subjects studied; elevated epinephrine
and norepinephrine in plasma and brain; elevated glutamate; and
acetylcholine deficiency in hippocampus (2,21,76-83).
Gillberg
and Coleman (2) estimate that 35-45% of autistics eventually develop
epilepsy. A recent MEG study reported epileptiform activity in 82%
of 50 regressive autistic children; in another study, half the autistic
children expressed abnormal EEG activity during sleep (84). Autistic
EEG abnormalities tend to be non-specific and have a variety of
patterns (85). Unusual epileptiform activity has been found in a
number of mercury poisoning cases (18,27,34,86-88). Early mHg exposure
enhances tendencies toward epileptiform activity with a reduced
level of seizure-discharge amplitude (89), a finding consistent
with the subtlety of seizures in many autism spectrum children (84,85).
The fact that Hg increases extracellular glutamate would also contribute
to epileptiform activity (90).
Some
autistic children show a low capacity to oxidize sulfur compounds
and low levels of sulfate (91,92). These findings may be linked
with HgP because (a) Hg preferentially binds to sulfhydryl molecules
(-SH) such as cysteine and GSH, thereby impairing various cellular
functions (40), and (b) mercury can irreversibly block the sulfate
transporter NaSi cotransporter NaSi-1, present in kidneys and intestines,
thus reducing sulfate absorption (93). Besides low sulfate, many
autistics have low GSH levels, abnormal GSH-peroxidase activity
within erythrocytes, and decreased hepatic ability to detoxify xenobiotics
(91,94,95). GSH participates in cellular detoxification of heavy
metals (96); hepatic GSH is a primary substrate for organic-Hg clearance
from the human (40); and intraneuronal GSH participates in various
protective responses against Hg in the CNS (56). By preferentially
binding with GSH, preventing absorption of sulfate, or inhibiting
the enzymes of glutathione metabolism (97), Hg might diminish GSH
bioavailability. Low GSH can also derive from chronic infection
(98,99), which would be more likely in the presence of immune impairments
arising from mercury (100). Furthermore, mercury disrupts purine
and pyrimidine metabolism (97,10). Altered purine or pyrimidine
metabolism can induce autistic features and classical autism (2,101,102),
suggesting another mechanism by which Hg can contribute to autistic
traits.
Autistics
are more likely to have allergies, asthma, selective IgA deficiency
(sIgAd), enhanced expression of HLA-DR antigen, and an absence of
interleukin-2 receptors, as well as familial autoimmunity and a
variety of autoimmune phenomena. These include elevated serum IgG
and ANA titers, IgM and IgG brain antibodies, and myelin basic protein
(MBP) antibodies (103-110). Similarly, atypical responses to Hg
have been ascribed to allergic or autoimmune reactions (8), and
genetic predisposition to such reactions may explain why Hg sensitivity
varies so widely by individual (88,111). Children who developed
acrodynia were more likely to have asthma and other allergies (11);
IgG brain autoantibodies, MBP, and ANA have been found in HgP subjects
(18,111,112); and mice genetically prone to develop autoimmune diseases
"are highly susceptible to mercury-induced immunopathological alterations"
even at the lowest doses (113). Additionally, many autistics have
reduced natural killer cell (NK) function, as well as immune-cell
subsets shifted in a Th2 direction and increased urine neopterin
levels, indicating immune system activiation (103,114-116). Depending
upon genetic predisposition, Hg can induce immune activation, an
expansion of Th2 subsets, and decreased NK activity (117-120).
POPULATION
CHARACTERISTICS
In
most affected children, autistic symptoms emerge gradually, although
there are cases of sudden onset (3). The earliest abnormalities
have been detected in 4 month olds and consist of subtle movement
disturbances; subtle motor-sensory disturbances have been observed
in 9 month olds (49). More overt speech and hearing difficulties
become noticeable to parents and pediatricians between 12 and 18
months (2). TMS vaccines have been given in repeated intervals starting
from infancy and continuing until 12 to 18 months. While HgP symptoms,
may arise suddenly in especially sensitive individuals (11), usually
there is a pre-clinical "silent stage" in which subtle neurological
changes are occurring (121) and then a gradual emergence of symptoms.
The first symptoms are typically sensory and motor-related, which
are followed by speech and hearing deficits, and finally the full
array of HgP characteristics (40). Thus, both the timing and nature
of symptom emergence in ASD are fully consistent with a vaccinal
Hg etiology. This parallel is reinforced by parental reports of
excessive amounts of mercury in urine or hair from younger autistic
children, as well as some improvement in symptoms with standard
chelation therapy (122).
The
discovery and rise in prevalence of ASD mirrors the introduction
and spread of TMS in vaccines. Autism was first described in 1943
among children born in the 1930s (123). Thimerosal was first introduced
into vaccines in the 1930s (7). In studies conducted prior to 1970,
autism prevalence was estimated, at 1 in 2000; in studies from 1970
to 1990 it averaged 1 in 1000 (124). This was a period of increased
vaccination rates of the TMS-containing DPT vaccines among children
in the developed world. In the early 1990s, the prevalence of autism
was found to be 1 in 500 (125), and in 2000 the CDC found 1 in 150
children affected in one community, which was consistent with reports
from other areas in the country (126). In the late 1980s and early
1990s, two new TMS vaccines, the HIB and Hepatitis B, were added
to the recommended schedule (7).
Nearly
all US children are immunized, yet only a small proportion develop
autism. A pertinent characteristic of mercury is the great variability
in its effects by individual, so that at the same exposure level,
some will be affected severely while others will be asymptomatic
(9,11,28). An example is acrodynia, which arose in the early 20th
Century from mercury in teething powders and afflicted only 1 in
500-1000 children given the same low dose (28). Studies in mice
as well as humans indicate that susceptibility to Hg effects arises
from genetic status, in some cases including a propensity to autoimmune
disorders (113,34,40). ASD exhibits a strong genetic component,
with high concordance in monozygotic twins and a higher than expected
incidence among siblings (4); autism is also more prevalent in families
with autoimmune disorders (106).
Additionally,
autism is more prevalent among boys than girls, with the ratio estimated
at 4:1 (2). Mercury studies in mice and humans consistently report
greater effects on males than females, except for kidney damage
(57). At high doses, both sexes are affected equally; at low doses
only males are affected (38,40,127).
DISCUSSION
We
have shown that every major characteristic of autism has been exhibited
in at least several cases of documented mercury poisoning. Recently,
the FDA and AAP have revealed that the amount of mercury given to
infants from vaccinations has exceeded safety levels. The timing
of mercury administration via vaccines coincides with the onset
of autistic symptoms. Parental reports of autistic children with
measurable mercury levels in hair and urine indicate a history of
mercury exposure. Thus the standard primary criteria for a diagnosis
of mercury poisoning - observable symptoms, known exposure at the
time of symptom onset, and detectable levels in biologic samples
(11,31) - have been met in autism. As such, mercury toxicity may
be a significant etiological factor in at least some cases of regressive
autism. Further, each known form of HgP in the past has resulted
in a unique variation of mercurialism - e.g., Minamata disease,
acrodynia, Mad Hatter's disease - none of which has been autism,
suggesting that the Hg source which may be involved in ASD has not
yet been characterized; given that most infants receive eHg via
vaccines, and given that the effect on infants of eHg in vaccines
has never been studied (129), vaccinal thimerosal should be considered
a probable source. It is also possible that vaccinal eHg may be
additive to a prenatal mercury load derived from maternal amalgams,
immune globulin injections, or fish consumption, and environmental
sources.
CONCLUSION
The
history of acrodynia illustrates that a severe disorder, afflicting
a small but significant percentage of children, can arise from a
seemingly benign application of low doses of mercury. This review
establishes the likelihood that Hg may likewise be etiologically
significant in ASD, with the Hg derived from thimerosal in vaccines
rather than teething powders. Due to the extensive parallels between
autism and HgP, the likelihood of a causal relationship is great.
Given this possibility, TMS should be removed from all childhood
vaccines, and the mechanisms of Hg toxicity in autism should be
thoroughly investigated. With perhaps 1 in 150 children now diagnosed
with ASD, development of HgP-related treatments, such as chelation,
would
Order
Table
I: Summary Comparison of Traits of Autism & Mercury Poisoning
(ASD references in bold; HgP references in italics)
Psychiatric
Disturbances |
Social
deficits, shyness, social withdrawal (1,2,130,131; 21,31,45,53,132 |
Repetitive,
perseverative, stereotypic behaviors; obsessive-compulsive
tendencies (1,2,43,48,133; 20,33-35,132) |
Depression/depressive
traits, mood swings, flat affect; impaired face recognition
(14,15,17,103, 134,135; 19,21,24,26,31) |
Anxiety;
schizoid tendencies; irrational fears (2,15,16; 21,27,29,31) |
| |
Irritability,
aggression, temper tantrums (12,13,43; 18,21,22,25) |
Lacks
eye contact; impaired visual fixation (HgP)/ problems in joint
attention (ASD) (3,36,136,137; 18,19,34) |
Speech
and Language Deficits |
Loss
of speech, delayed language, failure to develop speech (1-3,138,139; 11,23,24,27,30,37) |
Dysarthria;
articulation problems (3; 21,25,27,39) |
Speech
comprehension deficits (3,4,140; 9,25,34,38) |
Verbalizing
and word retrieval problems (HgP); echolalia, word use and
pragmatic errors (ASD) (1,3,36; 21,27,70) |
Sensory
Abnormalities |
Abnormal
sensation in mouth and extremities (2,49; 25,28,34,39) |
Sound
sensitivity; mild to profound hearing loss (2,47,48; 19,23-25,39,40) |
Abnormal
touch sensations; touch aversion (2,49; 23,24,45,53) |
Over-sensitivity
to light; blurred vision (2,50,51; 18,23,31,34,45) |
Motor
Disorders |
Flapping,
myoclonal jerks, choreiform movements, circling, rocking,
toe walking, unusual postures (2,3,43,44; 11,19,27,30,31,34,39) |
Deficits
in eye-hand coordination; limb apraxia; intention tremors
(HgP)/problems with intentional movement or imitation (ASD)
(2,3,36,181; 25,29,32,38,70,87) |
Abnormal
gait and posture, clumsiness and incoordination; difficulties
sitting, lying, crawling, and walking; problem on one side
of body (4,41,42,123; 18,25,31,34,39,45) |
Cognitive
Impairments |
Borderline
intelligence, mental retardation - some cases reversible (2,3,151,152; 19,25,31,39,70) |
Poor
concentration, attention, response inhibition (HgP)/shifting
attention (ASD) (4,36,153; 21,25,31,38,141) |
Uneven
performance on IQ subtests; verbal IQ higher than performance
IQ (3,4,36; 31,38) |
Poor
short term, verbal, and auditory memory (36,140; 21,29,31,35,38,87,141) |
Poor
visual and perceptual motor skills; impairment in simple reaction
time (HgP)/ lower performance on timed tests (ASD) (4,140,181; 21,29,142) |
Deficits
in understanding abstract ideas & symbolism; degeneration
of higher mental powers (HgP)/sequencing, planning & organizing
(ASD); difficulty carrying out complex commands (3,4,36,153; 9,18,37,57,142) |
Unusual
Behaviors |
Self
injurious behavior, e.g. head banging (3,154; 11,18,53) |
ADHD
traits (2,36,155; 35,70) |
Agitation,
unprovoked crying, grimacing, staring spells 3,154; 11,23,37,88) |
Sleep
difficulties (2,156,157; 11,22,31) |
Physical
Disturbances |
Hyper-
or hypotonia; abnormal reflexes; decreased muscle strength,
especially upper body; incontinence; problems chewing, swallowing
(3,42,145,181; 19,27,31,32,39) |
Rashes,
dermatitis, eczema, itching (107,146; 22,26,143) |
Diarrhea;
abdominal pain/discomfort, constipation, "colitis" (107,147-149; 18,23,26,27,31,32) |
Anorexia;
nausea (HgP)/vomiting (ASD); poor appetite (HgP)/restricted
diet (ASD) (2,123; 18,22) |
Lesions
of ileum and colon; increased gut permeability (147,150; 57,144) |
Table
II: Summary Comparison of Biological Abnormalities
in Autism & Mercury Exposure
Mercury
Exposure |
Autism |
Biochemistry |
|
Binds
-SH groups; blocks sulfate transporter in intestines, kidneys
(40,93) |
Low
sulfate levels (91,92) |
Reduces
glutathione availability; inhibits enzymes of glutathione
metabolism; glutathione needed in neurons, cells, and liver
to detoxify heavy metals; reduces glutathione peroxidase
and reductase (97,100,161,162) |
Low
levels of glutathione; decreased ability of liver to detoxify
xenobiotics; abnormal glutathione peroxidase activity in
erythrocytes (91,94,95) |
Disrupts
purine and pyrimidine metabolism (10,97,158,159) |
Purine
and pyrimidine metabolism errors lead to autistic features
(2,101,102) |
Disrupts
mitochondrial activities, especially in brain (160,163,164) |
Mitochondrial
dysfunction, especially in brain (76,172) |
Immune
System |
|
Sensitive
individuals more likely to have allergies, asthma, autoimmune-like
symptoms, especially rheumatoid-like ones (8,11,18,24,28,31,111,113) |
More
likely to have allergies and asthma; familial presence of
autoimmune diseases, especially rheumatoid arthritis; IgA
deficiencies (103,106-109,115) |
Can
produce an immune response in CNS; causes brain/MBP autoantibodies
(18,111,165) |
On-going
immune response in CNS; brain/MBP autoantibodies present
(104,105,109,110) |
Causes
overproduction of Th2 subset; kills/inhibits lymphocytes,
T-cells, and monocytes; decreases NK T-cell activity; induces
or suppresses IFNg & IL-2 (100,112,117-120,166) |
Skewed
immune-cell subset in the Th2 direction; decreased responses
to T-cell mitogens; reduced NK T-cell function; increased
IFNg & IL-12 (103,108,114-116,173,174) |
CNS
Structure |
|
Selectively
targets brain areas unable to detoxify or reduce Hg-induced
oxidative stress (40,56,161) |
Specific
areas of brain pathology; many functions spared (36) |
Accummulates
in amygdala, hippocampus, basal ganglia, cerebral cortex;
damages Purkinje and granule cells in cerebellum; brain
stem defects in some cases (10,34,40,70-73) |
Pathology
in amygdala, hippocampus, basal ganglia, cerebral cortex;
damage to Purkinje and granule cells in cerebellum; brain
stem defects in some cases (36,60-69) |
Causes
abnormal neuronal cytoarchitecture; disrupts neuronal migration,
microtubules, and cell division; reduces NCAMs (10,28,57-59,161) |
Neuronal
disorganization; increased neuronal cell replication, increased
glial cells; depressed expression of NCAMs (4,54,55) |
Progressive
microcephaly (24) |
Progressive
microcephaly and macrocephaly (175) |
Neuro-chemistry |
|
Prevents
presynaptic serotonin release and inhibits serotonin transport;
causes calcium disruptions (78,79,163,167,168) |
Decreased
serotonin synthesis in children; abnormal calcium metabolism
(76,77,103,179) |
Alters
dopamine systems; peroxidine deficiency in rats resembles
mercurialism in humans (8,80) |
Either
high or low dopamine levels; positive response to peroxidine,
which lowers dopamine levels (2,177,178) |
Elevates
epinephrine and norepinephrine levels by blocking enzyme
that degrades epinephrine (81,160) |
Elevated
norepinephrine and epinephrine (2) |
Elevates
glutamate (21,171) |
Elevated
glutamate and aspartate (82,176) |
Leads
to cortical acetylcholine deficiency; increases muscarinic
receptor density in hippocampus and cerebellum (57,170) |
Cortical
acetylcholine deficiency; reduced muscarinic receptor binding
in hippocampus (83) |
Causes
demyelinating neuropathy (22,169) |
Demyelination
in brain (105) |
Neurophysiology |
|
Causes
abnormal EEGs, epileptiform activity, variable patterns,
e.g., subtle, low amplitude seizure activities (27,31,34,86-89) |
Abnormal
EEGs, epileptiform activity, variable patterns, including
subtle, low amplitude seizure activities (2,4,84,85) |
Causes
abnormal vestibular nystagmus responses; loss of sense of
position in space (9,19,34,70) |
Abnormal
vestibular nystagmus responses; loss of sense of position
in space (27,180) |
Results
in autonomic disturbance: excessive sweating, poor circulation,
elevated heart rate (11,18,31,45) |
Autonomic
disturbance: unusual sweating, poor circulation, elevated
heart rate (17,180) |
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