α-HgS is the main component of traditional Chinese medicine cinnabar, while β-HgS is the main component of Tibetan medicine Zuotai. However, there was no comparative study on the dissolution and absorption in gastrointestinal tract and bioaccumulation in organs of mercury in Cinnabar, Zuotai, α-HgS and β-HgS. In this study, the dissolution process of the four compounds in the human gastrointestinal tract was simulated to determine the mercury dissolutions and compare the mercury dissolution of different medicines and the dissolution-promoting capacity of different solutions. To explore the absorption and bioaccumulation of cinnabar and Zuotai in organisms, mice were orally administered with clinical equivalent doses cinnabar and Zuotai. Meanwhile, a group of mice was given α-HgS and β-HgS with the equivalent mercury with cinnabar, while another group was given β-HgS and HgCl2 with the equivalent mercury with Zuotai. The mercury absorption and bioaccumulation capacities of different medicines in mice and their mercury bioaccumulation in different tissues and organs were compared. The experimental results showed a high mercury dissolutions of Zuotai in artificial gastrointestinal fluid, which was followed by β-HgS, cinnabar and α-HgS. As for the mercury absorption and bioaccumulation in mice, HgCl2 was the highest, β-HgS was the next, and a-HgS was slightly higher than cinnabar. The organs with the mercury bioaccumulation from high to low were kidney, liver and brain. This study is close to clinical practices and can provide reference for the clinical safe medication as well as a study model for the safety evaluation on heavy metal-containing medicines by observing the mercury dissolution, absorption, distribution and accumulation of mercury-containing medicines cinnabar and zuotai.
Animals ; Brain ; metabolism ; Drugs, Chinese Herbal ; chemistry ; pharmacokinetics ; Gastrointestinal Tract ; metabolism ; Kidney ; metabolism ; Liver ; metabolism ; Male ; Mercury ; chemistry ; pharmacokinetics ; Mercury Compounds ; chemistry ; pharmacokinetics ; Mice ; Solubility

Mercury is a toxic and non-essential metal in the human body. Mercury is ubiquitously distributed in the environment, present in natural products, and exists extensively in items encountered in daily life. There are three forms of mercury, i.e., elemental (or metallic) mercury, inorganic mercury compounds, and organic mercury compounds. This review examines the toxicity of elemental mercury and inorganic mercury compounds. Inorganic mercury compounds are water soluble with a bioavailability of 7% to 15% after ingestion; they are also irritants and cause gastrointestinal symptoms. Upon entering the body, inorganic mercury compounds are accumulated mainly in the kidneys and produce kidney damage. In contrast, human exposure to elemental mercury is mainly by inhalation, followed by rapid absorption and distribution in all major organs. Elemental mercury from ingestion is poorly absorbed with a bioavailability of less than 0.01%. The primary target organs of elemental mercury are the brain and kidney. Elemental mercury is lipid soluble and can cross the blood-brain barrier, while inorganic mercury compounds are not lipid soluble, rendering them unable to cross the blood-brain barrier. Elemental mercury may also enter the brain from the nasal cavity through the olfactory pathway. The blood mercury is a useful biomarker after short-term and high-level exposure, whereas the urine mercury is the ideal biomarker for long-term exposure to both elemental and inorganic mercury, and also as a good indicator of body burden. This review discusses the common sources of mercury exposure, skin lightening products containing mercury and mercury release from dental amalgam filling, two issues that happen in daily life, bear significant public health importance, and yet undergo extensive debate on their safety.
Biological Availability ; Biological Markers/blood/urine ; Blood-Brain Barrier/metabolism ; Body Burden ; Dental Amalgam/chemistry/metabolism ; *Environmental Exposure ; Humans ; Mercury/chemistry/*metabolism ; Mercury Compounds/chemistry/*metabolism ; Skin Lightening Preparations/chemistry/metabolism

Mercury is emitted to the atmosphere from various natural and anthropogenic sources, and degrades with difficulty in the environment. Mercury exists as various species, mainly elemental (Hg0) and divalent (Hg2+) mercury depending on its oxidation states in air and water. Mercury emitted to the atmosphere can be deposited into aqueous environments by wet and dry depositions, and some can be re-emitted into the atmosphere. The deposited mercury species, mainly Hg2+, can react with various organic compounds in water and sediment by biotic reactions mediated by sulfur-reducing bacteria, and abiotic reactions mediated by sunlight photolysis, resulting in conversion into organic mercury such as methylmercury (MeHg). MeHg can be bioaccumulated through the food web in the ecosystem, finally exposing humans who consume fish. For a better understanding of how humans are exposed to mercury in the environment, this review paper summarizes the mechanisms of emission, fate and transport, speciation chemistry, bioaccumulation, levels of contamination in environmental media, and finally exposure assessment of humans.
Air Pollutants/chemistry/metabolism ; *Environmental Exposure ; Environmental Remediation ; Food Chain ; Humans ; Mercury/chemistry/*metabolism ; Methylmercury Compounds/chemistry/metabolism ; Photolysis ; Sulfur-Reducing Bacteria/metabolism ; Water Pollutants, Chemical/metabolism

Mercury-containing preparations are widely used in surgery department of traditional Chinese medicine and have made remarkable achievements. But they are toxic to human kidney, nerve, immune, etc. Smilacis Glabrae Rhizoma is sweet, tasteless and neutral in nature and able to enter liver and stomach channels and detoxify mercury poisoning. This article summarizes the mercury poisoning and the detoxification effect of Smilacis Glabrae Rhizoma in ancient records, pharmaceutical studies and clinical application, in order to provide ideas and methods for the safe use of mercury-containing preparations in surgery department of traditional Chinese medicine.
Drugs, Chinese Herbal ; therapeutic use ; Humans ; Inactivation, Metabolic ; Liliaceae ; chemistry ; Liver ; drug effects ; metabolism ; Medicine, Chinese Traditional ; Mercury Compounds ; adverse effects ; pharmacokinetics ; therapeutic use ; Mercury Poisoning ; prevention & control ; Plants, Medicinal ; chemistry ; Rhizome ; chemistry ; Stomach ; drug effects ; metabolism

OBJECTIVETo study comparatively the characteristics of absorption and distribution of mercury and arsenic from realgar and cinnabar of Angong Niuhuang Pill in normal rats and the rats with cerebral ischemia after oral administration.

METHODThe blood samples and homogenates of liver, kidney and brain were prepared at various intervals after the animals were treated with Angong Niuhuang pill ig. The levels of total mercury and total arsenic in the blood and the organ homogenates were measured with Microwava Accelerated Reaction System and AAs, respectively.

RESULTThe blood concentrations of mercury and arseic reached the highest point in normal rats at one hour following single oral dosing of Angong Niuhuang pill. In normal rats, the mercury distribution was characterized by its higher level in blood and kidneys than in other organs, while a higher distribution of arsenic was found in blood than in organs. No difference in the distribution of mercury or arsenic was found between normal rats and rats with cerebral ischemia after the treatment with the pill.

CONCLUSIONThe highest level of mercury or arsenic in blood occurs at one hour after oral administration of the pill in normal rats. There is a higher distribution of mercury in blood and kidneys, while a higher distribution of the arsenic only in blood. There is no significant difference in the distribution of mercury or arsenic between the normal rats and the ischemic rats.

Animals ; Arsenic ; blood ; metabolism ; Arsenicals ; pharmacokinetics ; Brain Ischemia ; metabolism ; Drug Combinations ; Drugs, Chinese Herbal ; isolation & purification ; pharmacokinetics ; Male ; Materia Medica ; isolation & purification ; pharmacokinetics ; Mercury ; blood ; metabolism ; Mercury Compounds ; pharmacokinetics ; Plants, Medicinal ; chemistry ; Rats ; Sulfides ; pharmacokinetics ; Tissue Distribution

Methylmercury is a hazardous substance that is of interest with regard to environmental health, as inorganic mercury circulating in the general environment is dissolved into freshwater and seawater, condensed through the food chain, ingested by humans, and consequently affects human health. Recently, there has been much interest and discussion regarding the toxicity of methylmercury, the correlation with fish and shellfish intake, and methods of long-term management of the human health effects of methylmercury. What effects chronic exposure to a low concentration of methylmercury has on human health remains controversial. Although the possibility of methylmercury poisoning the heart and blood vessel system, the reproductive system, and the immune system is continuously raised and discussed, and the carcinogenicity of methylmercury is also under discussion, a clear conclusion regarding the human health effects according to exposure level has not yet been drawn. The Joint FAO/WHO Expert Committee on Food Additives proposed to prepare additional fish and shellfish intake recommendations for consumers based on the quantified evaluation of the hazardousness of methylmercury contained in fish and shellfish, methylmercury management in the Korea has not yet caught up with this international trend. Currently, the methylmercury exposure level of Koreans is known to be very high. The starting point of methylmercury exposure management is inorganic mercury in the general environment, but food intake through methylation is the main exposure source. Along with efforts to reduce mercury in the general environment, food intake management should be undertaken to reduce the human exposure to methylmercury in Korea.
Animals ; *Environmental Exposure ; Fishes/metabolism ; Food Chain ; Humans ; Mercury Poisoning, Nervous System/etiology ; Methylmercury Compounds/chemistry/*metabolism/toxicity ; Neurons/drug effects ; Oxidative Stress/drug effects ; Public Health ; Reproduction/drug effects ; Thymocytes/cytology/drug effects

OBJECTIVETo explore the pharmacologic mechanism of cinnabar (CA) and realgar (RG) in Angong Niuhuang powder (ANP) by way of studying the characteristics of their effects on organism under physiologic and pathologic states.

METHODSSD rats were randomly divided into six groups, 8-10 rats in each group. Group A: untreated normal rats; Group B: normal rats administered by ANP (drug I) 278 mg/kg; Group C: normal rats administered by ANP subtracted CA and RG (drug II) 222.7 mg/kg; Group D: brain edema model rats established by unilateral common carotid artery injection of Bacillus pertussis 250 million/kg; Group E: model rats administered by ANP 278 mg/kg 1 hr before modeling; Group F: model rats administered by drug II 222.7 mg 1 hr before modeling. Blood sample and brain tissue in Group D were obtained 4 hrs after modeling and those in other groups obtained 5 hrs after drug administration. The total activity of lactate dehydrogenase (LDH) in serum and brain tissue was determined by colorimetry and that of serum LDH isoenzymes (LDH(1-5)) were determined by gel electrophoresis.

RESULTSAs compared with Group A, LDH, LDH1 and LDH2 activities increased in Group D (P < 0.01), and increased also in Group B and C (P < 0.05), while LDH4 and LDH5 decreased obviously in Group B and C. But except that of LDH5, no significant difference of LDH(1-4) in brain tissue and serum was shown in comparison of Group B and C. As compared with Group D, LDH was lower (P < 0.01) and LDH5 was higher (P < 0.01) in Group E and F without significant difference, LDH2, LDH3 were lower in Group E (P < 0.01) but unchanged in Group F, LDH1 and LDH4 were not changed in Group E but significantly lowered in Group F (P < 0.05 and P < 0.01).

CONCLUSIONAdministration of ANP in normal physiologic condition would cause damage on myocardium and kidney to certain extent, administration of ANP and drug II in pathologic (infectious brain edema) would suppress the hyper-activated LDH, with no significant difference between the effects of drug II and ANP. However, CA and RA in ANP are proven to have influence on the serum LDH isoenzymes, indicating that the two ingredients may have some potential pharmacological effects.

Animals ; Arsenicals ; pharmacology ; Brain Edema ; enzymology ; etiology ; Drugs, Chinese Herbal ; chemistry ; Encephalitis ; complications ; Isoenzymes ; metabolism ; L-Lactate Dehydrogenase ; metabolism ; Male ; Mercury Compounds ; pharmacology ; Powders ; Rats ; Rats, Sprague-Dawley ; Sulfides ; pharmacology