Mercury poisoning

Mercury poisoning
mercury toxicity, mercury overdose, mercury intoxication, hydrargyria, mercurialism

Specialty toxicology
Symptoms muscle weakness, poor coordination, numbness in the hands and feet[1]
Causes Exposure to mercury[1]
Diagnostic method difficult[2]
Prevention decreasing use of mercury, low mercury diet[3]
Medication acute poisoning: dimercaptosuccinic acid (DMSA), dimercaptopropane sulfonate (DMPS)[4]

Mercury poisoning is a type of metal poisoning, due to exposure to mercury.[2] Symptoms may include muscle weakness, poor coordination, numbness in the hands and feet, skin rashes, memory problems, trouble speaking, trouble hearing, or trouble seeing.[1] Symptoms depend upon the type, dose, method, and duration of exposure.[2][3] The effects of long term low dose exposure to methylmercury is unclear.[5] High level exposure to methylmercury is known as Minamata disease.[6] Exposure in children may result in acrodynia (Pink's disease) in which the skin becomes pink and peels.[6]

Mercury (chemical symbol Hg) exposure may occur in number of forms including: metal, vapor, salt, and organic compound. Most exposure is from eating fish, amalgam based dental fillings, or exposure at work. In fish, those higher up in the food chain generally have higher levels of mercury. Less commonly poisoning may occur as an attempt to end one's life.[2] Human activities that release mercury into the environment include the burning of coal and mining of gold.[3] Tests of the blood, urine, and hair for mercury are available but do not relate well to the amount in the body.[2]

Prevention includes eating a diet low in mercury, removing mercury from medical and other devices, proper disposal of mercury, and not mining further mercury.[3][6] In those with acute poisoning from inorganic mercury salts, chelation with either dimercaptosuccinic acid (DMSA) or dimercaptopropane sulfonate (DMPS) appears to improve outcomes if given within a few hours of exposure.[4] Chelation for those with long term exposure is of unclear benefit.[4] Long term complications may include kidney problems and decreased intelligence.[6] In certain communities which survive on fishing, rates of mercury poisoning among children are as high as 1.7 per 100.[3]

Signs and symptoms

Common symptoms of mercury poisoning include peripheral neuropathy, presenting as paresthesia or itching, burning, pain, or even a sensation that resembles small insects crawling on or under the skin (formication); skin discoloration (pink cheeks, fingertips and toes); swelling; and desquamation (shedding or peeling of skin).

Mercury irreversibly inhibits selenium-dependent enzymes (see below) and may also inactivate S-adenosyl-methionine, which is necessary for catecholamine catabolism by catechol-O-methyl transferase. Due to the body's inability to degrade catecholamines (e.g. epinephrine), a person suffering from mercury poisoning may experience profuse sweating, tachycardia (persistently faster-than-normal heart beat), increased salivation, and hypertension (high blood pressure).

Affected children may show red cheeks, nose and lips, loss of hair, teeth, and nails, transient rashes, hypotonia (muscle weakness), and increased sensitivity to light. Other symptoms may include kidney dysfunction (e.g. Fanconi syndrome) or neuropsychiatric symptoms such as emotional lability, memory impairment, or insomnia.

Thus, the clinical presentation may resemble pheochromocytoma or Kawasaki disease. Desquamation (skin peeling) can occur with severe mercury poisoning acquired by handling elemental mercury.[7]

Causes

The consumption of fish is by far the most significant source of ingestion-related mercury exposure in humans, although plants and livestock also contain mercury due to bioconcentration of mercury from seawater, freshwater, marine and lacustrine sediments, soils, and atmosphere, and due to biomagnification by ingesting other mercury-containing organisms.[8] Exposure to mercury can occur from breathing contaminated air,[9] from eating foods that have acquired mercury residues during processing,[10] from exposure to mercury vapor in mercury amalgam dental restorations,[11] and from improper use or disposal of mercury and mercury-containing objects, for example, after spills of elemental mercury or improper disposal of fluorescent lamps.[12]

All of these, except elemental liquid mercury produce toxicity or death with less than a gram. Mercury's zero oxidation state (Hg0) exists as vapor or as liquid metal, its mercurous state (Hg+) exists as inorganic salts, and its mercuric state (Hg2+) may form either inorganic salts or organomercury compounds.

Consumption of whale and dolphin meat, as is the practice in Japan, is a source of high levels of mercury poisoning. Tetsuya Endo, a professor at the Health Sciences University of Hokkaido, has tested whale meat purchased in the whaling town of Taiji and found mercury levels more than 20 times the acceptable Japanese standard.[13]

Human-generated sources, such as coal-burning power plants [14] emit about half of atmospheric mercury, with natural sources such as volcanoes responsible for the remainder. An estimated two-thirds of human-generated mercury comes from stationary combustion, mostly of coal. Other important human-generated sources include gold production, nonferrous metal production, cement production, waste disposal, human crematoria, caustic soda production, pig iron and steel production, mercury production (mostly for batteries), and biomass burning.[15]

Small independent gold-mining operation workers are at higher risk of mercury poisoning because of crude processing methods. Such is the danger for the galamsey in Ghana and similar workers known as orpailleurs in neighboring francophone countries. While no official government estimates of the labor force have been made, observers believe 20,000-50,000 work as galamseys in Ghana, a figure including many women, who work as porters. Similar problems have been reported amongst the gold miners of Indonesia.[16]

Mercury and many of its chemical compounds, especially organomercury compounds, can also be readily absorbed through direct contact with bare, or in some cases (such as methylmercury) insufficiently protected, skin. Mercury and its compounds are commonly used in chemical laboratories, hospitals, dental clinics, and facilities involved in the production of items such as fluorescent light bulbs, batteries, and explosives.[17]

No scientific data support the claim that mercury compounds in vaccine preservatives cause autism[18] or its symptoms.[19]

Sources

Compounds of mercury tend to be much more toxic than either the elemental or the salts. These compounds have been implicated in causing brain and liver damage. The most dangerous mercury compound, dimethylmercury, is so toxic that even a few microliters spilled on the skin, or even on a latex glove, can cause death, as in the case of Karen Wetterhahn.[20][21]

Methylmercury and related organomercury compounds

Main article: Mercury in fish

Methylmercury is the major source of organic mercury for all individuals.[22] Due to bioaccumulation it works its way up through the food web and thus biomagnifies, resulting in high concentrations among populations of some species. Top predatory fish, such as tuna or swordfish, are usually of greater concern than smaller species. The US FDA and the EPA advise women of child-bearing age, nursing mothers, and young children to completely avoid swordfish, shark, king mackerel and tilefish from the Gulf of Mexico, and to limit consumption of albacore ("white") tuna to no more than 6 oz (170 g) per week, and of all other fish and shellfish to no more than 12 oz (340 g) per week.[23] A 2006 review of the risks and benefits of fish consumption found, for adults, the benefits of one to two servings of fish per week outweigh the risks, even (except for a few fish species) for women of childbearing age, and that avoidance of fish consumption could result in significant excess coronary heart disease deaths and suboptimal neural development in children.[24]

The period between exposure to methylmercury and the appearance of symptoms in adult poisoning cases is long. The longest recorded latent period is five months after a single exposure, in the Dartmouth case (see History); other latent periods in the range of weeks to months have also been reported. No explanation for this long latent period is known. When the first symptom appears, typically paresthesia (a tingling or numbness in the skin), it is followed rapidly by more severe effects, sometimes ending in coma and death. The toxic damage appears to be determined by the peak value of mercury, not the length of the exposure.[25]

Methylmercury exposure during rodent gestation, a developmental period that approximately models human neural development during the first two trimesters of gestation,[26][27] has long-lasting behavioral consequences that appear in adulthood and, in some cases, may not appear until aging. Prefrontal cortex or dopamine neurotransmission could be especially sensitive to even subtle gestational methylmercury exposure[28] and suggests that public health assessments of methylmercury based on intellectual performance may underestimate the impact of methylmercury in public health.

Ethylmercury is a breakdown product of the antibacteriological agent ethylmercurithiosalicylate, which has been used as a topical antiseptic and a vaccine preservative (further discussed under Thiomersal below). Its characteristics have not been studied as extensively as those of methylmercury. It is cleared from the blood much more rapidly, with a half-life of seven to 10 days, and it is metabolized much more quickly than methylmercury. It is presumed not to have methylmercury's ability to cross the blood–brain barrier via a transporter, but instead relies on simple diffusion to enter the brain.[22] Other exposure sources of organic mercury include phenylmercuric acetate and phenylmercuric nitrate. These compounds were used in indoor latex paints for their antimildew properties, but were removed in 1990 because of cases of toxicity.[22]

Inorganic mercury compounds

Mercury occurs as salts such as mercuric chloride (HgCl2) and mercurous chloride (Hg2Cl2), the latter also known as calomel. Because they are more soluble in water, mercuric salts are usually more acutely toxic than mercurous salts. Their higher solubility allows them to be more readily absorbed from the gastrointestinal tract. Mercury salts affect primarily the gastrointestinal tract and the kidneys, and can cause severe kidney damage; however, as they cannot cross the blood–brain barrier easily, these salts inflict little neurological damage without continuous or heavy exposure.[29][29] Mercuric cyanide (Hg(CN)2) is a particularly toxic mercury compound that has been used in murders, as it contains not only mercury but also cyanide, leading to simultaneous cyanide poisoning.[30] The drug n-acetyl penicillamine has been used to treat mercury poisoning with limited success.[31]

Elemental mercury

Quicksilver (liquid metallic mercury) is poorly absorbed by ingestion and skin contact. Its vapor is the most hazardous form. Animal data indicate less than 0.01% of ingested mercury is absorbed through the intact gastrointestinal tract, though it may not be true for individuals suffering from ileus. Cases of systemic toxicity from accidental swallowing are rare, and attempted suicide via intravenous injection does not appear to result in systemic toxicity,[25] though it still causes damage by physically blocking blood vessels both at the site of injection and the lungs. Though not studied quantitatively, the physical properties of liquid elemental mercury limit its absorption through intact skin and in light of its very low absorption rate from the gastrointestinal tract, skin absorption would not be high.[32] Some mercury vapor is absorbed dermally, but uptake by this route is only about 1% of that by inhalation.[33]

In humans, approximately 80% of inhaled mercury vapor is absorbed via the respiratory tract, where it enters the circulatory system and is distributed throughout the body.[34] Chronic exposure by inhalation, even at low concentrations in the range 0.7–42 μg/m3, has been shown in case control studies to cause effects such as tremors, impaired cognitive skills, and sleep disturbance in workers.[35][36]

Acute inhalation of high concentrations causes a wide variety of cognitive, personality, sensory, and motor disturbances. The most prominent symptoms include tremors (initially affecting the hands and sometimes spreading to other parts of the body), emotional lability (characterized by irritability, excessive shyness, confidence loss, and nervousness), insomnia, memory loss, neuromuscular changes (weakness, muscle atrophy, muscle twitching), headaches, polyneuropathy (paresthesia, stocking-glove sensory loss, hyperactive tendon reflexes, slowed sensory and motor nerve conduction velocities), and performance deficits in tests of cognitive function.[32]

Mechanism

The toxicity of mercury sources can be expected to depend on its nature, i.e., salts vs. organomercury compounds vs. elemental mercury.

One mechanism of mercury toxicity involves its irreversible inhibition of selenoenzymes, such as thioredoxin reductase (IC50 = 9 nM).[37] Although it has many functions, thioredoxin reductase restores vitamins C and E, as well as a number of other important antioxidant molecules, back into their reduced forms, enabling them to counteract oxidative damage.[38] Since the rate of oxygen consumption is particularly high in brain tissues, production of reactive oxygen species (ROS) is accentuated in these vital cells, making them particularly vulnerable to oxidative damage and especially dependent upon the antioxidant protection provided by selenoenzymes. High mercury exposures deplete the amount of cellular selenium available for the biosynthesis of thioredoxin reductase and other selenoenzymes that prevent and reverse oxidative damage,[39] which, if the depletion is severe and long lasting, results in brain cell dysfunctions that can ultimately cause death.

Mercury in its various forms is particularly harmful to fetuses as an environmental toxin in pregnancy, as well as to infants. Women who have been exposed to mercury in substantial excess of dietary selenium intakes during pregnancy are at risk of giving birth to children with serious birth defects. Mercury exposures in excess of dietary selenium intakes in young children can have severe neurological consequences, preventing nerve sheaths from forming properly. Mercury inhibits the formation of myelin.

Diagnosis

Diagnosis of elemental or inorganic mercury poisoning involves determining the history of exposure, physical findings, and an elevated body burden of mercury. Although whole-blood mercury concentrations are typically less than 6 μg/L, diets rich in fish can result in blood mercury concentrations higher than 200 μg/L; it is not that useful to measure these levels for suspected cases of elemental or inorganic poisoning because of mercury's short half-life in the blood. If the exposure is chronic, urine levels can be obtained; 24-hour collections are more reliable than spot collections. It is difficult or impossible to interpret urine samples of patients undergoing chelation therapy, as the therapy itself increases mercury levels in the samples.[40]

Diagnosis of organic mercury poisoning differs in that whole-blood or hair analysis is more reliable than urinary mercury levels.[40]

Prevention

Mercury poisoning can be prevented (or minimized) by eliminating or reducing exposure to mercury and mercury compounds. To that end, many governments and private groups have made efforts to regulate heavily the use of mercury, or to issue advisories about its use. For example, the export from the European Union of mercury and some mercury compounds has been prohibited since the 15th of March, 2010.[41] The variability among regulations and advisories is at times confusing for the lay person as well as scientists.

[42]
Country Regulating agency Regulated activity Medium Type of mercury compound Type of limit Limit
US Occupational Safety and Health Administration occupational exposure air elemental mercury Ceiling (not to exceed) 0.1 mg/m³
US Occupational Safety and Health Administration occupational exposure air organic mercury Ceiling (not to exceed) 0.05 mg/m³
US Food and Drug Administration eating sea food methylmercury Maximum allowable concentration 1 ppm (1 mg/L)
US Environmental Protection Agency drinking water inorganic mercury Maximum contaminant level 2 ppb (0.002 mg/L)

The United States Environmental Protection Agency (EPA) issued recommendations in 2004 regarding exposure to mercury in fish and shellfish.[43] The EPA also developed the "Fish Kids" awareness campaign for children and young adults [44] on account of the greater impact of mercury exposure to that population.

Cleaning spilled mercury

Mercury thermometers and mercury light bulbs are not as common as they used to be, and the amount of mercury they contain is unlikely to be a health concern if handled carefully. However, broken items still require careful cleanup, as mercury can be hard to collect and it is easy to accidentally create a much larger exposure problem.[45]

Treatment

Identifying and removing the source of the mercury is crucial. Decontamination requires removal of clothes, washing skin with soap and water, and flushing the eyes with saline solution as needed.

Chelation therapy for acute inorganic mercury poisoning can be done with DMSA, 2,3-dimercapto-1-propanesulfonic acid (DMPS), D-penicillamine (DPCN), or dimercaprol (BAL).[22] Only DMSA is FDA-approved for use in children for treating mercury poisoning. However, several studies found no clear clinical benefit from DMSA treatment for poisoning due to mercury vapor.[46] No chelator for methylmercury or ethylmercury is approved by the FDA; DMSA is the most frequently used for severe methylmercury poisoning, as it is given orally, has fewer side-effects, and has been found to be superior to BAL, DPCN, and DMPS.[22] α-Lipoic acid (ALA) has been shown to be protective against acute mercury poisoning in several mammalian species when it is given soon after exposure; correct dosage is required, as inappropriate dosages increase toxicity. Although it has been hypothesized that frequent low dosages of ALA may have potential as a mercury chelator, studies in rats have been contradictory.[47] Glutathione and N-acetylcysteine (NAC) are recommended by some physicians, but have been shown to increase mercury concentrations in the kidneys and the brain.[47] Experimental findings have demonstrated an interaction between selenium and methylmercury, but epidemiological studies have found little evidence that selenium helps to protect against the adverse effects of methylmercury.[48]

Chelation therapy can be hazardous if administered incorrectly. In August 2005, an incorrect form of EDTA (edetate disodium) used for chelation therapy resulted in hypocalcemia, causing cardiac arrest that killed a five-year-old autistic boy.[49]

Prognosis

Some of the toxic effects of mercury are partially or wholly reversible, either through specific therapy or through natural elimination of the metal after exposure has been discontinued.[50] Autopsy findings point to a half-life of inorganic mercury in human brains of 27.4 years.[51] Heavy or prolonged exposure can do irreversible damage, in particular in fetuses, infants, and young children. Young's syndrome is believed to be a long-term consequence of early childhood mercury poisoning.[52] Mercuric chloride may cause cancer as it has caused increases in several types of tumors in rats and mice, while methyl mercury has caused kidney tumors in male rats. The EPA has classified mercuric chloride and methyl mercury as possible human carcinogens (ATSDR, EPA)

Detection in biological fluids

Mercury may be measured in blood or urine to confirm a diagnosis of poisoning in hospitalized people or to assist in the forensic investigation in a case of fatal overdosage. Some analytical techniques are capable of distinguishing organic from inorganic forms of the metal. The concentrations in both fluids tend to reach high levels early after exposure to inorganic forms, while lower but very persistent levels are observed following exposure to elemental or organic mercury. Chelation therapy can cause a transient elevation of urine mercury levels.[53]

History

Infantile acrodynia

For more details on this topic, see Acrodynia.

Infantile acrodynia (also known as "calomel disease", "erythredemic polyneuropathy", and "pink disease") is a type of mercury poisoning in children characterized by pain and pink discoloration of the hands and feet.[70] The word is derived from the Greek, where άκρο means end (as in: upper extremity) and οδυνη means pain. Acrodynia resulted primarily from calomel in teething powders and decreased greatly after calomel was excluded from most teething powders in 1954.[71][72]

Acrodynia is difficult to diagnose, "it is most often postulated that the etiology of this syndrome is an idiosyncratic hypersensitivity reaction to mercury because of the lack of correlation with mercury levels, many of the symptoms resemble recognized mercury poisoning."[73]

Medicine

Mercury was once prescribed as a purgative. Many mercury-containing compounds were once used in medicines.

Thiomersal

For more details on this topic, see Thiomersal controversy.

In 1999, the Centers for Disease Control (CDC) and the American Academy of Pediatrics (AAP) asked vaccine makers to remove the organomercury compound thiomersal (spelled "thimerosal" in the US) from vaccines as quickly as possible, and thiomersal has been phased out of US and European vaccines, except for some preparations of influenza vaccine.[74] The CDC and the AAP followed the precautionary principle, which assumes that there is no harm in exercising caution even if it later turns out to be unwarranted, but their 1999 action sparked confusion and controversy that Thiomersal was the cause of autism.[74]

Since 2000, the thiomersal in child vaccines has been alleged to contribute to autism, and thousands of parents in the United States have pursued legal compensation from a federal fund.[75] A 2004 Institute of Medicine (IOM) committee favored rejecting any causal relationship between thiomersal-containing vaccines and autism.[76] Autism incidence rates increased steadily even after thiomersal was removed from childhood vaccines.[77] Currently there is no accepted scientific evidence that exposure to thiomersal is a factor in causing autism.[78]

Dental amalgam toxicity

For more details on this topic, see Dental amalgam toxicity.

Dental amalgam is a possible cause of low-level mercury poisoning due to its use in dental fillings. Discussion on the topic includes debates on whether amalgam should be used, with critics arguing that its toxic effects make it unsafe.

Cosmetics

Some skin whitening products contain the toxic chemical mercury(II) chloride as the active ingredient. When applied, the chemical readily absorbs through the skin into the bloodstream.[79] The use of mercury in cosmetics is illegal in the United States. However, cosmetics containing mercury are often illegally imported. Following a certified case of mercury poisoning resulting from the use of an imported skin whitening product, the United States Food and Drug Administration warned against the use of such products.[80][81] Symptoms of mercury poisoning have resulted from the use of various mercury-containing cosmetic products.[25][82][83] The use of skin whitening products is especially popular amongst Asian women.[84] In Hong Kong in 2002, two products were discovered to contain between 9,000 and 60,000 times the recommended dose.[85]

Fluorescent lamps

Fluorescent lamps contain mercury which is released when bulbs are broken. Mercury in bulbs is typically present as either elemental mercury liquid, vapor, or both, since the liquid evaporates at ambient temperature.[86] When broken indoors, bulbs may emit sufficient mercury vapor to present health concerns, and the U.S. Environmental Protection Agency recommends evacuating and airing out a room for at least 15 minutes after breaking a fluorescent light bulb.[87] Breakage of multiple bulbs presents a greater concern. A 1987 report described a 23-month-old toddler who suffered anorexia, weight loss, irritability, profuse sweating, and peeling and redness of fingers and toes. This case of acrodynia was traced to exposure of mercury from a carton of 8-foot fluorescent light bulbs that had broken in a potting shed adjacent to the main nursery. The glass was cleaned up and discarded, but the child often used the area for play.[88]

Assassination

Mercury has been used at various times to assassinate people. In 2008, Russian lawyer Karinna Moskalenko claimed to have been poisoned by mercury left in her car,[89] while in 2010 journalists Viktor Kalashnikov and Marina Kalashnikova accused Russia's FSB of trying to poison them.[90]

See also

References

  1. 1 2 3 "Mercury". NIEHS. Retrieved 19 November 2016.
  2. 1 2 3 4 5 Bernhoft, RA (2012). "Mercury toxicity and treatment: a review of the literature.". Journal of environmental and public health. 2012: 460508. PMID 22235210.
  3. 1 2 3 4 5 "Mercury and health". WHO. January 2016. Retrieved 19 November 2016.
  4. 1 2 3 Kosnett, MJ (December 2013). "The role of chelation in the treatment of arsenic and mercury poisoning.". Journal of medical toxicology : official journal of the American College of Medical Toxicology. 9 (4): 347–54. PMID 24178900.
  5. Hong, YS; Kim, YM; Lee, KE (November 2012). "Methylmercury exposure and health effects.". Journal of preventive medicine and public health = Yebang Uihakhoe chi. 45 (6): 353–63. PMID 23230465.
  6. 1 2 3 4 Bose-O'Reilly, S; McCarty, KM; Steckling, N; Lettmeier, B (September 2010). "Mercury exposure and children's health.". Current problems in pediatric and adolescent health care. 40 (8): 186–215. PMID 20816346.
  7. Horowitz Y, Greenberg D, Ling G, Lifshitz M (2002). "Acrodynia: a case report of two siblings". Arch. Dis. Child. 86 (6): 453. doi:10.1136/adc.86.6.453. PMC 1762992Freely accessible. PMID 12023189.
  8. United States Environmental Protection Agency (December 1997). Mercury Study Report to Congress (PDF). 3. Washington, D.C.: United States Environmental Protection Agency.
  9. ATSDR Mercury ToxFAQ (April 1999). "ToxFAQs: Mercury". Agency for Toxic Substances and Disease Registry. Retrieved 2007-07-25.
  10. Dufault R, LeBlanc B, Schnoll R, et al. (2009). "Mercury from chlor-alkali plants: measured concentrations in food product sugar". Environ. Health. 8 (1): 2. doi:10.1186/1476-069X-8-2. PMC 2637263Freely accessible. PMID 19171026. Lay summary Medscape Today (2009-01-27).
  11. Levy M. (1995). "Dental Amalgam: toxicological evaluation and health risk assessment". J. Can. Dent. Assoc. 61: 667–8, 671–4.
  12. Goldman LR, Shannon MW (2001). "Technical report: mercury in the environment: implications for pediatricians". Pediatrics. 108 (1): 197–205. doi:10.1542/peds.108.1.197. PMID 11433078.
  13. url = http://search.japantimes.co.jp/cgi-bin/nn20090923f2.html
  14. http://www.epa.gov/mercury/about.htm
  15. Pacyna EG, Pacyna JM, Steenhuisen F, Wilson S (2006). "Global anthropogenic mercury emission inventory for 2000". Atmos. Environ. 40 (22): 4048–63. Bibcode:2006AtmEn..40.4048P. doi:10.1016/j.atmosenv.2006.03.041.
  16. How mercury poisons gold miners and enters the food chain, BBC News
  17. United States Environmental Protection Agency (December 1997). Mercury Study Report to Congress (PDF). 4. Washington, D.C.: United States Environmental Protection Agency.
  18. Doja A, Roberts W (2006). "Immunizations and autism: a review of the literature". Can J Neurol Sci. 33 (4): 341–6. doi:10.1017/s031716710000528x. PMID 17168158.
  19. Thompson WW, Price C, Goodson B, et al. (2007). "Early thimerosal exposure and neuropsychological outcomes at 7 to 10 years". N. Engl. J. Med. 357 (13): 1281–92. doi:10.1056/NEJMoa071434. PMID 17898097.
  20. 1 2 The Karen Wetterhahn story - University of Bristol web page documenting her death, retrieved December 9, 2006.
  21. 1 2 OSHA update following Karen Wetterhahn's death
  22. 1 2 3 4 5 Clifton JC 2nd (2007). "Mercury exposure and public health". Pediatr. Clin. North Am. 54 (2): 237–69, viii. doi:10.1016/j.pcl.2007.02.005. PMID 17448359.
  23. What you need to know about mercury in fish and shellfish - Advice for women who might become pregnant women who are pregnant nursing mothers young children. U.S. FDA and U.S. EPA Advisory EPA-823-F-04-009, March 2004.
  24. Mozaffarian D, Rimm EB (2006). "Fish intake, contaminants, and human health: evaluating the risks and the benefits". JAMA. 296 (15): 1885–99. doi:10.1001/jama.296.15.1885. PMID 17047219.
  25. 1 2 3 Clarkson TW, Magos L (2006). "The toxicology of mercury and its chemical compounds". Crit. Rev. Toxicol. 36 (8): 609–62. doi:10.1080/10408440600845619. PMID 16973445.
  26. Bayer, SA; Altman, J; Russo, RJ; Xhang, X (1993). "Timetables of neurogenesis in the human brain based on experimentally determined patterns in the rat". Neurotoxicology. 14 (1): 83–144. PMID 8361683.
  27. Rice, DC; Barone, S (2000). "Critical periods of vulnerability for the developing nervous system: evidence from human and animal models". Environmental Health Perspectives. 108 (3): 511–533. doi:10.2307/3454543. PMC 1637807Freely accessible. PMID 10852851.
  28. Newland, MC; Reed, MN; Rasmussen, E (2015). "A hypothesis about how early developmental methylmercury exposure disrupts behavior in adulthood". Behavioural Processes. 114: 41–51. doi:10.1016/j.beproc.2015.03.007.
  29. 1 2 Langford NJ, Ferner RE (1999). "Toxicity of mercury" (PDF). Journal of Human Hypertension. 13 (10): 651–6. doi:10.1038/sj.jhh.1000896. PMID 10516733. Retrieved 2007-07-31.
  30. Emsley, John. The Elements of Murder. Oxford: Oxford University Press, 2005. ISBN 0-19-280599-1
  31. "Mercuric Cyanide." 1987. http://www.gulflink.osd.mil/m256/m256_refs/n17en111/164.htm (accessed April 2, 2009).
  32. 1 2 ATSDR. 1999. Toxicological Profile for Mercury. Atlanta, GA:Agency for Toxic Substances and Disease Registry. http://www.atsdr.cdc.gov/toxprofiles/tp46.pdf
  33. Hursh JB, Clarkson TW, Miles E, Goldsmith LA (1989). "Percutaneous absorption of mercury vapor by man". Arch. Environ. Health. 44 (2): 120–127. doi:10.1080/00039896.1989.9934385. PMID 2494955.
  34. Cherian MG, Hursh JG, Clarkson TW (1978). "Radioactive mercury distribution in biological fluids and excretion in human subjects after inhalation of mercury vapor". Archives of Environmental Health. 33: 190–214.
  35. Ngim CH, Foo SC, Boey KW, Keyaratnam J (1992). "Chronic neurobehavioral effects of elemental mercury in dentists". British Journal of Industrial Medicine. 49 (11): 782–790. doi:10.1136/oem.49.11.782. PMC 1039326Freely accessible. PMID 1463679.
  36. Liang YX, Sun RK, Chen ZQ, Li LH (1993). "Psychological effects of low exposure to mercury vapor: Application of computer-administered neurobehavioral evaluation system". Environmental Research. 60 (2): 320–327. doi:10.1006/enrs.1993.1040. PMID 8472661.
  37. Carvalho CM, Chew EH, Hashemy SI, Lu J, Holmgren A (2008). "Inhibition of the human thioredoxin system: A molecular mechanism of mercury toxicity.". Journal of Biological Chemistry. 283 (18): 11913–11923. doi:10.1074/jbc.m710133200. PMID 18321861.
  38. Linster, C.L.; Van Schaftingen, E. (2007). "Vitamin C: Biosynthesis, recycling and degradation in mammals.". FEBS Journal. 274 (1): 1–22. doi:10.1111/j.1742-4658.2006.05607.x. PMID 17222174.
  39. Ralston, Nicholas V.C.; Raymond, Laura J. (2010). "Dietary selenium's protective effects against methylmercury toxicity.". Toxicology. 278 (1): 112–123. doi:10.1016/j.tox.2010.06.004. PMID 20561558.
  40. 1 2 Ibrahim D, Froberg B, Wolf A, Rusyniak DE (2006). "Heavy metal poisoning: clinical presentations and pathophysiology". Clin. Lab. Med. 26 (1): 67–97, viii. doi:10.1016/j.cll.2006.02.003. PMID 16567226.
  41. "Export-ban of mercury and mercury compounds from the EU by 2011" (Press release). European Parliament. 2008-05-21. Retrieved 2008-06-10.
  42. ATSDR - Mercury - Regulations and Advisories
  43. What You Need to Know about Mercury in Fish and Shellfish
  44. EPA Fish Kids Flash-based movie
  45. Cleaning Up Spilled Mercury
  46. Risher JF, Amler SN (2005). "Mercury exposure: evaluation and intervention the inappropriate use of chelating agents in the diagnosis and treatment of putative mercury poisoning". Neurotoxicology. 26 (4): 691–9. doi:10.1016/j.neuro.2005.05.004. PMID 16009427.
  47. 1 2 Rooney JP (2007). "The role of thiols, dithiols, nutritional factors and interacting ligands in the toxicology of mercury". Toxicology. 234 (3): 145–56. doi:10.1016/j.tox.2007.02.016. PMID 17408840.
  48. Watanabe C (2002). "Modification of mercury toxicity by selenium: practical importance?" (PDF). Tohoku J. Exp. Med. 196 (2): 71–7. doi:10.1620/tjem.196.71. PMID 12498318.
  49. Hazards of chelation therapy:
  50. Rooney, J.P.K. (2014). "The retention time of inorganic mercury in the brain — A systematic review of the evidence". Toxicology and Applied Pharmacology. 274 (3): 425–435. doi:10.1016/j.taap.2013.12.011.
  51. Hendry WF, A'Hern RP, Cole PJ (1993). "Was Young's syndrome caused by exposure to mercury in childhood?". BMJ. 307 (6919): 1579–82. doi:10.1136/bmj.307.6919.1579. PMC 1697782Freely accessible. PMID 8292944.
  52. R. Baselt, Disposition of Toxic Drugs and Chemicals in Man, 8th edition, Biomedical Publications, Foster City, CA, 2008, pp. 923-927.
  53. Zhao HL, Zhu X, Sui Y (2006). "The short-lived Chinese emperors". J. Am. Geriatr. Soc. 54 (8): 1295–6. doi:10.1111/j.1532-5415.2006.00821.x. PMID 16914004.
  54. Waldron HA (1983). "Did the Mad Hatter have mercury poisoning?". Br. Med. J. 287 (6409): 1961. doi:10.1136/bmj.287.6409.1961. PMC 1550196Freely accessible. PMID 6418283.
  55. Kathryn J. Kitzmiller, Ph.D. The Not-So-Mad Hatter: Occupational Hazards of Mercury
  56. An Account of the Effect of Mercurial Vapors on the Crew of His Majesty's Ship Triumph, in the year 1810. By Wm. Burnet, M.D. one of the Medical Commissioners of the Navy, formerly Physician and Inspector of Hospitals to the Mediterranean Fleet.
  57. Michael J. Doherty MD: The Quicksilver Prize: Mercury vapor poisoning aboard HMS Triumph and HMS Phipps (2003).
  58. "An article about the cathedral.". Archived from the original on 2011-08-25.
  59. "An article about gilding.".
  60. Stock A (1926). "Die Gefaehrlichkeit des Quecksilberdampfes". Zeitschrift für angewandte Chemie. 39 (15): 461–466. doi:10.1002/ange.19260391502.
  61. Hunter D, Bomford RR, Russell DS (1940). "Poisoning by methylmercury compounds". Quart. J. Med. 9: 193–213.
  62. Davidson PW, Myers GJ, Weiss B (2004). "Mercury exposure and child development outcomes". Pediatrics. 113 (4 Suppl): 1023–9. doi:10.1542/peds.113.4.S1.1023. PMID 15060195.
  63. Engler R (April 27, 1985). "Technology out of Control". The Nation. 240.
  64. Vargas JA (2007-01-26). "'Mad Scientist': On Court TV, Fatal Chemistry". The Washington Post. Retrieved 2007-01-28.
  65. Swearengin M (2008-04-01). "Man dies from mercury poisoning after trying to extract gold". Durant Daily Democrat.
  66. (Associated Press) (2008-04-01). "Colbert man dies from mercury poisoning". Tulsa World. Retrieved 2008-04-20.
  67. Tiffany McGee (2009-01-15). "Jeremy Piven Explains His Mystery Ailment". People. Retrieved 2009-01-15.
  68. Down To Earth: India's Minimata
  69. James WD, Berger TG, Elston DM (2006). Andrews' diseases of the skin: clinical dermatology (10th ed.). Saunders. p. 134. ISBN 0-7216-2921-0.
  70. Bjørklund G (1995). "Mercury and Acrodynia" (PDF). Journal of Orthomolecular Medicine. 10 (3 & 4): 145–146.
  71. Dally A (1997). "The rise and fall of pink disease". Soc. Hist. Med. 10 (2): 291–304. doi:10.1093/shm/10.2.291. PMID 11619497.
  72. Ford M, Delaney KA, Ling L, Erickson T (2000). Clinical Toxicology (1st ed.). Saunders. ISBN 0-7216-5485-1.
  73. 1 2 Offit PA (2007). "Thimerosal and vaccines—a cautionary tale". N. Engl. J. Med. 357 (13): 1278–9. doi:10.1056/NEJMp078187. PMID 17898096.
  74. Sugarman SD (2007). "Cases in vaccine court—legal battles over vaccines and autism". N. Engl. J. Med. 357 (13): 1275–7. doi:10.1056/NEJMp078168. PMID 17898095.
  75. Immunization Safety Review Committee (2004). Immunization Safety Review: Vaccines and Autism. The National Academies Press. ISBN 0-309-09237-X.
  76. Gerber, Jeffrey S.; Paul A. Offit (2009). "Vaccines and Autism: A Tale of Shifting Hypotheses". Clinical Infectious Diseases. 48 (4): 456–451. doi:10.1086/596476. PMC 2908388Freely accessible. PMID 19128068.
  77. Doja A, Roberts W (2006). "Immunizations and autism: a review of the literature". Can. J. Neurol. Sci. 33 (4): 341–6. doi:10.1017/s031716710000528x. PMID 17168158.
  78. Counter SA (December 16, 2003). Whitening skin can be deadly. The Boston Globe.
  79. "FDA Proposes Hydroquinone Ban".FDA bans hydroquinone in skin whitening products
  80. "NYC Health Dept. Warns Against Use of "Skin-lightening" Creams Containing Mercury or Similar Products Which Do Not List Ingredients". January 27, 2005.
  81. Counter SA, Buchanan LH. "Mercury exposure in children: a review" (PDF).
  82. Mahaffey KR. "Dynamics of Mercury Pollution on Regional and Global Scales".
  83. In a survey, 28% of Koreans and 50% of Philippians say that they use skin whitening products."Skin lightening in Asia? A bright future?".
  84. Bray M (2002-05-15). SKIN DEEP: Dying to be white. CNN. Retrieved 2010-05-12.
  85. Aucott M, McLinden M, Winka M (2003). "Release of mercury from broken fluorescent bulbs". J. Air Waste Manag. Assoc. 53 (2): 143–51. doi:10.1080/10473289.2003.10466132. PMID 12617289.
  86. "Spills, disposal and site cleanup". U.S. Environmental Protection Agency. 2009-07-13. Retrieved 2009-06-30.
  87. Tunnessen WW Jr; McMahon KJ; Baser M (1987). "Acrodynia: exposure to mercury from fluorescent light bulbs". Pediatrics. 79 (5): 786–9. PMID 3575038.
  88. Russian lawyer suspects mercury poisoning, USA Today.com
  89. German inquiry into 'poisoning' of Russian dissidents, Telegraph

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