TY - JOUR
T1 - Anoxic or aerial survival of bivalves and other euryoxic invertebrates as a useful response to environmental stress - A comprehensive review
AU - De Zwaan, A.
AU - Eertman, R.H.M.
N1 - Reporting year: 1996
Metis note: 0746; CEME; MM; file:///L:/Endnotedatabases/NIOOPUB/pdfs/Pdfs1996/DeZwaan_ea_0746.pdf
PY - 1996
Y1 - 1996
N2 - Laboratory and field studies have demonstrated the applicability of anoxic/aerial survival as an early warning indicator of contaminant induced stress. The effects of xenobiotics, including heavy metals, organometals and organics as well as contaminated field sediments have been investigated. The use of this physiological response is rapid, easily quantified and inexpensive. In most studies bivalve molluscs were investigated, the sea mussel Mytihus edulis L. being the favourite species. The different approaches used by various researchers, as reported in the literature, demonstrate the necessity for these experiments to be standardized. When estimating the mortality rate in a closed system or by aerial exposure, the cause of death may not be an indication of anoxia tolerance, but may be an artifact due to the development of microorganisms. Therefore the use of a flow-through system is suggested in cases where the duration of a test exceeds 1 week. When the response is used for the acute assessment of water quality a closed system may be used at low temperatures in combination with an organism with a relatively low anoxia tolerance (e.g., crustaceans). Various reasons why anoxic tolerance may be reduced by toxicants are proposed. Depletion of fuel reserves involved in anaerobic metabolism and intoxication by fermentative products may already commence during chronic exposure to contaminants, and/or the anaerobic energy metabolism may be disturbed. In general there is elevated catabolic activity during anoxic exposure, especially pyruvate derivatives are prominent end produces in muscle tissue of contaminant exposed groups. [KEYWORDS: mortality; contaminants; aerial exposure; anoxia; anaerobiosis; invertebrates; Mytilus edulis; metabolic rate; environmental stress Mussel mytilus-edulis; halicryptus-spinulosus priapulida; clam scapharca-inaequivalvis; anaerobic energy-metabolism; physiological-responses; hydrogen-sulfide; phylogenetic distribution; marine-invertebrates; oxygen-consumption;sipunculus-nudus]
AB - Laboratory and field studies have demonstrated the applicability of anoxic/aerial survival as an early warning indicator of contaminant induced stress. The effects of xenobiotics, including heavy metals, organometals and organics as well as contaminated field sediments have been investigated. The use of this physiological response is rapid, easily quantified and inexpensive. In most studies bivalve molluscs were investigated, the sea mussel Mytihus edulis L. being the favourite species. The different approaches used by various researchers, as reported in the literature, demonstrate the necessity for these experiments to be standardized. When estimating the mortality rate in a closed system or by aerial exposure, the cause of death may not be an indication of anoxia tolerance, but may be an artifact due to the development of microorganisms. Therefore the use of a flow-through system is suggested in cases where the duration of a test exceeds 1 week. When the response is used for the acute assessment of water quality a closed system may be used at low temperatures in combination with an organism with a relatively low anoxia tolerance (e.g., crustaceans). Various reasons why anoxic tolerance may be reduced by toxicants are proposed. Depletion of fuel reserves involved in anaerobic metabolism and intoxication by fermentative products may already commence during chronic exposure to contaminants, and/or the anaerobic energy metabolism may be disturbed. In general there is elevated catabolic activity during anoxic exposure, especially pyruvate derivatives are prominent end produces in muscle tissue of contaminant exposed groups. [KEYWORDS: mortality; contaminants; aerial exposure; anoxia; anaerobiosis; invertebrates; Mytilus edulis; metabolic rate; environmental stress Mussel mytilus-edulis; halicryptus-spinulosus priapulida; clam scapharca-inaequivalvis; anaerobic energy-metabolism; physiological-responses; hydrogen-sulfide; phylogenetic distribution; marine-invertebrates; oxygen-consumption;sipunculus-nudus]
U2 - 10.1016/0742-8413(95)02101-9
DO - 10.1016/0742-8413(95)02101-9
M3 - Article
SN - 1532-0456
VL - 113
SP - 299
EP - 312
JO - Comparative Biochemistry and Physiology Part - C: Toxicology and Pharmacology
JF - Comparative Biochemistry and Physiology Part - C: Toxicology and Pharmacology
IS - 2
ER -