tetrodotoxin and Mercury-Poisoning

tetrodotoxin has been researched along with Mercury-Poisoning* in 2 studies

Other Studies

2 other study(ies) available for tetrodotoxin and Mercury-Poisoning

Article	Year
Hg2+ causes neurotoxicity at an intracellular site following entry through Na and Ca channels. Brain research, 1983, May-16, Volume: 267, Issue:2 At motor nerve terminals, Hg2+ causes (a) irreversible depolarization, (b) increase in transmitter release, and (c) subsequent irreversible block of transmitter release. All effects are antagonized when a Na channel blocker (tetrodotoxin, TTX) and a Ca channel blocker (Co2+) are present, but not when either blocker is used alone. The effects are not antagonized by TTX plus Co2+ when the mercurial is lipid-soluble (methylmercury). This indicates that the neurotoxic action of Hg2+ is at an intracellular site and that entry is gained through both Na and Ca channels. The results suggest that metals may inhibit transmitter release at either the Ca channel or at the release site, but that irreversible toxicity is due to an intracellular action, possibly involving SH groups. Topics: Animals; Calcium; Cobalt; Ion Channels; Mercury Poisoning; Motor Endplate; Neuromuscular Junction; Pectoralis Muscles; Rana pipiens; Sodium; Synaptic Transmission; Tetrodotoxin	1983
Current research on toxic food contaminants. Journal of the American Dietetic Association, 1966, Volume: 49, Issue:2 Topics: Aflatoxins; Animals; Aspergillus; Bacteria; Benzopyrenes; Carcinogens; Fishes; Food Contamination; Food Preservation; Fungi; Humans; Mercury Poisoning; Plant Poisoning; Tetrodotoxin; Toxins, Biological; Trypsin Inhibitors	1966

Article

Year

Hg2+ causes neurotoxicity at an intracellular site following entry through Na and Ca channels.

Brain research, 1983, May-16, Volume: 267, Issue:2

At motor nerve terminals, Hg2+ causes (a) irreversible depolarization, (b) increase in transmitter release, and (c) subsequent irreversible block of transmitter release. All effects are antagonized when a Na channel blocker (tetrodotoxin, TTX) and a Ca channel blocker (Co2+) are present, but not when either blocker is used alone. The effects are not antagonized by TTX plus Co2+ when the mercurial is lipid-soluble (methylmercury). This indicates that the neurotoxic action of Hg2+ is at an intracellular site and that entry is gained through both Na and Ca channels. The results suggest that metals may inhibit transmitter release at either the Ca channel or at the release site, but that irreversible toxicity is due to an intracellular action, possibly involving SH groups.

Topics: Animals; Calcium; Cobalt; Ion Channels; Mercury Poisoning; Motor Endplate; Neuromuscular Junction; Pectoralis Muscles; Rana pipiens; Sodium; Synaptic Transmission; Tetrodotoxin

1983

Current research on toxic food contaminants.

Journal of the American Dietetic Association, 1966, Volume: 49, Issue:2

Topics: Aflatoxins; Animals; Aspergillus; Bacteria; Benzopyrenes; Carcinogens; Fishes; Food Contamination; Food Preservation; Fungi; Humans; Mercury Poisoning; Plant Poisoning; Tetrodotoxin; Toxins, Biological; Trypsin Inhibitors

1966