Tributyltin is arguably the most toxic compound ever to be deliberately introduced into the
marine environment as an ingredient of antifouling paints. It has had widespread toxic effects
on a range of marine organisms, with some gastropod species being particularly sensitive.
Effects of TBT on non-target species have resulted in partial bans on its use in many countries,
so that new inputs to the water column have decreased in most areas.
One of the physicochemical features of TBT is that it is readily sequestered by suspended
particulates due to its low solubility and its hydrophobicity, therefore becoming incorporated
into estuarine sediments. The availability of this sediment-bound TBT has been investigated
through its potential for re-release back to the water column, and directly from the sediment
using the sediment dwelling gastropod Hinia reticulata.
The sorption process itself has been investigated using natural components to determine the
sediment-water partition coefficient (Kd) together with factors affecting its magnitude. Sorption
by sediments has been shown to be rapid (minutes), although the achievement of equilibrium
may take longer (hours), and exhibits a Freundlich-like dependence on the TBT concentration
due to the variable energies of TBT sorption sites on sediment particles. The major determinant
of Kd is sediment type, greater adsorption occurring in fine-grained organic rich sediments
compared to low organic sands; although both salinity and pH modify the degree of adsorption.
The sorption process has been shown to be reversible, so that previously contaminated
sediments may act as reservoirs of TBT, releasing the compound back to the overlying water
for many years.
Hinia reticulata has been shown to be an effective and quantitative accumulator of both
dissolved and sediment-bound TBT, principally acquiring TBT from water across the respiratory
surfaces. When additionally exposed to sediments, significantly higher body burdens were
accumulated, with up to 80% of the total attributable to the sediment. Uptake of TBT across the
surface of the head/foot appears to be an important pathway for sediment-exposed Hinia
reticulata, while the ingestion of contaminated sediment does not appear to occur. Hinia
reticulata is capable of metabolising TBT to lesser butylated and presumably less toxic
products which are excreted, making its accumulated body burdens responsive to changing
environmental TBT levels, and increasing its value as a biomonitor.
When exposed to a range of TBT contaminated sediments, Hinia reticulata showed there to be
greater TBT availability from sediments with a low sorptive capacity (sands), principally through
desorption of TBT to the overlying water. Fine-grained organic-rich muds, which have a greater
capacity for TBT, produced lower accumulated burdens in Hinia reticulata, but may represent
more important long-term sources of TBT to benthic organisms in estuaries.
Date of Award | 1998 |
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Original language | English |
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Awarding Institution | |
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THE BIOAVAILABILITY OF SEDIMENT BOUND TRIBUTYLTIN (TBT)
Dingle Pope, N. (Author). 1998
Student thesis: PhD