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This
publication was supported by Grant No. Grant No.
H4BHS00029 from the Health Resources and Services
Administration’s Division of Healthcare Preparedness, Poison Control
Program (PCP), U.S. Department of Health and Human Services. The contents
of this publication/presentation are solely the responsibility of the author(s)
and do not necessarily represent the views of HRSA/PCP.
CALL US...TM
The
Official Newsletter of the
Volume 5,
Number 5.
Fall 2007
Thallium
Poisoning
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Introduction
Thallium was accidentally discovered
in 1861 by Sir William Crookes, who noted an unexpected green banding on
colorimetric spectroscopy, while researching tellurium ore (Greek, thallos:
“green young shoot”). Thallium is a metal with a storied
history of medicinal and commercial applications as a depilatory, syphilis
remedy, rodenticide, ant killer, and in the manufacturing of photocells and
semiconductors. Today, medicinal use is
limited to trace amounts of radioactive thallium for nuclear imaging. Thallium is a tasteless, odorless, and
extremely potent poison – acute ingestions of as little as one gram of
thallium salt may kill an adult.
Thallium is a well-known poison cited in numerous works of fictional
literature, but is also a popular real-life agent of murder with worldwide
homicidal usage documented since the 1800s.
Case presentation
A 26-year-old man developed
nausea, abdominal cramping, and mildly bloody diarrhea, 9 hours after a
suicidal ingestion of illegally imported rat poison. He had clinical signs of dehydration and
laboratory evidence of fluid depletion and was admitted overnight for treatment
of dehydration. The next day, he
developed a feeling of “pins and needles” in the lower extremities,
followed by pain, burning sensations, and weakness in both upper and lower
distal extremities over the next 12 hours.
During this time, he had over 10 episodes of diarrhea, and became
slightly confused, and moderately diaphoretic.
Electrocardiogram revealed intermittent runs of supraventricular
tachycardia. Urinalysis revealed trace
urine protein and specific gravity of 1.020.
Complete blood count and serum electrolytes were found to be within
normal limits.
On Day 2, the patient
continued with severe pain, discomfort, weakness, waxing-and-waning lethargy,
and confusion. During a period of
lucidity, he disclosed that he ingested a large amount of illegal rat poison
from the “Old Soviet Union”.
Thallium toxicity was suspected and he was prepared for
hemodialysis. He was started on an oral
antidote every six hours, and underwent two 4-hour runs of hemodialysis. Urine thallium level was noted to be 1285
mcg/L. The patient’s mental status
began to normalize and other symptoms improved very slowly each day as he
continued on the oral antidote. By day
10, the patient was able to walk without assistance. When he walked to the bathroom to brush his
hair, his noted several clumps of hair in his hairbrush.
Questions:
1. Why did hair loss take so
long to occur after acute exposure to thallium?
2. What was the oral
antidote? How does it work?
Epidemiology
Commercial and consumer use of
thallium as a rodenticide or insecticide was banned in the
Pathophysiology
Although ingestion is the
most common route of exposure thallium may also be absorbed by inhalation or
skin penetration. Thallium and its salts
are corrosive to the gastrointestinal mucosa, leading to abdominal pain,
intestinal fluid secretion, diarrhea, and vomiting. After absorption, thallium distributes widely
to multiple organs with a distribution pattern similar to that of potassium ions,
which have a similar atomic radius to thallium.
Thallium deposition therefore occurs primarily in tissues with high
potassium concentrations such as neuronal, myocardial, hepatic, renal, and
dermal tissues. In contrast to more common
heavy metal exposures such as lead, mercury, or arsenic, long-term, low-level exposure
to thallium does not typically lead to accumulation in body tissues for an extended
duration. Thallium replaces potassium in
numerous potassium-dependent enzyme systems usually with superior affinity over
potassium. Affected enzyme systems
include pyruvate kinase, succinic dehydrogenase,
sodium-potassium-ATPase, hemoserine dehydrogenase, vitamin B12-dependent diol
dehydrogenase, guanine deamiase,
L-threonine dehydrogenase,
monoamine oxidase, acid phosphatase, and cathepsin. In
addition, thallium damages the 60s subunit of ribosomes,
resulting in impaired protein synthesis.
The combined effect of these acute cellular dysfunctions is the failure
of aerobic respiration and poor cellular energy production. In the peripheral nervous system, thallium
causes a “dying-back” or Wallerian
degenerative sensory neuropathy due to acute myelin fragmentation and axonal
degeneration. This process is mediated
by mitochondrial dysfunction, swelling, and vacuolization from inhibition of pyruvate kinase and succinic dehydrogenase and
subsequent decrease in ATP production.
Motor neuropathy may occur with severe acute exposures, as high thallium
concentrations impair depolarization of muscle fibers. Central nervous system findings are mediated
by multi-focal edematous changes and chromatolysis,
particularly in the frontal lobe, motor cortex, basal ganglia, and pyramidal
cells. Similar changes are noted in the
ganglia of the spinal cord in chronic poisoning. Inhaled or ingested thallium induces pulmonary
inflammation and hyaline membrane formation.
High doses of thallium directly damage the myocardium with myocardial
thinning, lipid droplet infiltration, necrosis, and inflammatory changes. Thallium damages kidney tissue, most likely
via infarction. Hepatic findings in severe
cases may include centrilobular necrosis with fatty infiltration; however, most
cases of thallium poisoning result in mild hepatic inflammation. Hair loss is caused by stunted mitosis of
hair follicle epithelial cells, and by destruction of hair shaft cells.
Clinical presentation
Signs and symptoms of
thallium ingestion often begin with a non-febrile gastroenteritis, severe
abdominal pain, cramping, vomiting, and diarrhea during the first 6 hours after
exposure. Gastrointestinal symptoms last
for 12-96 hours. Constipation often
occurs for several days after diarrhea has resolved. Patients with chronic poisoning may have few
or no gastrointestinal findings.
Thallium inhalation leads initially to non-febrile cough and pleuritic
chest pain, persisting for several days.
After 1-5 days, systemic symptoms begin to develop. Neurological symptoms usually predominate
secondary to the predilection of thallium for nerve tissue. Findings include painful, rapidly ascending,
sensory neuropathy. Motor neuropathy may
accompany sensory neuropathy, but rarely occurs alone. Patients commonly complain of severe pain and
burning in the feet, difficulty walking, skeletal muscle cramps, and
“stocking-glove” numbness and tingling. Both oral and inhalational exposures may lead
to pneumonitis, ARDS, and pulmonary edema.
Respiratory depression may occur from neurological dysfunction of the
respiratory muscles. Dysfunction of cranial
nerves II, III, IV, and VI which govern oculomotor
and visual function are most common. Nystagmus,
confusion, anxiety, tremor, ataxia, optic neuritis, altered mental status,
seizures, and coma may also occur.
Peripheral and cranial nerve findings may persist for several
weeks-to-months after exposure, and may be permanent in severe cases. Some patients may endure persistent
short-term memory and cognitive deficits.
Cardiac effects include sinus bradycardia or tachycardia, and
ventricular dysrhythmias in severe cases.
Rapidly fatal cases of thallium poisoning are likely to result from acute
myocardial injury. Renal findings occur
within the first several days after exposure and include proteinuria,
diminished creatinine clearance, elevated blood urea nitrogen, and acute
tubular necrosis. Urine may have a
slight green discoloration. Hepatic
failure or jaundice occurs in extreme cases.
Alopecia, a hallmark of thallium poisoning, occurs 7-12 days after other
symptoms begin. Hair loss commonly
involves the scalp, often involves body hair, and is generally not
permanent. Complete hair loss usually
occurs by one month post-exposure. Mees lines, horizontal white depositions in the nails, may
be observed up to 4 weeks after exposure, but are not specific. Alopecia and neuropathy may be the only
presenting symptoms in cases of chronic thallium poisoning.
Diagnosis
Thallium poisoning should be
suspected in any patient with neurological symptoms and hair loss. Gastrointestinal findings may be mild or
nonexistent, especially in chronic poisoning.
Thallium blood levels may be elevated after recent exposures, but it is
cleared from the blood relatively quickly.
Cases of known thallium exposure may be confirmed easily by early blood
testing with quantitative atomic absorption.
The diagnosis of thallium poisoning may not be considered until several
days after exposure – typically when hair loss begins – by which
time blood levels may have decreased significantly. Measurable urine concentrations of thallium
tend to persist for several days after exposure, and may be used to monitor
treatment. A 24-hour urine thallium
concentration is the most accurate way to assess thallium toxicity; however, a
“spot” urine level provides more rapid confirmation. Acute toxicity will produce a thallium
concentration many times higher than the reference range of 0-5 mcg/L. Injection of large boluses of potassium to
enhance urinary thallium excretion before urine sampling, also known as
“potassium mobilization” (described below) is not advised, as this
practice may precipitate cardiac and neurological toxicity. Both blood and urine levels should be
obtained in cases of known or suspected thallium poisoning. Hair testing for thallium may provide
additional confirmation of thallium exposure in the presence of strongly
positive urine and blood results; however, hair testing is a highly unreliable
method of diagnosing acute or chronic thallium poisoning, and is generally not
recommended. Experienced pathologists
may detect a characteristic pattern of black pigmentation at the roots of scalp
hair in thallium-poisoned patients. Electrocardiography may demonstrate prolongation of
the QTc interval, non-specific T-wave changes, and dysrhythmias. Serum transaminases
and alkaline phosphatase may be elevated. Complete blood count may reveal anemia from
gastrointestinal hemorrhage. Plain
abdominal radiography may show opacities due to heavy metal retention in the
gastrointestinal tract; however, absence of radiographic findings may be
misleading and does not exclude retained metal. Electromyelography may reveal diminished neuromuscular transmission,
and electroretinography may demonstrate delayed
visual evoked response. These findings
may precede clinical symptoms. The
differential diagnosis of thallium poisoning includes arsenic poisoning,
selenium poisoning, colchicine poisoning, Guillain-Barre Syndrome (GBS), and botulism. Serum or urine determinations of arsenic,
selenium, or colchicine may rule out these poisonings,
but may be difficult to obtain rapidly.
Hair loss following neurological symptoms is a useful clue to exclude
GBS and botulism.
Treatment
Patients with very recent ingestions
of thallium should be treated with activated charcoal. Although most metals bind poorly to activated
charcoal, thallium is an exception and binds well. Patients with radiographic evidence of
retained thallium in the gastrointestinal tract may benefit from whole bowel
irrigation with polyethylene glycol solution (see http://www.calpoison.org/hcp/2003/callusvol1no4.html “Call Us… Whole Bowel
Irrigation”, Jun 2003 Vol. 1 No. 4).
Extracorporeal removal of thallium using hemodialysis
or hemoperfusion should take place as early as
possible during the course of poisoning.
Hemodialysis is most beneficial when blood levels are high, before
tissue distribution has taken place.
After systemic signs develop, dialysis reveals inconsistent
results. Although excretion of thallium
is nominally enhanced with dialysis, this procedure may accelerate the
redistribution of thallium out of tissues such as the central nervous
system. Therefore, hemodialysis should
be performed in most symptomatic patients with acute thallium poisoning in
conjunction with other treatments.
Prussian Blue, an FDA-approved antidote for
cesium and thallium poisonings, is a potassium-rich oral cation
exchange resin. Potassium is exchanged preferentially for thallium entering the
enterohepatic circulation. As Prussian Blue
sequesters thallium, a concentration gradient is established for the continued
movement of thallium into the gut.
Dosing of Prussian Blue is 250 mg/kg/day,
divided every 6-12 hours. Constipation
may complicate Prussian Blue administration, and may
be attenuated by the addition of a cathartic such as mannitol. Duration of treatment with Prussian Blue is not well-studied. Case reports have suggested this
therapy can be safely discontinued when spot urine thallium levels are <100
mcg/L. Patients with persistent
neurological findings may require physical or occupational therapy for several weeks-to-months
after acute toxicity is treated. Hair
growth spontaneously returns to normal over days or weeks. Multiple-dose activated charcoal (MDAC) may
enhance thallium excretion by interruption of enterohepatic
circulation; however, human models of toxicity have not demonstrated clinical
benefit to MDAC. Forced diuresis
provides no clinical benefit in the treatment of thallium poisoning. Some proposed treatments attempt to take
advantage of the similarities between cellular handling of potassium and
thallium. For example, the
administration of potassium blocks renal tubular reabsorption of thallium, thus
enhancing excretion up to 300%; however, potassium administration also
mobilizes thallium from tissue depots, thus making more thallium available to
the central nervous system. Therefore,
“potassium mobilization” is not advised as either a diagnostic
challenge nor as a treatment modality. Sodium polystyrene sulfonate
(Kayexelate®) is a proposed treatment, demonstrating
excellent in vitro binding to
thallium. However, polystyrene binds
preferentially to potassium, not thallium, in
vivo, and is not recommended because of its potential to cause
hypokalemia. Thallium binds poorly to
medicinal chelators, such as Ca-Na-EDTA, British anti-Lewisite
(BAL), and DMPS. D-penicillamine
may worsen thallium toxicity. Other
proposed pharmaceutical treatments, such as N-acetylcyesteine,
diphenylthiocarbazone, and dithiocarb
may increase thallium excretion, but are not recommended, because they are
ineffective or may worsen neurological toxicity.
Discussion of case questions
1.
Alopecia
is a very common characteristic of thallium poisoning; however, hair loss is
often delayed by 7-12 days after symptoms begin, and this delay may be
inversely dependent on dose.
2.
The
oral antidote for thallium poisoning is Prussian Blue. In combination with hemodialysis and
supportive care, Prussian Blue enhances thallium
excretion, and may speed recovery by exchanging potassium for thallium in the
gastrointestinal tract.
Consultation assistance
Consultation with a
specialist in poison information or with a medical toxicologist can be obtained
free of charge by calling the California Poison Control System at
1-800-222-1222.
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